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+Project Gutenberg (https://www.gutenberg.org) public repository for
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-The Project Gutenberg eBook, Evolution and Adaptation, by Thomas Hunt
-Morgan
-
-
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-Title: Evolution and Adaptation
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-Author: Thomas Hunt Morgan
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-      Text that was in italics is enclosed by underscores
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-      Text that was in bold face is enclosed by by equal
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-EVOLUTION AND ADAPTATION
-
-
-------------------------------------------------------------------------
-
-
-[Illustration: Publisher's logo (The Macmillan Company)]
-
-
-------------------------------------------------------------------------
-
-
-EVOLUTION AND ADAPTATION
-
-by
-
-THOMAS HUNT MORGAN, Ph.D.
-
-
-
-
-
-
-New York
-The Macmillan Company
-London: Macmillan & Co., Ltd.
-1908
-
-All rights reserved
-
-Copyright, 1903,
-by The Macmillan Company.
-
-Set up and electrotyped. Published October, 1903. Reprinted January,
-1908.
-
-Norwood Press
-J. S. Cushing Co.—Berwick & Smith Co.
-Norwood, Mass., U.S.A.
-
-
-------------------------------------------------------------------------
-
-
-
-
-                                   TO
-
-                     Professor William Keith Brooks
-
-
-              AS A TOKEN OF SINCERE ADMIRATION AND RESPECT
-
-
-
-
-------------------------------------------------------------------------
-
-
-
-
-                                PREFACE
-
-
-The adaptation of animals and plants to the conditions under which they
-live has always excited the interest, and also the imagination, of
-philosophers and scientists; for this relation between the organism and
-its environment is one of the most characteristic features of living
-things. The question at once suggests itself: How has such a relation
-been brought about? Is it due to something inherent in the living matter
-itself, or is it something that has been, as it were, superimposed upon
-it? An example may make my meaning clearer. No one will suppose that
-there is anything inherent in iron and other metals that would cause
-them to produce an engine if left to themselves. The particular
-arrangement of the pieces has been superimposed upon the metals, so that
-they now fulfil a purpose, or use. Have the materials of which organisms
-are composed been given a definite arrangement, so that they fulfil the
-purpose of maintaining the existence of the organism; and if so, how has
-this been accomplished? It is the object of the following pages to
-discuss this question in all its bearings, and to give, as far as
-possible, an idea of the present state of biological thought concerning
-the problem. I trust that the reader will not be disappointed if he
-finds in the sequel that many of the most fundamental questions in
-regard to adaptation are still unsettled.
-
-In attempting to state the problem as clearly as possible, I fear that
-it may appear that at times I have “taken sides,” when I should only
-have been justified in stating the different aspects of the question.
-But this will do little harm provided the issue has been sharply drawn.
-Indeed, it seems to me that the only scientific value, that a discussion
-of what the French call “les grands problèmes de la Biologie” has, is to
-get a clearer understanding of the relation of what is known to what is
-unknown or only surmised.
-
-In some quarters speculation concerning the origin of the adaptation of
-living things is frowned upon, but I have failed to observe that the
-critics themselves refrain entirely from theorizing. They shut one door
-only to open another, which also leads out into the dark. To deny the
-right to speculative thought would be to deny the right to use one of
-the best tools of research.
-
-Yet it must be admitted that all speculation is not equally valuable.
-The advance of science in the last hundred years has shown that the kind
-of speculation that has real worth is that which leads the way to
-further research and possible discovery. Speculation that leads to this
-end must be recognized as legitimate. It becomes useless when it deals
-with problems that cannot be put to the actual test of observation or
-experiment. It is in this spirit that I have approached the topics
-discussed in the following pages.
-
-The unsophisticated man believes that all other animals exist to
-minister to his welfare; and from this point of view their adaptations
-are thought of solely in their relation to himself. A step in advance
-was taken when the idea was conceived that adaptations are for the good
-of the organisms themselves. It seemed a further advance when the
-conclusion was reached that the _origin_ of adaptations could be
-accounted for, as the result of the benefit that they conferred on their
-possessor. This view was the outcome of the acceptation of the theory of
-evolution, combined with Darwin’s theory of natural selection. It is the
-view held by most biologists at the present time; but I venture to
-prophesy that if any one will undertake to question modern zoologists
-and botanists concerning their relation to the Darwinian theory, he will
-find that, while professing _in a general way_ to hold this theory, most
-biologists have many reservations and doubts, which they either keep to
-themselves or, at any rate, do not allow to interfere either with their
-teaching of the Darwinian doctrine or with the applications that they
-may make of it in their writings. The claim of the opponents of the
-theory that Darwinism has become a dogma contains more truth than the
-nominal followers of this school find pleasant to hear; but let us not,
-therefore, too hastily conclude that Darwin’s theory is without value in
-relation to one side of the problem of adaptation; for, while we can
-profitably reject, as I believe, much of the theory of natural
-selection, and more especially the idea that adaptations have arisen
-because of their usefulness, yet the fact that living things must be
-adapted more or less well to their environment in order to remain in
-existence may, after all, account for the widespread _occurrence_ of
-adaptation in animals and plants. It is this point of view that will be
-developed in the following pages.
-
-I am fully aware of the danger in attempting to cover so wide a field as
-that of “Evolution and Adaptation,” and I cannot hope to escape the
-criticism that is certain to be directed against a specialist who
-ventures nowadays beyond the immediate field of his own researches; yet,
-in my own defence, I may state that the whole point of view underlying
-the position here taken is the immediate outcome of my work on
-regeneration. One of the general questions that I have always kept
-before me in my study of regenerative phenomena is how such a useful
-acquirement as the power to replace lost parts has arisen, and whether
-the Darwinian hypothesis is adequate to explain the result. The
-conclusion that I have reached is that the theory is entirely inadequate
-to account for the _origin_ of the power to regenerate; and it seemed to
-me, therefore, desirable to reëxamine the whole question of adaptation,
-for might it not prove true here, also, that the theory of natural
-selection was inapplicable? This was my starting-point. The results of
-my examination are given in the following pages.
-
-I am deeply indebted to Professor G. H. Parker and to Professor E. G.
-Conklin for advice and friendly criticism; and in connection with the
-revision of the proof I am under many obligations to Professor Joseph W.
-Warren and to Professor E. A. Andrews. Without their generous help I
-should scarcely have ventured into a field so full of pitfalls.
-
-
-Bryn Mawr, Penn., June 10, 1903.
-
-
-------------------------------------------------------------------------
-
-
-
-
-                                CONTENTS
-
-
-                               CHAPTER I
-
-                                                     PAGE
-
-               The Problem of Adaptation                1
-
-               – Structural Adaptations                 1
-
-               – Adaptations for the Good of the       19
-                 Species
-
-               – Organs of Little Use to the           22
-                 Individual
-
-               – Changes in the Organism that are      25
-                 of No Use to the Individual or to
-                 the Race
-
-               – Comparison with Inorganic             26
-                 Phenomena
-
-
-                               CHAPTER II
-
-               The Theory of Evolution                 30
-
-               – Evidence in Favor of the              32
-                 Transmutation Theory
-
-               –  – Evidence from Classification       32
-                 and from Comparative Anatomy
-
-               –  – The Geological Evidence            39
-
-               –  – Evidence from Direct               43
-                 Observation and Experiment
-
-               –  – Modern Criticism of the Theory     44
-                 of Evolution
-
-
-                              CHAPTER III
-
-               The Theory of Evolution (continued)     58
-               – The Evidence from Embryology          58
-               –  – The Recapitulation Theory          58
-               – Conclusions                           84
-
-
-                               CHAPTER IV
-
-               Darwin’s Theories of Artificial and     91
-                 of Natural Selection
-
-               – The Principle of Selection            91
-
-               – Variation and Competition in         104
-                 Nature
-
-               – The Theory of Natural Selection      116
-
-
-                               CHAPTER V
-
-               The Theory of Natural Selection        129
-                 (continued)
-
-               – Objections to the Theory of          129
-                 Natural Selection
-
-               – Sterility between Species            147
-
-               – Weismann’s Germinal Selection        154
-
-
-                               CHAPTER VI
-
-               Darwin’s Theory of Sexual Selection    167
-
-               – Sexual Selection                     167
-
-               – General Criticism of the Theory      213
-                 of Sexual Selection
-
-
-                              CHAPTER VII
-
-               The Inheritance of Acquired            222
-                 Characters
-
-               – Lamarck’s Theory                     222
-
-               – Darwin’s Hypothesis of Pangenesis    233
-
-               – The Neo-Lamarckian School            240
-
-
-                              CHAPTER VIII
-
-               Continuous and Discontinuous           261
-                 Variation and Heredity
-
-               – Continuous Variation                 261
-
-               – Heredity and Continuous Variation    270
-
-               – Discontinuous Variation              272
-
-               – Mendel’s Law                         278
-
-               – The Mutation Theory of De Vries      287
-
-               – Conclusions                          297
-
-
-                               CHAPTER IX
-
-               Evolution as the Result of External    300
-                 and Internal Factors
-
-               – The Effect of External Influences    300
-
-               – Responsive Changes in the            319
-                 Organism that adapt it to the New
-                 Environment
-
-               – Nägeli’s Perfecting Principle        325
-
-
-                               CHAPTER X
-
-               The Origin of the Different Kinds      340
-                 of Adaptations
-
-               – Form and Symmetry                    340
-
-               – Mutual Adaptation of Colonial        350
-                 Forms
-
-               – Degeneration                         352
-
-               – Protective Coloration                357
-
-               – Sexual Dimorphism and Trimorphism    360
-
-               – Length of Life as an Adaptation      370
-
-               – Organs of Extreme Perfection         371
-
-               – Secondary Sexual Organs as           372
-                 Adaptations
-
-               – Individual Adjustments as            375
-                 Adaptations
-
-               – Color Changes as Individual          375
-                 Adaptations
-
-               – Increase of Organs through Use       376
-                 and Decrease through Disuse
-
-               – Reactions of the Organism to         377
-                 Poisons, etc.
-
-               – Regeneration                         379
-
-
-                               CHAPTER XI
-
-               Tropisms and Instincts as              382
-                 Adaptations
-
-
-                              CHAPTER XII
-
-               Sex as an Adaptation                   414
-
-               – The Different Kinds of Sexual        414
-                 Individuals
-
-               – The Determination of Sex             422
-
-               – Sex as a Phenomenon of Adaptation    439
-
-
-                              CHAPTER XIII
-
-               Summary and General Conclusions        452
-
-
-               INDEX                                  465
-
-------------------------------------------------------------------------
-
-
-
-
-                        EVOLUTION AND ADAPTATION
-
-
-
-
-                               CHAPTER I
-
-                       THE PROBLEM OF ADAPTATION
-
-
-Between an organism and its environment there takes place a constant
-interchange of energy and of material. This is, in general, also true
-for all bodies whether living or lifeless; but in the living organism
-this relation is a peculiar one; first, because the plant or the animal
-is so constructed that it is suited to a particular set of physical
-conditions, and, second, because it may so respond to a change in the
-outer world that it further adjusts itself to changing conditions,
-_i.e._ the response may be of such a kind that it better insures the
-existence of the individual, or of the race. The two ideas contained in
-the foregoing statement cover, in a general way, what we mean by the
-adaptation of living things. The following examples will serve to
-illustrate some of the very diverse phenomena that are generally
-included under this head.
-
-
-                         Structural Adaptations
-
-The most striking cases of adaptations are those in which a special, in
-the sense of an unusual, relation exists between the individual and its
-surroundings. For example, the foreleg of the mole is admirably suited
-for digging underground. A similar modification is found in an entirely
-different group of the animal kingdom, namely, in the mole-cricket, in
-which the first legs are also well suited for digging. By their use the
-mole-cricket makes a burrow near the surface of the ground, similar to,
-but of course much smaller than, that made by the mole. In both of these
-cases the adaptation is the more obvious, because, while the leg of the
-mole is formed on the same general plan as that of other vertebrates,
-and the leg of the mole-cricket has the same fundamental structure as
-that of other insects, yet in both cases the details of structure and
-the general proportions have been so altered, that the leg is fitted for
-entirely different purposes from that to which the legs of other
-vertebrates and of other insects are put. The wing of the bat is another
-excellent case of a special adaptation. It is a modified fore-limb
-having a strong membrane stretched between the fingers, which are
-greatly elongated. Here we find a structure, which in other mammals is
-used as an organ for supporting the body, and for progression on the
-ground, changed into one for flying in the air.
-
-The tails of mammals show a number of different adaptations. The tail is
-prehensile in some of the monkeys; and not only can the monkey direct
-its tail toward a branch in order to grasp it, but the tail can be
-wrapped around the branch and hold on so firmly that the monkey can
-swing freely, hanging by its tail alone. The animal has thus a sort of
-fifth hand, one as it were in the middle line of the body, which can be
-used as a hold-fast, while the fingered hands are put to other uses. In
-the squirrels the bushy tail serves as a protection during the winter
-for those parts of the body not so thickly covered by hair. The tail of
-the horse is used to brush away the flies that settle on the hind parts
-of the body. In other mammals, the dog, the cat, and the rat, for
-example, the tail is of less obvious use, although the suggestion has
-been made that it may serve as a sort of rudder when the animal is
-running rapidly. In several other cases, as in the rabbit and in the
-higher apes, the tail is very short, and is of no apparent use; and in
-man it has completely disappeared.
-
-A peculiar case of adaptation is the so-called basket on the third pair
-of legs of the worker honey-bee. A depression of the outer surface of
-the tibia is arched over by stiff hairs. The pollen collected from the
-stamens of flowers is stowed away in this receptacle by means of the
-other pairs of legs. The structure is unique, and is not found in any
-other insects except the bees. It is, moreover, present only in the
-worker bees, and is absent in the queen and the males.
-
-The preceding cases, in which the adapted parts are used for the
-ordinary purposes of life of the individual, are not essentially
-different from the cases in which the organ is used to protect the
-animal from its enemies. The bad taste of certain insects is supposed to
-protect them from being eaten by birds. Cases like this of passive
-protection grade off in turn into those in which, by some reflex or
-voluntary act, the animal protects itself. The bad-smelling horns of the
-caterpillar of the black swallow-tailed butterfly (_Papilio polyxenes_)
-are thrust out when the animal is touched, and it is believed that they
-serve to protect the caterpillar from attack. The fœtid secretion of the
-glands of the skunk is believed to serve as a protection to the animal,
-although the presence of the nauseous odor may lead finally to the
-extermination of the skunk by man. The sting of bees and of wasps serves
-to protect the individual from attack. The sting was originally an
-ovipositor, and used in laying the eggs. It has, secondarily, been
-changed into an organ of offence.
-
-The special instincts and reflex acts furnish a striking group of
-adaptations. The building of the spider’s web is one of the most
-remarkable cases of this kind. The construction of the web cannot be the
-result of imitation, since, in many instances, the young are born in the
-spring of the year following the death of the parents. Each species of
-spider has its own type of web, and each web has as characteristic a
-form as has the spider itself. It is also important to find that a
-certain type of web may be characteristic of an entire family of
-spiders. Since, in many cases, the web is the means of securing the
-insects used for food, it fulfils a purpose necessary for the welfare of
-the spider.
-
-The making of the nests by birds appears to be also in large part an
-instinctive act; although some writers are inclined to think that memory
-of the nest in which the young birds lived plays a part in their
-actions, and imitation of the old birds at the time of nest-building
-may, perhaps, also enter into the result. It has been stated that the
-first nest built by young birds is less perfect than that built by older
-birds, but this may be due to the bird’s learning something themselves
-in building their nests, _i.e._ to the perfecting of the instinct in the
-individual that makes use of it. In any case much remains that must be
-purely instinctive. The construction of the comb by bees appears to be
-largely, perhaps entirely, an instinctive act. That this is the case was
-shown by isolating young workers as soon as they emerged from the cell,
-and before they could have had any experience in seeing comb built. When
-given some wax they set to work to make a comb, and made the
-characteristic six-sided structures like those made by the bees in a
-hive. The formation of so remarkable a structure as the comb is worthy
-of admiration, for, with the greatest economy of material, a most
-perfect storeroom for the preservation of the honey is secured. This
-adaptation appears almost in the nature of foresight, for the store of
-honey is used not only to feed the young, but may be drawn on by the
-bees themselves in time of need. It is true that a comparison with other
-kinds of bees makes it probable that the comb was first made for the
-eggs and larvæ, and only later became used as a storehouse, but so far
-as its form is concerned there is the same economy of constructive
-materials in either case.
-
-The behavior of young birds, more especially those that take care of
-themselves from the moment they leave the egg, furnishes a number of
-cases of instincts that are protective. If, for example, a flock of
-young pheasants is suddenly disturbed, the birds at once squat down on
-the ground, and remain perfectly quiet until the danger is past. Their
-resemblance to the ground is so perfect that they are almost invisible
-so long as they remain quiet. If, instead of remaining still, they were
-to attempt to run away when disturbed, they would be much more easily
-seen.
-
-Certain solitary wasps (_Ammophila_) have the habit of stinging
-caterpillars and spiders, and dragging them to their nests, where they
-are stored away for the future use of the young that hatch from the eggs
-laid by the wasp on the body of the prey. As a result of the sting which
-the wasp administers to the caterpillar, the latter is paralyzed, and
-cannot escape from the hole in which it is stored, where it serves as
-food for the young wasp that emerges from the egg. It was originally
-claimed by Forel that the wasp stings the caterpillar in such a way that
-the central nervous system is always pierced, and many subsequent
-naturalists have marvelled at the perfection of such a wonderful
-instinct. But the recent results of the Peckhams have made it clear that
-the act of the wasp is not carried out with the precision previously
-supposed, although it is true that the wasp pierces the caterpillar on
-the lower surface where the ventral chain of ganglia lies. The habit of
-this wasp is not very dissimilar from that shown by many other kinds of
-wasps that sting their captive in order to quiet it. We need not imagine
-in this case that the act carries with it the consciousness that the
-caterpillar, quieted in this way, will be unable to escape before the
-young wasps have hatched.
-
-The resemblance in color of many animals to their natural backgrounds
-has in recent years excited the interest and imagination of many
-naturalists. The name of protective coloration has been given to this
-group of phenomena. The following cases which have less the appearance
-of purely imaginative writing may serve by way of illustration. A
-striking example is that of the ptarmigan which has a pure white coat in
-winter, and a brown coat in summer. The white winter plumage renders the
-animal less conspicuous against the background of snow, while in summer
-the plumage is said to closely resemble the lichen-covered ground on
-which the bird rests. The snowy owl is a northern bird, whose color is
-supposed to make it less conspicuous, and may serve either as a
-protection against enemies, or may allow the owl to approach its prey
-unseen. It should not pass unnoticed, however, that there are white
-birds in other parts of the world, where their white color cannot be of
-any use to them as a protection. The white cockatoos, for example, are
-tropical birds, living amongst green foliage, where their color must
-make them conspicuous, rather than the reverse.
-
-The polar bear is the only member of the family that is white, and while
-this can scarcely be said to protect it from enemies, because it is
-improbable that it has anything to fear from the other animals of the
-ice-fields, yet it may be claimed that the color is an adaptation to
-allow the animal to approach unseen its prey.
-
-In the desert many animals are sand-colored, as seen for instance in the
-tawny color of the lion, the giraffe, the antelopes, and of many birds
-that live on or near the ground.
-
-It has been pointed out that in the tropics and temperate zones there
-are many greenish and yellowish birds whose colors harmonize with the
-green and yellow of the trees amongst which they live; but on the other
-hand we must not forget that in all climes there are numbers of birds
-brilliantly colored, and many of these do not appear to be protected in
-any special way. The tanagers, humming-birds, parrots, Chinese
-pheasants, birds of paradise, etc., are extremely conspicuous, and so
-far as we can see they must be much exposed on account of the color of
-their plumage. Whether, therefore, we are justified in picking out
-certain cases as examples of adaptation, because of an agreement in
-color between the organism and its surroundings, and in neglecting all
-others, is, as has been already said, a point to be further examined.
-
-Not only among mammals and birds have many cases of protective
-coloration been described by writers dealing with this subject, but in
-nearly every group of the animal kingdom similar cases have been
-recognized. The green and brown color of lizards may protect them, the
-green color of many frogs is supposed to conceal them as they sit
-amongst the plants on the edge of a stream or pond. The gray-brown color
-of the toad has been described as a resemblance to the dry ground, while
-the brilliant green of several tree-frogs conceals them very effectively
-amongst the leaves. Many fishes are brilliantly colored, and it has even
-been suggested that those living amongst corals and sea-anemonies have
-acquired their colors as a protection, but Darwin states that they
-appeared to him very conspicuous even in their highly colored
-environment.
-
-Amongst insects innumerable cases of adaptive coloration have been
-described. In fact this is the favorite group for illustrating the
-marvels of protective coloration. A few examples will here serve our
-purpose. The oft-cited case of the butterfly _Kallima_ is, apparently, a
-striking instance of protective resemblance. When at rest the wings are
-held together over the back, as in nearly all butterflies, so that only
-the under surface is exposed. This surface has an unquestionably close
-resemblance to a brown leaf. It is said on no less authority than that
-of Wallace that when this butterfly alights on a bush it is almost
-impossible to distinguish between it and a dead leaf. The special point
-in the resemblance to which attention is most often called is the
-distinct line running obliquely across the wings which looks like the
-midrib of a leaf. Whether the need of such a close resemblance to a leaf
-is requisite for the life of this butterfly, we do not know, of course,
-and so long as we do not have this information there is danger that the
-case may prove too much, for, if it should turn out that this remarkable
-case is accidental the view in regard to the resemblance may be
-endangered.
-
-Amongst caterpillars there are many cases of remarkable resemblances in
-color between the animal and its surroundings. The green color of many
-of those forms that remain on the leaves of the food-plant during the
-day will give, even to the most casual observer, the impression that the
-color is for the purpose of concealment; and that it does serve to
-conceal the animal there can be no doubt. But even from the point of
-view of those who maintain that this color has been acquired because of
-its protective value it must be admitted that the color is insufficient,
-because some of these same green caterpillars are marvellously armed
-with an array of spines which are also supposed to be a protection
-against enemies. Equally well protected are the brown and mottled
-geometrid caterpillars. These have, moreover, the striking and unusual
-habit of fixing themselves by the posterior pairs of false legs, and
-standing still and rigid in an oblique position on the twigs to which
-they are affixed. So close is their resemblance to a short twig, that
-even when their exact position is known it is very difficult to
-distinguish them.
-
-Grasshoppers that alight on the ground are, in many cases, so similar to
-the surface of the ground that unless their exact location is known they
-easily escape attention, while the green color of the katydid, a member
-of the same group of orthoptera, protects it from view in the green
-foliage of the trees where it lives. The veinlike wings certainly
-suggest a resemblance to a leaf, but whether there is any necessity for
-so close an imitation may be questioned.
-
-There can be little doubt in some of these cases that the color of the
-animal may be a protection to it, but as has been hinted already, it is
-another question whether it acquired these colors because of their
-usefulness. Nevertheless, if the color is useful to its possessor, it is
-an adaptation in our sense of the word, without regard to the way in
-which it has been acquired. Even, for instance, if the resemblance were
-purely the outcome of chance in the sense that the color appeared
-without relation to the surroundings, it would still be an adaptation if
-it were of use to the animal under the ordinary conditions of life.
-
-In the lower groups numerous cases in which animals resemble their
-surroundings could be given. Such cases are known in crustacea, worms,
-mollusks, hydroids, etc., and the possible value of these resemblances
-may be admitted in many instances.
-
-It is rather curious that so few cases of adaptive coloration have been
-described for plants. No one supposes that the slate color of the lichen
-is connected with the color of the rocks on which it grows, in the sense
-that the resemblance is of any use to the lichen. Nor does the color of
-the marine red algæ serve in any way to protect the plants so far as is
-known. The green color of nearly all the higher plants is obviously
-connected with the substance, chlorophyl, that is essential for the
-processes of assimilation, and has no relation to external objects. But
-when we come to the colors of flowers we meet with curious cases of
-adaptation, at least according to the generally accepted point of view.
-For it is believed by many naturalists that the color of the corolla of
-flowering plants is connected with the visits of insects to the flowers,
-and these visits are in many cases essential for the cross-fertilization
-of the flowers. This adaptation is one useful to the species, rather
-than the individual, and belongs to another category.
-
-The leaf of the Venus’s fly-trap, which suddenly closes together from
-the sides when a fly or other light body comes to rest on it, is
-certainly a remarkable adaptation. A copious secretion of a digestive
-fluid is poured out on the surface of the leaf, and the products of
-digestion are absorbed. There can be no question that this contrivance
-is of some use to the plant. In other insectivorous plants, the pitcher
-plants, the leaves are transformed into pitchers. In Nepenthes a
-digestive fluid is secreted from the walls. A line of glands secreting a
-sweet fluid serves to attract insects to the top of the pitcher, whence
-they may wander or fall into the fluid inside, and there being drowned,
-they are digested. A lidlike cover projecting over the opening of the
-pitcher is supposed to be of use to keep out the rain.
-
-In _Utricularia_, a submerged water-plant, the tips of the leaves are
-changed into small bladders, each having a small entrance closed by an
-elastic valve opening inwards. Small snails and crustaceans can pass
-into this opening, to which they are guided by small outgrowths; but
-once in the cup they cannot get out again, and, in fact, small animals
-are generally found in the bladders where they die and their substance
-is absorbed by forked hairs projecting into the interior of the bladder.
-
-The cactus is a plant that is well suited to a dry climate. Its leaves
-have completely disappeared, and the stem has become swollen into a
-water-reservoir. “It has been estimated that the amount of water
-evaporated by a melon cactus is reduced to one six-hundredth of that
-given off by any equally heavy climbing-plant.”
-
-
-[Illustration:
-
-  Fig. 1.—The fertilization of _Aristolochia Clematitis_.
-  A, portion of stem with flowers in axil of leaf in different stages.
-  B and C, longitudinal sections of two flowers, before and after
-    fertilization. (After Sachs.)]
-
-
-Sachs gives the following account of the fertilization process in
-_Aristolochia Clematitis_, which he refers to as a conspicuous and
-peculiar adaptation. In Figure 1 A a group of flowers is shown, and in
-Figure 1 B and C a single flower is split open to show the interior. In
-B a small fly has entered, and has brought in upon its back some pollen
-that has stuck to it in another flower. The fly has entered through the
-long neck which is beset with hairs which are turned inwards so that the
-fly can enter but cannot get out. In roaming about, the pollen that is
-sticking to its back will be rubbed against the stigmatic surface. “As
-soon as this has taken place the anthers, which have been closed
-hitherto, dehisc and become freely accessible,” as a result in the
-change in the stigma and of the collapse of the hairs at the base of the
-enlargement which has widened. The fly can now crawl under the anthers,
-and, if it does so, new pollen may stick to its back. At this time the
-hairs in the throat dry up, and the fly can leave its prison house,
-Figure 1 C. If the fly now enters another flower this is fertilized by
-repeating the process. The unfertilized flowers stand erect with widely
-open mouths. As soon as they have been fertilized they bend down, as
-seen in Figure 1 A, and at the same time the terminal flap bends over
-the open mouth of the throat, “stopping the entrance to the flies, which
-have now nothing more to do here.”
-
-
-      Adjustments of the Individual to Changes in the Environment
-
-The most familiar cases of adjustments of the individual to the
-environment are those that we recognize in our own bodies. After violent
-exercise we breathe more rapidly, and take deeper inspirations. Since
-during exercise our blood loses more oxygen and takes in more carbon
-dioxide from the muscles, it is clear that one result of more rapid
-breathing is to get more oxygen into the blood and more carbon dioxide
-out of it. The process of sweating, that also follows exercise, may be
-also looked upon as an adaptive process, since by evaporation the skin
-is kept cooler, and, in consequence, the blood, which at this time flows
-in larger quantities to the skin, is cooled also.
-
-More permanent adaptive changes than these also take place as the result
-of prolonged use of certain parts. If the muscles work against powerful
-resistance, they become larger after several days or weeks, and are
-capable of doing more work than at first. Conversely, when any group of
-muscles is not used, it becomes smaller than the normal and capable of
-doing less work. It would be a nice point to decide whether this latter
-change is also an adaptation. If so it is one in a somewhat different
-sense from that usually employed. The result is of no direct advantage
-to the animal, except possibly in saving a certain amount of food, but
-since the same change will take place when an abundance of food is
-consumed, the result is, under these conditions, of no use.
-
-The thickening of the skin on those parts of the body where continued
-pressure is brought to bear on it is a change in a useful direction. The
-thickening on the soles of the feet and on the palms of the hands is a
-case in point. Not only is the skin thicker at birth in these parts, but
-it becomes thicker through use. In other parts of the body also, the
-skin hardens and becomes thicker if pressure is brought to bear on it.
-We may regard this as a general property of the skin, which is present
-even in those parts where, under ordinary circumstances, it can rarely
-or never be brought into use.
-
-Even as complicated and as much used an organ as the eye can become
-adaptively improved. It is said that the lateral region of the field of
-vision can be trained to perceive more accurately; and every one who has
-used a microscope is familiar with the fact that if one eye is
-habitually used it becomes capable of seeing more distinctly and better
-than the other eye. This seems to be due, in part at least, to the
-greater contraction of the iris.
-
-Another phenomenon, which, I think, must be looked upon as an
-adaptation, is the immunity to certain poisons that can be gradually
-brought about by slowly increasing the amount introduced into the body.
-Nicotine is a most virulent poison, and yet by slowly increasing the
-dose an animal can be brought into a condition in which an amount of
-nicotine, fatal to an ordinary individual, can be administered without
-any ill effects at all resulting.
-
-The same phenomenon has been observed in the case of other poisons, not
-only in case of other alkaloids, such as morphine and cocaine, but also
-in the case of caffein, alcohol, and even arsenic. There is a curious
-phenomenon in regard to arsenic, which appears to be well established,
-viz., that a person who has gradually increased the dose to an amount
-great enough to kill ten ordinary men, will die if he suddenly ceases
-altogether to take arsenic. He can, however, be gradually brought back
-to a condition in which arsenic is not necessary for his existence, if
-the dose is gradually decreased. It is a curious case of adaptation that
-we meet with here, since the man becomes so thoroughly adjusted to a
-poison that if he is suddenly brought back to the normal condition of
-the race he will die.
-
-Immunity to the poison of venomous snakes can also be acquired by slowly
-increasing the amount given to an animal. It is possible to make a
-person so immune to the poison of venomous snakes that he would become,
-in a sense, adapted to live amongst them without danger to himself. It
-is to be noted, moreover, that this result could be reached only by
-quite artificial means, for, under natural conditions it is
-inconceivable that the nicely graded series of doses of increasing
-strength necessary to bring about the immunity could ever be acquired.
-Hence we find here a case of response in an adaptive direction that
-could not have been the outcome of experience in the past. It is
-important to emphasize this capacity of organisms to adapt themselves to
-certain conditions entirely new to them.
-
-These cases lead at once to cases of immunity to certain bacterial
-diseases. An animal may become immune to a particular disease in several
-ways. First, by having the disease itself, which renders it immune for a
-longer or a shorter period afterwards; or, second, by having a mild form
-of the disease as in the case of smallpox, where immunity is brought
-about by vaccination, _i.e._ by giving the individual a mild form of
-smallpox; or, third, by introducing into the blood an antidote, in the
-form, for example, of antitoxin, which has been made by another animal
-itself immune to the disease. The first two classes of immunity may be
-looked upon as adaptations which are of the highest importance to the
-organism; the last case can scarcely be looked upon as an adaptive
-process, since the injurious effect of the poison may as well be
-neutralized outside of the body by mixing it with the antitoxin. We may
-suppose, then, that in the body a similar process goes on, so that the
-animal itself takes no active part in the result.
-
-When we consider that there are a number of bacterial diseases, in each
-of which a different poison is made by the bacteria, we cannot but ask
-ourselves if the animal really makes a counter-poison for each disease,
-or whether a single substance may not be manufactured that counteracts
-all alike? That the latter is not the case is shown by the fact that an
-animal made immune to one disease is not immune to others. When we
-recall that the animal has also the capacity to react in one way or
-another to a large number of organic and inorganic poisons, to which it
-or its ancestors can have had little or no previous experience, we may
-well marvel at this wonderful regulative power.
-
-The healing of wounds, which takes place in all animals, forms another
-class of adaptive processes. The immense usefulness of this power is
-obvious when it is remembered how exposed most animals are to injuries.
-By repairing the injury the animal can better carry on its normal
-functions. Moreover, the presence of the wound would give injurious
-bacteria a ready means of entering the body. In fact, an intact skin is
-one of the best preventives to the entrance of bacteria.
-
-Not only have most organisms the power of repairing injuries, but many
-animals have also the closely related power of regenerating new parts if
-the old ones are lost. If a crab loses its leg, a new one is
-regenerated. If a fresh-water worm (_Lumbriculus_) is cut into pieces,
-each piece makes a new head at its anterior end and a new tail at the
-posterior end. In this way as many new worms are produced as there are
-pieces. And while in a strict sense it cannot be claimed that this power
-of regeneration is of any use to the original worm, since the original
-worm, as such, no longer exists, yet since it has not died but has
-simply changed over into several new worms, the process is of use
-inasmuch as by this means the pieces can remain in existence.
-
-We need not discuss here the relative importance to different animals of
-this power of regeneration, but it may be stated, that, while in some
-cases it may be necessary to replace the lost part if the animal is to
-remain in existence, as when a new head is formed on an earthworm after
-the old one was cut off, in other cases the replacement of the lost part
-appears to be of minor importance, as in the case of the leg of the
-crab. While we are not, for the moment, concerned with the relative
-importance of the different adaptations, this question is one of much
-importance in other connections and will be considered later.
-
-The protective coloration of some animals, which is the direct result of
-a change in color of the animal in response to the surroundings,
-furnishes us with some most striking cases of adaptive coloration. A
-change of this sort has been recorded in a number of fishes, more
-especially in the flounders. The individuals found living on a dark
-background are darker than those living on a lighter background; and
-when the color of the background is changed it has been observed that
-the color of the fish also changes in the same direction. I have
-observed a change of this sort from dark to light, or from light to
-dark, in the common minnow (_Fundulus_) in accordance with a change of
-its background, and the same sort of change appears to take place in
-many other fishes.
-
-The change from green to brown and from brown to green in certain tree
-frogs and in the lizard (_Anolis_), which is popularly supposed to take
-place according to whether the background is green or brown, is not
-after all, it appears, connected with the color of the background, but
-depends on certain other responses of the animals that have not yet been
-satisfactorily made out. If it be claimed that in summer the animal
-would generally be warm, and therefore, often green, and that this color
-would protect it at this time of year when the surroundings are green,
-and in winter brown, when this color is the prevailing one in temperate
-regions, then it might appear that the change is of use to the animal;
-but if it is true that the same change takes place in some of the
-lizards that live in the tropics, where the prevailing color is always
-green, it would appear that the result may have no direct relation with
-the surroundings. It has been shown in a number of well-authenticated
-cases that the pupæ of certain butterflies vary in color within certain
-limits in response to the color of the background. When the caterpillar
-fixes itself to some surface, and there throws off the outer skin, and
-acquires a new one, the color of the latter is influenced by the
-background. The result is a better protection to the pupa. The change is
-not brought about through the ocelli or eyes, but through the general
-surface of the skin, for the same change takes place when the eyes have
-been previously covered with a dark pigment.
-
-The growth of plants toward the light may be looked upon as an adaptive
-process, since only in the light can they find the conditions necessary
-for their life. The extraordinary elongation of shoots and young plants
-when grown in the dark may also be considered an adaptation for finding
-the light, since in this way a plant, deeply embedded in the ground, may
-ultimately reach the surface. Thus while the actual process of
-elongation in the dark is not in itself of any use, yet under the
-ordinary conditions of its life, this response may be of great benefit
-to the plant.
-
-The closing together of the leaves of some plants has been supposed
-to protect them from too rapid radiation of heat, and incidentally
-this purpose may be fulfilled; but since some tropical plants also
-close their leaves during the night, it can hardly be maintained
-that the closing has been acquired for this purpose. It has been
-suggested that the opening of certain flowers under certain
-conditions of light is connected with the visits of insects that
-bring about cross-fertilization.
-
-The preceding examples will suffice to give a general idea of what is
-meant by adaptation in organisms. That the term includes a large number
-of phenomena of very different kinds is apparent. When we have examined
-these phenomena further we shall find, I think, that it will be
-necessary to put some of them into different categories and treat them
-differently. It is probably incorrect to suppose that all processes
-useful to the organism have been acquired in the same way, nevertheless,
-for the present the term adaptation is sufficiently general, even if
-vague, to cover these different groups of cases.
-
-It may be asked, in what respects are these structures and processes of
-adaptation different from the ordinary structures and changes that go on
-in the organism? Why is the leg of the mole more of an adaptation than
-that of a dog? The one is of as much use as the other to its possessor.
-What reason can we give for citing the poison of the snake, and not
-mentioning in the same connection the other glands of the body? In fact,
-the poison gland of the snake is supposed to be a modified superior
-labial gland. Why, in short, are not the processes of digestion,
-excretion, secretion, the beating of the heart, the ordinary reflex acts
-of the nervous system, and the action of the sense-organs, as truly
-adaptations as the special cases that have been selected for
-illustration. The answer is simply that we are more impressed by those
-cases of adaptation that are more unusual, as when an animal departs in
-the use of certain structures from the rest of the group to which it
-belongs. For example, if all mammals lived underground, ourselves
-included, and the fore-legs or arms were used for burrowing, we should
-not think this unusual; but if we found an animal using all four legs to
-support the body and for purposes of progression, we should, most
-likely, think this was an excellent illustration of adaptation.
-
-In other instances the condition is somewhat different. The color of
-certain animals may unquestionably be of use to them in concealing them
-from their enemies. In other cases the color may not serve this purpose,
-or any purpose at all. Thus while in the former case we speak of the
-color as an adaptation to the surroundings, in the latter we do not
-think of it as having any connection at all with the environment. Even
-in the same animal the color of different parts of the body may appear
-under this twofold relation. For example, the green color of the skin of
-the frog renders it less conspicuous amongst the green plants on the
-edge of the stream, but the brilliant orange and black pigment in the
-body-cavity cannot be regarded as of any use to the animal.
-
-
-                Adaptations for the Good of the Species
-
-Aside from the class of adaptations that are for the good of the
-individual, there is another class connected solely with the
-preservation of the race. The organs for reproduction are the most
-important examples of this kind. These organs are of no use to the
-individual for maintaining its own existence, and, in fact, their
-presence may even be deleterious to the animal. The instincts connected
-with the use of these organs may lead inevitably to the death of the
-individual, as in the case of the California salmon, which, on entering
-fresh water in order to deposit its eggs, dies after performing this
-act.
-
-The presence of the organs of reproduction in the individual is
-obviously connected with the propagation of other individuals. Indeed in
-many organisms the life of the individual appears to have for its
-purpose the continuation of the race. In a large number of animals the
-individual dies after it has deposited its eggs. The most striking case
-is that of the May-flies, whose life, as mature individuals, may last
-for only a few hours. The eggs are set free by the bursting of the
-abdomen, and the insect dies. The male bee also dies after union with
-the queen. In some annelids, the body is also said to burst when the
-eggs are set free; and in other forms those parts of the body containing
-the eggs break off, and, after setting free the eggs, die. These are
-extreme cases of what is seen in many animals, namely the replacement of
-the old individuals by a new generation; and while in general there is
-only a loose connection between the death of the individual and the
-consummation of its reproductive power, yet the two run a course so
-nearly parallel that several writers have attempted to explain this
-connection as one of racial adaptation.
-
-It has also been pointed out that in those higher animals that take care
-of their young after birth, the life of the individual does not end with
-the period of birth of the young, but extends at least throughout the
-time necessary to care for the young. It has even been suggested that
-this lengthening of the life period has been acquired on account of its
-use to the species. When, however, as in the case of the vertebrates,
-the young are born at intervals either in great numbers at a birth, as
-in fishes and amphibia, or in lots of twos, threes, or fours, as in many
-birds and mammals, or even only one at a time, as in a few birds and in
-man, it will be evident that the relation cannot be so simple as has
-been supposed. It cannot be assumed in these forms that the end of the
-life of the individual is in any way connected with the ripening of the
-last eggs, for, on the contrary, hundreds, or even many thousands, of
-potential eggs may be present in the ovaries when the animal is
-overtaken by old age, and its power of reproduction lost.
-
-In regard to several of the lower animals, we find, in a number of cases
-where there are accurate data, that the individual goes on year after
-year producing young. Whether they ever grow old, in the sense of losing
-their power of reproduction, has not been definitely determined, but
-there is, so far as I know, no evidence to show that such a process
-takes place, and these animals appear to have the power of reproducing
-themselves indefinitely.
-
-The phenomenon of old age (apart from its possible connection with the
-cessation of the power of reproduction), which leads to the death of the
-individual, has been looked upon by a few writers as an adaptation of
-the individual for the good of the species. It has been pointed out by
-these writers that the longer an individual lives, the more likely it is
-to become damaged, and if along with this its powers of reproduction
-diminish, as compared with younger individuals, then it stands in the
-way and takes food that might be used by other, younger individuals,
-that are better able to carry on the propagation of the race. It is
-assumed, therefore, that the life of the individual has been shortened
-for the benefit of the race. Whether such a thing is probable is a
-question that will also be discussed later. We are chiefly concerned
-here only in recording the different groups of phenomena that have been
-regarded by biologists as adaptations.
-
-The so-called secondary sexual characters such as the brighter colors of
-the males, ornaments of different kinds, crests, color-pattern, tail
-feathers, etc., organs of offence and of defence used in fighting
-members of the same species, present a rather unique group of
-adaptations. These characters are supposed to be of use to the
-individual in conquering its rivals, or in attracting the females. They
-may be considered as useful to the individual in allowing it to
-propagate at the expense of its rivals, but whether the race is thereby
-benefited is a question that will be carefully considered later.
-
-The colors of flowers, that is supposed to attract insects, have been
-already mentioned. The sweet fluid, or nectar, secreted by many flowers
-is sought by insects, which on entering the flowers bring about
-cross-fertilization. Thus while the nectar seems to be of no immediate
-service to the plant itself, it is useful to the species in bringing
-about the fertilization of the flowers. The odors of flowers also serve
-to attract insects, and their presence is one of the means by which
-insects find the flowers. This also is of advantage to the race.
-
-
-                 Organs of Little Use to the Individual
-
-In every organism there are parts of the body whose presence cannot be
-of vital importance to the individual. We may leave out of consideration
-the reproductive organs, since their presence, as has just been stated,
-is connected with the continuation of the race. The rudimentary organs,
-so-called, furnish many examples of structures whose presence may be of
-little or of no use to the individual; in fact, as in the case of the
-appendix in man, the organs may be a source of great danger to the
-individual. In this respect the organism is a structure not perfectly
-adapted to its conditions of life, since it contains within itself parts
-that are of little or of no use, which may even lead to its destruction,
-and may often expose it to unnecessary danger. Nevertheless such parts
-are surprisingly infrequent, and their presence is usually accounted for
-on the supposition that in the past these organs have been of use, and
-have only secondarily come to play an insignificant part in the
-functions of the organism. Another example of the same thing is found in
-the rudimentary eyes of animals living in the dark, such as the mole and
-several cave animals, fishes, amphibia, and insects.
-
-There are still other organs, which cannot be looked upon as
-rudimentary, yet whose presence can scarcely be considered as essential
-to the life of the individual. It is with this class that we are here
-chiefly concerned. For instance, the electric organs in some of the rays
-and fish can hardly protect the animal from enemies, even when as highly
-developed as in the torpedo; and we do not know of any other essential
-service that they can perform. Whether the same may be also said of the
-phosphorescent organs of many animals is perhaps open in some cases to
-doubt, but there can be little question that the light produced by most
-of the small marine organisms, such as noctiluca, jellyfish,
-ctenophores, copepods, pyrosoma, etc., cannot be of use to these animals
-in protecting them from attack. In the case of certain bacteria it seems
-quite evident that the production of light can be of no use as such to
-them. The production of light may be only a sort of by-product of
-changes going on in the organism, and have no relation to outside
-conditions. In certain cases, as in the glowworm, it has been supposed
-that the display may serve to bring the sexes together; but since the
-phosphorescent organs are also present in the larval stages of the
-glowworm, and since even the egg itself is said to be phosphorescent, it
-is improbable, in these stages at least, that the presence of the light
-is of service to the organism.
-
-It has been pointed out that the colors of certain animals may serve to
-conceal them and may be regarded as an adaptation; but it is also true
-that in many cases the color of the whole animal or the color of special
-parts can be of little if any direct use. While it is difficult to show
-that the wonderful patterns and magnificent coloration of many of the
-larger animals are not of service to the animal, however sceptical we
-may be on the subject, yet in the case of many microscopical forms that
-are equally brilliantly colored there can be little doubt that the
-coloration can be of no special service to them. If it be admitted that
-in these small forms the color and the color patterns are not
-protective, we should at least be on our guard in ascribing off-hand to
-larger forms a protective value in their coloration, unless there is
-actual proof that it serves some purpose.
-
-We also see in other cases that the presence of color need not be
-connected with any use that it bears as such to the animal. For
-instance, the beautiful colors on the inside of the shells of many
-marine snails and of bivalve mollusks, can be of no use to the animal
-that makes the shell, because as long as the animal is alive this color
-cannot be seen from the outside. This being the case let us not jump too
-readily to the conclusion that when other shells are colored on the
-outer surface that this must be of use to the mollusk.
-
-In regard to the colors of plants, there are many cases of brilliant
-coloration, which so far as we can see can be of no service to the
-organism. In such forms as the lichens and the toadstools, many of which
-are brilliantly colored, it is very doubtful if the color, as such, is
-of any use to the plant. The splendid coloring of the leaves in the
-autumn is certainly of no service to the trees.
-
-It should not pass unnoticed in this connection that the stems and the
-trunks of shrubs and of trees and also many kinds of fruits and nuts are
-sometimes highly colored. It is true that some of the latter have been
-supposed to owe their color to its usefulness in attracting birds and
-other animals which, feeding on the fruit, swallow the seeds, and these,
-passing through the digestive tract and falling to the ground, may
-germinate. The dissemination of the seeds of such plants is supposed to
-be brought about in this way; and since they may be widely disseminated
-it may be supposed that it is an advantage to the plant to have
-attracted the attention of the fruit-eating birds. On the other hand one
-of the most brilliantly colored seeds, the acorn, is too large to pass
-through the digestive tracts of birds, and is, in fact, ground to pieces
-in the gizzard, and in the case of several mammals that feed on the
-acorns, the acorn is crushed by the teeth. It would seem, therefore,
-that its coloration is injurious to it rather than the reverse, as it
-leads to its destruction. It has been suggested by Darwin that since the
-acorns are for a time stored up in the crop of the bird, the passenger
-pigeon for example, and since the birds may be caught by hawks and
-killed, the seeds in the crop thus become scattered. Consequently it may
-be, after all, of use to the oak to produce colored acorns that attract
-the attention of these pigeons. This suggestion seems too far-fetched to
-consider seriously. In the case of the horse-chestnut the rich brown
-color is equally conspicuous, but the nut is too large to be swallowed
-by any of the ordinary seed-feeding birds or mammals. Shall we try to
-account for its color on the grounds of the poisonous character of the
-seed? Has it been acquired as a warning to those animals that have eaten
-it once, and been made sick or have died in consequence? I confess to a
-personal repugnance to imaginative explanations of this sort, that have
-no facts of experience to support them.
-
-
- Changes in the Organism that are of No Use to the Individual or to the
-                                  Race
-
-As an example of a change in the organism that is of no use to it may be
-cited the case of the turning white of the hair in old age in man and in
-several other mammals. The absorption of bone at the angle of the chin
-in man, is another case of a change of no immediate use to the
-individual. We also find in many other changes that accompany old age,
-processes going on that are of no use to the organism, and which may, in
-the end, be the cause of its death. Such changes, for instance, as the
-loss of the vigor of the muscles, and of the nervous system, the
-weakening of the heart, and partial failure of many of the organs to
-carry out their functions. These changes lead sooner or later to the
-death of the animal, in consequence of the breaking down of some one
-essential organ, or to disease getting an easier foothold in the body.
-We have already discussed the possible relation of death as an
-adaptation, but the changes just mentioned take place independently of
-their relation to the death of the organism as a whole, and show that
-some of the normal organic processes are not for the good of the
-individual or of the race. In fact, the perversions of some of the most
-deeply seated instincts of the species, as in infanticide, while the
-outcome of definite processes in the organism, are of obvious
-disadvantage to the individual, and the perversion of so deeply seated a
-process as the maternal instinct, leading to the destruction of the
-young, is manifestly disadvantageous to the race. As soon, however, as
-we enter the field of so-called abnormal developments, the adaptive
-relation of the organism to its environment is very obscure; and yet, as
-in the case of adaptation to poisons, we see that we cannot draw any
-sharp line between what we call normal and what we call abnormal
-development.
-
-
-                  Comparison with Inorganic Phenomena
-
-The preceding examples and discussion give some idea of what is meant by
-adaptation in living things. In what respects, it may be asked, do these
-adaptations differ from inorganic phenomena? The first group of
-inorganic bodies that challenges comparison are machines. These are so
-constructed that they may be said to accomplish a definite purpose, and
-the question arises whether this purpose can be profitably compared with
-the purposefulness of the structure and response of organisms. That the
-two cannot be profitably compared is seen at once, when we recall the
-fact that the activity of the machine is of no use to it, in the sense
-of preserving its integrity. The object of the machine is, in fact, to
-perform some useful purpose for the organism that built it, namely, for
-man. Furthermore, the activity of the machine only serves to wear it
-out, and, therefore, its actions do not assist in preserving its
-integrity as do some, at least, of the activities of an animal. It is
-true, of course, that in a mechanical sense every action of the organism
-leads also to a breaking down of its structure in the same way that a
-machine is also worn out by use; but the organism possesses another
-property that is absent in the machine, namely, the power of repairing
-the loss that it sustains.
-
-One of the most characteristic features of the organism is its power of
-self-adjustment, or of regulation, by which it adapts itself to changes
-in the environment in such a way that its integrity is maintained. Most
-machines have no such regulative power, although, in a sense, the
-fly-wheel of an engine regulates the speed, and a water-bath, with a
-thermostat, regulates itself to a fixed temperature; but even this
-comparison lacks one of the essential features of the regulation seen in
-organisms, namely, in that the regulation does not protect the machine
-from injury. It may be claimed, however, that the safety valve of an
-engine does fulfil this purpose, since it may prevent the engine from
-exploding. Here, in fact, we do find better grounds for comparison, but,
-when we take into account the relation of the regulations in the
-organism to all the other properties of the organism, we see that this
-comparison is not very significant. The most essential difference
-between a machine and an organism is the power of reproduction possessed
-by the latter, which is absent in all machines. Here, however, we meet
-with a somewhat paradoxical relation, since the reproductive power of
-organisms cannot be looked upon as an adaptation for the continuation of
-the individual, but rather for the preservation of a series of
-individuals. Hence, in this respect also, we cannot profitably compare
-the individual with a machine, but if we make any comparison we should
-compare all the individuals that have come from a single one with a
-machine. In this sense the power of reproduction is a sort of racial
-regulation. A comparison of this sort is obviously empty of real
-significance.
-
-The regenerative power of the organism, by means of which it may replace
-a lost part, or by means of which a piece may become a new whole, is
-also something not present in machines.
-
-In using a machine for comparison we should not leave out of sight the
-fact that machines are themselves the work of organisms, and have been
-made for some purpose useful to the organism. They may perform the same
-purpose for which we would use our own hands, for they differ from parts
-of the body mainly in that they are made of different compounds having
-different properties, as the above comparisons have shown. But the
-regulations of the machine have been added to it by man on account of
-their usefulness to himself, and are not properties of the material of
-which the machine itself is composed. This shows, I think, the
-inappropriateness of making any comparison between these two entirely
-different things.
-
-If, then, we find the comparison between machines and organisms
-unprofitable, can we find any other things in inorganic nature that can
-be better compared with the phenomenon of adaptation of the organism?
-The following phenomena have been made the subject of comparison from
-time to time. The bendings, which are gradually made by rivers often
-lead to a meeting of the loops, so that a direct, new communication is
-established, and the course of the river is straightened out. The water
-takes, therefore, a more direct course to the sea. It cannot be said,
-however, to be of any advantage to the river to straighten its course.
-Again, a glacier moulds itself to its bed, and gradually moves around
-obstacles to a lower level, but this adaptation of the glacier to the
-form of its surroundings cannot be said to be of advantage to the
-glacier. On the contrary, the glacier reaches so much the sooner a lower
-level where it is melted.
-
-The unusual case of a solid being lighter than the liquid from which it
-forms, as seen in the case of ice, has been looked upon as a useful
-arrangement, since were the reverse the case all rivers and ponds would
-become solid in winter in cold climates, and the polar regions would
-become one solid block of ice. But no one will suppose for a moment that
-there is any relation between the anomalous condition of the lightness
-of ice, and its relation to the winter freezing of streams, ponds, etc.
-It has even been suggested that this property of ice was given to it in
-order that the animals living in the water might not be killed, which
-would be the case if the ice sank to the bottom, but such a method of
-interpreting physical phenomena would scarcely commend itself to a
-physicist.
-
-The formation of a covering of oxide over the surface of a piece of iron
-delays the further process of oxidation, but who will imagine that this
-property of iron has been acquired in order to prevent the iron from
-being destroyed by oxygen?
-
-If a piece is broken from a crystal, and the crystal is suspended in a
-saturated solution of the same substance, new material is deposited over
-its whole surface, and, as it grows larger, the broken side is completed
-and the crystal assumes its characteristic form. But of what advantage
-is it to the crystal whether it is complete or incomplete? In the case
-of an animal it is of some importance to be able to complete itself
-after injury, because it can then better obtain the food necessary to
-keep it alive, or it can better escape its enemies; but this is not the
-case with the crystal.
-
-In conclusion, therefore, it is obvious that the adaptations of
-organisms are something peculiar to living things, and their obvious
-purpose is to maintain the integrity of the individual, or that of the
-species to which the individual belongs. We are, therefore, confronted
-with the question as to how this peculiarity has come to be associated
-with the material out of which living things are made. In subsequent
-chapters this will be fully discussed, but before we take up this topic,
-it will be necessary to reach some understanding in regard to the theory
-of evolution, for the whole subsequent issue will turn upon the question
-of the origin of the forms of animals and plants living at the present
-time.
-
-
-------------------------------------------------------------------------
-
-
-
-
-                               CHAPTER II
-
-                        THE THEORY OF EVOLUTION
-
-
-One of the most important considerations in connection with the problem
-of adaptation is that in all animals and plants the individuals sooner
-or later perish and new generations take their places. Each new
-individual is formed, in most cases, by the union of two germ-cells
-derived one from each parent. As a result of this process of
-intermixing, carried on from generation to generation, all the
-individuals would tend to become alike, unless something else should
-come in to affect the result.
-
-So far as our actual experience reaches, we find that the succeeding
-generations of individuals resemble each other. It is true that no two
-individuals are absolutely alike, but if a sufficiently large number are
-examined at a given time, they will show about the same variations in
-about the same proportionate numbers. Such a group of similar forms,
-repeating itself in each generation, is the unit of the systematists,
-and is called a species.
-
-It has been said that within each species the individuals differ more or
-less from each other, but our experience teaches that in each generation
-the same kinds of variations occur, and, moreover, that from any one
-individual there may arise in the next generation any one of the
-characteristic variations. Certain limitations will have to be made in
-regard to this statement, but for the present it will suffice. The Law
-of Biogenesis states that each living thing arises from another living
-thing; that there is no life without antecedent life, _i.e._ spontaneous
-generation does not occur. The law is not concerned with the likeness or
-unlikeness of the different individuals that descend from each other.
-The theory of evolution includes the same idea, but in addition it has
-come to mean nowadays, that there have been changes, as the succeeding
-generations have arisen. The transmutation theory, and even the descent
-theory, have come to mean nearly the same thing as the theory of
-evolution. It is unfortunate that one of these terms cannot be used to
-signify simply the repetition, generation after generation, of groups of
-similar individuals. The theory of descent might be used to convey only
-this idea, but unfortunately it too has come to include also the idea of
-change. I shall attempt nevertheless to discriminate between the descent
-and the transmutation theory, and use the term _descent theory_ when I
-do not wish to convey the idea of change, and _transmutation theory_
-when I do wish to emphasize this idea.
-
-On the transmutation theory it is assumed that a group (species) may
-give rise to one or more groups of forms differing from their ancestors;
-the original group being now replaced by its new kinds of offspring, or
-the old and the new may remain in existence at the same time. This
-process repeating itself, each or some of the new groups giving rise in
-turn to one or more new species, there will be produced a larger group
-of species having certain similar characters which are due to their
-common descent. Such a group of species is called a genus. The
-resemblances of these species is accounted for by their common descent;
-but their differences must be due to those factors that have caused them
-to depart from the original type. We may now proceed to consider the
-evidence on which this idea of transmutation rests.
-
-
-             Evidence in Favor of the Transmutation Theory
-
-       EVIDENCE FROM CLASSIFICATION AND FROM COMPARATIVE ANATOMY
-
-It does not require any special study to see that there are certain
-groups of animals and of plants that are more like each other than they
-are like the members of any other group. It is obvious to every one that
-the group known as mammals has a combination of characters not found in
-any other group; such, for instance, as a covering of hair, mammary
-glands that furnish milk to the young, and a number of other less
-distinctive features. These and other common characteristics lead us to
-put the mammals into a single class. The birds, again, have certain
-common characters such as feathers, a beak without teeth, the
-development of a shell around the egg, etc., and on account of these
-resemblances we put them into another class. Everywhere in the animal
-and plant kingdoms we find large groups of similar forms, such as the
-butterflies, the beetles, the annelidan worms, the corals, the snails,
-the starfishes, etc.
-
-Within each of these groups we find smaller groups, in each of which
-there are again forms more like each other than like those of other
-groups. We may call these smaller groups families. Within the families
-we find smaller groups, that are more like each other than like any
-other groups in the same family, and these we put into genera. Within
-the genus we find smaller groups following the same rule, and these are
-the species. Here we seem to have reached a limit in many cases, for we
-do not always find within the species groups of individuals more like
-each other than like other groups. Although we find certain differences
-between the individuals of a species, yet the differences are often
-inconstant in the sense that amongst the descendants of any individual
-there may appear any one of the other variations. If this were the whole
-truth, it would seem that we had here reached the limits of
-classification, the species being the unit. This, however, is far from
-being the case, for, in many species we find smaller groups, often
-confined to special localities. These groups are called varieties.
-
-In some cases it appears, especially in plants, these smaller groups of
-varieties resemble in many ways the groups of species in other forms,
-since they breed true to their kind, even under changed conditions. They
-have been recognized as “smaller species” by a number of botanists.
-
-In this connection a point must be brought up that has played an
-important rôle in all discussion as to what limits can be set to a
-species. As a rule it is found that two distinct species cannot be made
-to cross with each other, _i.e._ the eggs of an individual of one
-species cannot be fertilized by spermatozoa derived from individuals of
-another species; or, at least, if fertilization takes place the embryo
-does not develop. In some cases, however, it has been found possible to
-cross-fertilize two distinct species, although the offspring is itself
-more or less infertile. Even this distinction, however, does not hold
-absolutely, for, in a few cases, the offspring of the cross is fertile.
-It cannot be maintained, therefore, that this test of infertility
-between species invariably holds, although in a negative sense the test
-may apply, for if two different forms are infertile, _inter se_, the
-result shows that they are distinct species. If they cross they may or
-may not be good species, and some other test must be used to decide
-their relation.
-
-We should always keep in mind the fact that the individual is the only
-reality with which we have to deal, and that the arrangement of these
-into species, genera, families, etc., is only a scheme invented by man
-for purposes of classification. Thus there is no such thing in nature as
-a species, except as a concept of a group of forms more or less alike.
-In nature there are no genera, families, orders, etc. These are
-inventions of man for purposes of classification.
-
-Having discovered that it is possible to arrange animals and plants in
-groups within groups, the question arises as to the meaning of this
-relation. Have these facts any other significance than that of a
-classification of geometric figures, or of crystals according to the
-relations of their axes, or of bodies as to whether they are solids,
-liquids, or gases, or even whether they are red, white, or blue?
-
-If we accept the transmutation view, we can offer an explanation of the
-grouping of living things. According to the transmutation theory, the
-grouping of living things is due to their common descent, and the
-greater or less extent to which the different forms have diverged from
-each other. It is the belief in this principle that makes the
-classification of the biologist appear to be of a different order from
-that in any other science; and it is this principle that appears to give
-us an insight into a large number of phenomena.
-
-For example, if, as assumed in the theory, a group of individuals
-(species) breaks up into two groups, each of these may be supposed to
-inherit a large number of common characteristics from their ancestors.
-These characters are, of course, the resemblances, and from them we
-conclude that the species are related and, therefore, we put them into
-the same genus. The differences, as has been said, between the species
-must be explained in some other way; but the principle of classification
-with which we are here concerned is based simply on the resemblances,
-and takes no account of the differences between species.
-
-In this argument it has been tacitly assumed that the transformation of
-one species into another, or into more than one, takes place by adding
-one or more new characters to those already present, or by changing over
-a few characters without altering others. But when we come to examine
-any two species whatsoever, we find that they differ, not only in one or
-in a few characters, but in a large number of points; perhaps in every
-single character. It is true that sometimes the differences are so small
-that it is difficult to distinguish between two forms, but even in such
-cases the differences, although small, may be as numerous as when they
-are more conspicuous. If, then, this is what we really find when we
-carefully examine species of animals or of plants, what is meant when we
-claim that our classification is based on the characters common to all
-of the forms that have descended from the same ancestor? We shall find,
-if we press this point that, in one sense, there is no absolute basis of
-this sort for our classification, and that we have an unreal system.
-
-If this is admitted, does our boasted system of classification, based as
-it is on the principle of descent, give us anything fundamentally
-different from an artificial classification? A few illustrations may
-make clearer the discussion that follows. If, for example, we take a
-definition of the group of vertebrates we read: “The group of craniate
-vertebrates includes those animals known as Fishes, Amphibians,
-Reptiles, Birds, and Mammals; or in other words, Vertebrates with a
-skull, a highly complex brain, a heart of three or four chambers, and
-red blood corpuscles.” If we attempt to analyze this definition, we find
-it stated that the skull is a characteristic of all vertebrates, but if
-we ask what this thing is that is called skull, we find not only that it
-is something different in different groups, being cartilaginous in
-sharks, and composed of bones in mammals, but that it is not even
-identical in any two species of vertebrates. If we try to define it as a
-case of harder material around the brain, then it is not something
-peculiar to the vertebrates, since the brain of the squid is also
-encased in a cartilaginous skull. What has been said of the skull may be
-said in substance of the brain, of the heart, and even of the red blood
-corpuscles.
-
-If we select another group, we find that the birds present a sharply
-defined class with very definite characters. The definition of the group
-runs as follows: “Birds are characterized by the presence of feathers,
-their fore-limbs are used for flight, the breast-bone is large and
-serves for the attachment of the muscles that move the wings; outgrowths
-from the lungs extend throughout the body and even into the bones and
-serve as air sacs which make the body more buoyant. Only one aortic arch
-is present, the right, and the right ovary and oviduct are not
-developed. The eyes are large and well developed. Teeth are absent. We
-have here a series of strongly marked characteristics such as
-distinguish hardly any other class. Moreover, the organization of
-existing birds is, in its essential features, singularly uniform; the
-entire class presenting less diversity of structure than many orders of
-Fishes, Amphibians, and Reptiles.”[1] The feathers are the most unique
-features of birds, and are not found in any other group of the animal
-kingdom; moreover the plan on which they are formed is essentially the
-same throughout the group, yet in no two species are the feathers
-identical, but differ not only in form and proportions, but even in the
-character of the barbs and hooks for holding the vane together. The
-modification of the fore-limbs for flight is another characteristic
-feature; yet in some birds, as the ostrich and kiwi, although the wing
-has the same general plan as in other birds, it is not used for flight.
-In the latter it is so small that it does not project beyond the
-feathers, and in some birds, as in the penguins, the wings are used only
-as organs for swimming.
-
-Footnote 1:
-
-  Parker and Haswell: “Text Book of Zoology.”
-
-In spite of these differences we have no difficulty in recognizing
-throughout the group of birds a similarity of plan or structure,
-modified though it be in a thousand different ways.
-
-Enough has been said to illustrate what is meant by the similarities of
-organisms on which we base our system of classification. When we
-conclude from the statement that all vertebrates have a skull that they
-owe this to a common descent, we do not mean that a particular structure
-has been handed down as a sort of entailed heirloom, but that the
-descendants have followed the same plan of structure as that of their
-ancestors, and have the brain enclosed in a covering of harder material,
-although this material may not have exactly the same form, or be made of
-the same substance in all cases. Furthermore while we may recognize that
-the cartilaginous skull of the shark is simpler in structure than that
-of the cartilaginous-bony skull of the frog, and that the skull of the
-frog is simpler than that of the rabbit, yet we should not be justified
-in stating, except in a metaphorical sense, that something has been
-added to the skull of the shark to make that of the frog, and something
-to the latter to make that of the rabbit. On the contrary, while
-something may have been added, and the plan made more complicated, the
-skull has also been changed throughout in every single part.
-
-There is another point of some importance to be taken into account in
-this connection; namely, that each new generation begins life as a
-single cell or egg. The egg does not contain any preformed adult
-structures that it hands down unaltered, but it is so constructed that,
-under constant conditions, the same, or nearly the same, kind of
-structure is produced. Should something affect the egg, we can imagine
-that it might form a new combination on the same general plan as that of
-the old, yet one that differed from the original in every detail of its
-structure. It is this idea, I believe, that lies at the base of the
-transmutation theory. On some such assumption as this, and on this
-alone, can we bring the theory of transmutation into harmony with the
-facts of observation.
-
-What has been said in regard to individuals as a whole may be repeated
-also in respect to the study of the single organs. Selecting any one
-group of the animal or plant kingdom, we find the same organ, or the
-same combination of organs present in whole groups of forms. We can
-often arrange these organs in definite series passing from the simple to
-the complex, or, in case of degeneration, in the reverse order. However
-convenient it may be to study the structure of organisms from this point
-of view, the artificiality of the procedure will be obvious, since here
-also the organs of any two species do not differ from each other in only
-one point, but in many, perhaps in all. Therefore to arrange or to
-compare them according to any one scheme gives only an incomplete idea
-of their structure. We should apply here the same point of view that we
-used above in forming a conception of the meaning of the zoological and
-botanical systems. We must admit that our scheme is only an ideal, which
-corresponds to nothing real in nature, but is an abstraction based on
-the results of our experience. It might be a pleasing fancy to imagine
-that this ideal scheme corresponds to the plan of structure or of
-organization that is in every egg, and furnishes the basis for all the
-variations that have come or may come into existence; but we should find
-no justification whatsoever for believing that our fiction corresponds
-to any such real thing.
-
-To sum up the discussion: we find that the resemblances of animals and
-plants can be accounted for on the transmutation theory, not in the way
-commonly implied, but in a somewhat different sense. We have found that
-the resemblances between the different members of a group are only of a
-very general sort, and the structures are not identically the same in
-any two species—in fact, perhaps in no two individuals. This conclusion,
-however, does not stand in contradiction to the transmutation
-hypothesis, because, since each individual begins as an egg which is not
-a replica of the original adult from which it is derived, there can be
-no identity, but at most a very close similarity. Admitting, then, that
-our scheme is an ideal one, we can claim, nevertheless, that on this
-basis the facts of classification find a legitimate explanation in the
-transmutation theory.
-
-
-                        THE GEOLOGICAL EVIDENCE
-
-On the theory of descent, as well as on the theory of transmutation, the
-ancestors of all present forms are supposed to have lived at some time
-in the past on the surface of the earth. If, therefore, their remains
-should have been preserved, we should expect on the descent theory to
-find some, at least, of these remains to be like present forms, while on
-the transmutation theory we should expect to find most, if not all, of
-the ancestral forms to be different from the present ones.
-
-The evidence shows that fossil forms are practically all different from
-living forms, and the older they are the greater the difference from
-present forms. In general, therefore, it may be said that the evidence
-is in favor of the transmutation theory. It can scarcely be claimed that
-the evidence is absolutely conclusive, however probable it may appear,
-for the problem is complicated in a number of ways.
-
-In the first place, there is convincing evidence that some forms have
-been entirely exterminated. Other groups have very few living
-representatives, as is the case in the group containing nautilus, and in
-that of the crinoids. It is therefore always possible that a given
-fossil form may represent an extinct line, and may be only indirectly
-connected with forms alive at the present time. Again the historical
-record is so broken and incomplete in all but a few cases that its
-interpretation is largely a question of probability. We can easily
-conceive that it would be only in very exceptional cases that successive
-generations of the same form would be buried one above the other, so
-that we should find the series unbroken. This is evident not only
-because the conditions that were at one time favorable for the
-preservation of organic remains might not be favorable at another time,
-but also because if the conditions remained the same the organisms
-themselves might also remain unchanged. A new form, in fact, would be,
-_ex hypothese_, better suited to live in a different environment, and
-consequently we should not expect always to find its remains in the same
-place as that occupied by the parent species. This possibility of
-migration of new forms into a new locality makes the interpretation of
-the geological record extremely hazardous.
-
-Nevertheless, if the evolution of the entire animal and plant kingdoms
-had taken place within the period between the first deposits of
-stratified rocks and the present time, we might still have expected to
-find, despite the imperfections of the record, sufficient evidence to
-show how the present groups have arisen, and how they are related to one
-another. But, unfortunately, at the period when the history of the rocks
-begins, nearly all the large groups of animals were in existence, and
-some of them, indeed, as the trilobites and the brachiopods, appear to
-have reached the zenith of their development.
-
-On the other hand, the subdivisions of the group of vertebrates have
-evolved during the period known to us. It is true that the group was
-already formed when our knowledge of it begins, but, from the fishes
-onwards, the history of the vertebrates is recorded in the rocks. The
-highest group of all, the mammals, has arisen within relatively modern
-times. The correctness of the transmutation theory could be as well
-established by a single group of geological remains as by the entire
-animal kingdom. Let us, therefore, examine how far the theory is
-substantiated by the paleontological record of the vertebrates. We find
-that the earliest vertebrates were fishes, and these were followed
-successively by the amphibians, reptiles, birds, and mammals, one of the
-last species of all to appear being man himself. There can be little
-doubt that this series, with certain limitations to be spoken of in a
-moment, represents a progressive series beginning with the simpler forms
-and ending with the more complicated. Even did we not know this
-geological sequence we would conclude, from the anatomical evidence
-alone, that the progression had been in some such order as the
-geological record shows. The limitation referred to above is this: that
-while the mammals arose later than the birds, we need not suppose that
-the mammals arose from the birds, and not even perhaps from the
-reptiles, or at least not from reptiles like those living at the present
-day. The mammals may in fact, as some anatomists believe, have come
-direct from amphibian-like forms. If this is the case, we find the
-amphibians giving rise on one hand to reptiles and these to birds, and
-on the other hand to mammals.
-
-This case illustrates how careful we should be in interpreting the
-record, since two or more separate branches or orders may arise
-independently from the same lower group. If the mammals arose from the
-amphibians later than did the reptiles, it would be easy to make the
-mistake, if the record was incomplete at this stage, of supposing that
-the mammals had come directly from the reptiles.
-
-That the birds arose as an offshoot from reptile-like forms is not only
-probable on anatomical grounds, but the geological record has furnished
-us with forms like archæopteryx, which in many ways appears to stand
-midway between the reptiles and birds. This fossil, archæopteryx, has a
-bird-like form with feathered wings, and at the same time has a beak
-with reptilian teeth, and a long, feathered tail with a core of
-vertebræ.
-
-From another point of view we see how difficult may be the
-interpretation of the geological record, when we recall that throughout
-the entire period of evolution of the vertebrates the fishes,
-amphibians, reptiles, and birds remained still in existence, although
-they, or some of them, may have at one time given origin to new forms.
-In fact, all these groups are alive and in a flourishing condition at
-the present time. The fact illustrates another point of importance,
-namely, that we must not infer that because a group gives rise to a
-higher one, that it itself goes out of existence, being exterminated by
-the new form. There may be in fact no relation whatsoever between the
-birth of a new group and the extermination of an old one.
-
-On the transmutation theory we should expect to find not only a sequence
-of forms, beginning with the simplest and culminating with the more
-complex, but also, in the beginning of each new group, forms more or
-less intermediate in structure. It is claimed by all paleontologists
-that such forms are really found. For example, transitional forms
-between the fishes and the amphibia are found in the group of dipnoans,
-or lung-fishes, a few of which have survived to the present day. There
-are many fossil forms that have characters between those of amphibians
-and reptiles, which if not the immediate ancestors of the reptiles, yet
-show that at the time when this group is supposed to have arisen
-intermediate forms were in existence. The famous archæopteryx remains
-have been already referred to above, and it appears in this case that we
-have not only an intermediate form, but possibly a transitional one. In
-the group of mammals we find that the first forms to appear were the
-marsupials, which are undoubtedly primitive members of the group.
-
-The most convincing evidence of transmutation is found in certain series
-of forms that appear quite complete. The evolution of the horse series
-is the most often cited. As this case will be discussed a little later,
-we need not go into it fully here. It will suffice to point out that a
-continuous series of forms has been found, that connect the living
-horses having a single toe through three-toed, with the five-toed
-horses. Moreover, and this is important, this series shows a
-transformation not only in one set of structures, but in all other
-structures. The fossil horses with three toes are found in the higher
-geological layers, and those with more toes in the deeper layers
-progressively. In some cases, at least, the fossils have been found in
-the same part of the world, so that there is less risk of arranging them
-arbitrarily in a series to fit in with the theory.
-
-
-            EVIDENCE FROM DIRECT OBSERVATION AND EXPERIMENT
-
-Within the period of human history we do not know of a single instance
-of the transformation of one species into another one, if we apply the
-most rigid and extreme tests used to distinguish wild species from each
-other.[2] It may be claimed that the theory of descent is lacking,
-therefore, in the most essential feature that it needs to place the
-theory on a scientific basis. This must be admitted. On the other hand,
-the absence of direct observation is not fatal to the hypothesis, for
-several reasons. In the first place, it is only within the last few
-hundred years that an accurate record of wild animals and plants has
-been kept, so that we do not know except for this period whether any new
-species have appeared. Again, the chance of observing the change might
-not be very great, especially if the change were sudden. We would simply
-find a new species, and could not state where it had come from. If, on
-the other hand, the change were very slow, it might extend over so many
-years that the period would be beyond the life of an individual man. In
-only a few cases has it been possible to compare ancient pictures of
-animals and plants with their prototypes living at the present time, and
-it has turned out in all cases that they are the same. But these have
-been almost entirely domesticated forms, where, even if a change had
-been found, it might have been ascribed to other factors. In other
-cases, as in the mummified remains of a few Egyptian wild animals (which
-have also been found to be exactly like the same animals living at the
-present day), it was pointed out by Geoffroy Saint-Hilaire that, since
-the conditions of the Egyptian climate are the same to-day as they were
-two thousand years ago, there is no reason to expect any change would
-have taken place. But waiving this assumption, we should not forget that
-the theory of evolution does not postulate that a change must take place
-in the course of time, but only that it may take place sometimes.
-
-Footnote 2:
-
-  The transformation of “smaller species,” described by De Vries, will
-  be described in a later chapter.
-
-The position that we have here taken in regard to the lack of evidence
-as to the transformation of species is, perhaps, extreme, for, as will
-be shown in some detail in later chapters, there is abundant evidence
-proving that species have been seen to change greatly when the
-conditions surrounding them have been changed; but never, as has been
-stated, so far, or rather in such a way, that an actual new species that
-is infertile with the original form has been produced. Whether, after
-all, these changes due to a change in the environment are of the kind
-that makes new species, is also a question to be discussed later.
-
-The experimental evidence, in favor of the transformation of species,
-relates almost entirely to domesticated forms, and in this case the
-conscious agency of man seems, in some cases, to have played an
-important part; but here, even with the aid of the factor of isolation,
-it cannot be claimed that a single new species has been produced,
-although great changes in form have been effected. It is clear,
-therefore, that we must, at present, rely on other data, less
-satisfactory in all respects, to establish the probability of the theory
-of transformation.
-
-
-              MODERN CRITICISM OF THE THEORY OF EVOLUTION
-
-Throughout the whole of the nineteenth century a steady fire of
-criticism was directed against the theory of evolution; the names of
-Cuvier and of Louis Agassiz stand out preëminent in this connection, yet
-the theory has claimed an ever increasing number of adherents, until at
-the present time it is rare to find a biologist who does not accept in
-one form or another the general principle involved in the theory. The
-storm of criticism aroused by the publication of Darwin’s “Origin of
-Species,” was directed more against the doctrine of evolution than
-against Darwin’s argument for natural selection. The ground has been
-gone over so often that there would be little interest in going over it
-again. It will be more profitable to turn our attention to the latest
-attack on the theory from the ranks of the zoologists themselves.
-
-Fleischmann, in his recent book, “Die Descendenztheorie,” has made a new
-assault on the theory of evolution from the three standpoints of
-paleontology, comparative anatomy, and embryology. His general method is
-to try to show that the recognized leaders in these different branches
-of biology have been led to express essentially different views on the
-same questions, or rather have compromised the doctrine by the examples
-they have given to illustrate it. Fleischmann is fond of bringing
-together the antiquated and generally exaggerated views of writers like
-Haeckel, and contrasting them with more recent views on the same
-subject, without making sufficient allowances for the advances in
-knowledge that have taken place. He selects from each field a few
-specific examples, by means of which he illustrates the weakness, and
-even, as he believes, the falsity of the deductions drawn for the
-particular case. For example, the plan of structure of the vertebrates
-is dealt with in the following way: In this group the limbs, consisting
-typically of a pair of fore-legs and a pair of hind-legs, appear under
-the form of cylindrical outgrowths of the body. In the salamander, in
-the turtle, in the dog, the cylindrical legs, supporting the body and
-serving to support it above the ground, are used also for progression.
-The general purpose to which the limbs are put as organs of locomotion
-has not interfered with an astonishing number of varieties of structure,
-adapted to different conditions of existence, such as the short legs
-used for creeping in salamanders, lizards, turtles, crocodiles; the long
-and thin legs of good runners, as the hoofed animals; the mobile legs of
-the apes used for climbing; and the parachute legs of some squirrels
-used for soaring. Even more striking is the great variety of hands and
-feet, as seen in the flat, hairy foot of the bear; the fore-foot of the
-armadillos, carrying long, sickle-shaped claws; the digging foot of the
-mole; the plump foot of the elephant, ending in a broad, flat pad with
-nails around the border, and without division into fingers; the hand of
-man and of the apes ending with fine and delicate fingers for grasping.
-To have discovered a general plan of structure running through such a
-great variety of forms was proclaimed a triumph of anatomical study.[3]
-
-Footnote 3:
-
-  This paragraph is a free translation of Fleischmann’s text.
-
-A study of the bony structure of the limb shows that typically it
-consists of a single proximal bone (the humerus in the upper arm, the
-femur in the thigh), followed by two bones running parallel to each
-other (the radius and ulna in the arm and the tibia and fibula in the
-shank); these are succeeded in the arm by the two series of carpal
-bones, and in the leg by the two series of tarsal bones, and these are
-followed in each by five longer bones (the metacarpals and metatarsals),
-and these again by the series of long bones that lie in the fingers and
-toes. Despite the manifold variety of forms, Fleischmann admits that
-both the hind- and the fore-limbs are constructed on the same plan
-throughout the vertebrates. Even forms like the camel, in which there
-are fewer terminal bones, may be brought into the same category by
-supposing a reduction of the bones to have taken place, so that three of
-the digits have been lost. In the leg of the pig and of the reindeer,
-even a greater reduction may be supposed to have taken place.
-Fleischmann points out that these facts were supposed to be in full
-harmony with the theory of descent.
-
-The analysis of the origin of the foot of the horse gave even better
-evidence, it was claimed, in favor of the theory. The foot consists of a
-single series of bones corresponding to the middle finger and toe. When,
-as sometimes happens, individual horses are found in which in addition
-to the single middle finger two smaller lateral fingers with small hoofs
-appear, the followers of the descent theory rejoiced to be able to bring
-this forward as a confirmation of their doctrine. The occurrence was
-explained as a sporadic return to an ancestral form. The naïve
-exposition of the laws of inheritance that were supposed to control such
-phenomena was accepted without question. And when finally a large number
-of fossil remains were found by paleontologists,—remains showing a
-gradual increase in the middle finger, and a decrease in size of the
-lateral fingers,—it was supposed that the proof was complete; and
-anatomists even went so far as to hold that the original ancestor of the
-horse was a five-fingered animal.
-
-This same law of type of structure was found to extend to the entire
-vertebrate series, and the only plausible explanation appeared to be
-that adopted by Darwin and his followers, namely, that the resemblance
-is the result of the blood-relationship of the different forms. But a
-simple comparison of the skeleton of the limbs if carried out without
-theoretical prejudice would show, Fleischmann thinks, that there is only
-a common style, or plan of structure, for the vertebrates. This
-anatomical result has about the same value as the knowledge of the
-different styles of historical architecture—that, for instance, all
-large churches of the Gothic period have certain general principles in
-common. The believers in the theory of descent have, however, he thinks,
-gone beyond the facts, and have concluded that the common plan in
-animals is the consequence of a common descent. “I cannot see the
-necessity for such a conclusion, and I certainly should unhesitatingly
-deny that the common plan of the Gothic churches depended on a common
-architect. The illustration is, however, not perfect, because the
-influence of the mediæval school of stone-cutters on its wandering
-apprentices is well known.”
-
-Fleischmann adds that if the descent theory is true we should expect to
-find that if a common plan of structure is present in one set of organs,
-as the limbs, it should be present in all other organs as well, but he
-does not add that this is generally the case.
-
-The weakness of Fleischmann’s argument is so apparent that we need not
-attempt an elaborate refutation. When he says there is no absolute proof
-that the common plan of structure must be the result of
-blood-relationship, he is not bringing a fatal argument against the
-theory of descent, for no one but an enthusiast sees anything more in
-the explanation than a very probable theory that appears to account for
-the facts. To demand an absolute proof for the theory is to ask for more
-than any reasonable advocate of the descent theory claims for it. As I
-have tried to show in the preceding pages, the evidence in favor of the
-theory of descent is not absolutely demonstrative, but the theory is the
-most satisfactory one that has as yet been advanced to account for the
-facts. Fleischmann’s reference to the common plan of structure of the
-Gothic churches is not very fortunate for his purpose, since he admits
-himself that this may be the result of a common tradition handed down
-from man to man, a sort of continuity that is not very dissimilar in
-principle from that implied in the descent theory; in the latter the
-continuity of substance taking the place of the tradition in the other.
-Had the plan for each, or even for many of the churches, originated
-independently in the mind of each architect, then the similarity in
-style would have to be accounted for by a different sort of principle
-from that involved in the theory of descent; but as a matter of fact the
-historical evidence makes it probable that similar types of architecture
-are largely the result of imitation and tradition. Certain variations
-may have been added by each architect, but it is just the similarity of
-type or plan that is generally supposed to be the outcome of a common
-tradition.
-
-Fleischmann’s attempt in the following chapter to belittle Gegenbaur’s
-theory of the origin of the five-fingered type of hand from a fin, like
-that of a fish, need not detain us, since this theory is obviously only
-a special application which like any other may be wrong, without in the
-least injuring the general principle of descent. That all phylogenetic
-questions are hazardous and difficult is only too obvious to any one
-familiar with the literature of the last thirty years.
-
-Fleischmann devotes a long chapter to the geological evidences in
-connection with the evolution of the horse, and attempts to throw
-ridicule on the conclusions of the paleontologists by emphasizing the
-differences of opinion that have been advanced in regard to the descent
-of this form. After pointing out that the horse, and its few living
-relatives, the ass and the zebra, are unique in the mammalian series in
-possessing a single digit, he shows that by the discovery of the fossil
-horses the group has been simply enlarged, and now includes horses with
-one, three, and five toes. The discovery of the fossil forms was
-interpreted by the advocates of the descent theory as a demonstration of
-the theory. The series was arranged by paleontologists so that the
-five-toed form came first, then those with three and one toe, the last
-represented by the living horses. But the matter was not so simple,
-Fleischmann points out, as it appeared to be to the earlier writers, for
-example to Haeckel, Huxley, Leidy, Cope, Marsh. Different authors came
-to express different opinions in regard to the genealogical connection
-between the fossil forms. Several writers have tried to show that the
-present genus, Equus, has not had a single line of descent, but have
-supposed that the European horses and the original American horses had
-different lines of ancestry, which may have united only far back in the
-genus Epihippus. Fleischmann points out that the arrangement of the
-series is open to the criticism that it is arbitrary, and that we could
-equally well make up an analogous series beginning with the
-five-fingered hand of man, then that of the dog with the thumb
-incompletely developed, then the four-fingered hind-foot of the pig
-without a big toe and with a weak second and fifth digit, then the foot
-of the camel with only two toes, and lastly the foot of the horse with
-only one toe. It sounds strange that Fleischmann should make such a
-trivial reply as this, and deliberately ignore the all-important
-evidence with which he is, of course, as is every zoologist, perfectly
-conversant. Not only are there a hundred other points of agreement in
-the horse series, but also the geological sequence of the strata, in
-which some at least of the series have been found, shows that the
-arrangement is not arbitrary, as he implies.
-
-Fleischmann then proceeds to point out that when the evidence from other
-parts of the anatomy is taken into account, it becomes evident that all
-the known fossil remains of horses cannot be arranged in a single line,
-but that there are at least three families or groups recognizable. Many
-of these forms are known only from fragments of their skeletons—a few
-teeth, for instance, in the case of Merohippus, which on this evidence
-alone has been placed at the uniting point of two series. At present
-about eight different species of living horses are recognized by
-zoologists, and paleontological evidence shows only that many other
-species have been in existence, and that even three- and one-toed forms
-lived together at the same time.
-
-Fleischmann also enters a protest against the ordinary arrangement of
-the fossil genera Eo-, Oro-, Meso-, Merohippus in a series, for these
-names stand not for single species, but for groups containing no less
-than six species under Protohippus, fourteen under Equus, twelve under
-Mesohippus, and twenty under Hipparion. Fleischmann concludes: “The
-descent of the horses has not been made out with the precision of an
-accurate proof, and it will require a great deal of work before we get
-an exact and thorough knowledge of the fossil forms. What a striking
-contrast is found on examination between the actual facts and the crude
-hopes of the apostles of the descent theory!...”
-
-In so far as this criticism of Fleischmann’s applies to the difficulties
-of determining the past history of the horse, it may be granted that he
-has scored a point against those who have pretended that the evidence is
-simple and conclusive; but we should not fail to remember that this
-difficulty has been felt by paleontologists themselves, who have been
-the first to call attention to the complexity of the problem, and to the
-difficulties of finding out the actual ancestors of the living
-representative of the series. And while we may admit that the early
-enthusiasts exaggerated, unintentionally, the importance of the few
-forms known to them, and went too far in supposing that they had found
-the actual series of ancestors of living horses, yet we need not let
-this blind us to the importance of the facts themselves. Despite the
-fact that it may be difficult and, perhaps, in most cases, impossible,
-to arrange the fossil forms in their relations to one another and to
-living forms, yet on an unprejudiced view it will be clear, I think,
-that so far as the evidence goes it is in full harmony with the theory
-of descent. This is especially evident if we turn our attention to a
-part of the subject that is almost entirely ignored by Fleischmann, and
-yet is of fundamental importance in judging of the result. The series of
-forms beginning with the five-toed horses and ending with those having a
-single toe has not been brought together haphazard, as Fleischmann’s
-comparison might lead one to suppose, but the five-fingered forms are
-those from the older rocks, and the three-toed forms from more recent
-layers. The value of this kind of evidence might have been open to
-greater doubt had the series been made up of forms found scattered over
-the whole world, for it is well known how difficult it is to compare in
-point of time the rocks of different continents. But in certain parts of
-the world, especially in North America, series of fossil horses have
-been found in sedimentary deposits that appear to be perfectly
-continuous. This series, by itself, and without regard to the point as
-to whether in other parts of the world other series may exist, shows
-exactly those results which the theory of descent postulates, and we
-find here, in all probability, a direct line of descent. While it may be
-freely admitted that no such series can demonstrate the theory of
-descent with absolute certainty, yet it would be folly to disregard
-evidence as clear as this.
-
-In regard to the other point raised by Fleischmann concerning the large
-number of species of fossil horses that have existed in past times, it
-is obvious that while this greatly increases the difficulty of the
-paleontologist it is not an objection to the descent theory. In fact,
-our experience with living species would lead us to expect that many
-types have been represented at each geological period by a number of
-related species that may have inhabited the same country. On the descent
-theory, one species only in each geological period could have been in
-the line of descent of the present species of horse. The difficulty of
-determining which species (if there were several living in a given
-epoch) is the ancestor of the horse is increased, but this is not in
-itself an objection to the theory.
-
-The descent of birds from flying reptiles is used by Fleischmann as
-another point of attack on the transmutation theory. The theory
-postulates that the birds have come from ancestors whose fore-legs have
-been changed into highly specialized wings. The long vertebrated tail of
-the ancestral form is supposed to have become very short, and long
-feathers to have grown out from its stump which act as a rudder during
-flight. Flying reptiles with winged fore-legs and a long vertebrated
-tail have been actually found as fossil remains, as seen in the
-pterodactyls and in the famous archæopteryx. The latter, which is
-generally regarded either as the immediate ancestor of living birds, or
-at least as a closely similar form, possessed a fore-leg having three
-fingers ending in claws, and feathers on the forearm similar to those of
-modern birds. It had a long tail, like that of a lizard, but with
-well-developed feathers along its sides. It had pointed teeth in the
-horn-covered jaws. Fleischmann proceeds to point out that the
-resemblance of the hand of archæopteryx to that of the reptiles is not
-very close, for two fingers are absent as in modern birds. The typical
-form of the foot is that of the bird, and is not the simple reptilian
-type of structure. Feathers and not scales cover the body, and give no
-clew as to how the feathers of birds have arisen. He concludes,
-therefore, that archæopteryx, having many true bird-like characters,
-such as feathers, union of bones in the foot, etc., has other characters
-not possessed by living birds, namely, a long, vertebrated tail, a flat
-breastbone, biconcave vertebræ, etc. Therefore, it cannot be regarded as
-an intermediate form. Fleischmann does not point out that it is just
-these characters that would be postulated on the descent theory for the
-ancestor of the birds, if the latter arose from reptiles. Even if it
-should turn out that archæopteryx is not the immediate forefather of
-living birds, yet the discovery that a form really existed intermediate
-in many characters between the reptiles and the birds is a gain for the
-transmutation theory. It is from a group having such characters that the
-theory postulates that the birds have been evolved, and to have
-discovered a member of such a group speaks directly and unmistakably in
-favor of the probability of the transmutation theory.
-
-Fleischmann again fails to point out that the geological period in which
-the remains of archæopteryx were found, is the one just before that in
-which the modern group of birds appeared, and, therefore, exactly the
-one in which the theory demands the presence of intermediate forms. This
-fact adds important evidence to the view that looks upon archæopteryx as
-a form belonging to a group from which living birds have arisen. That a
-number of recent paleontologists believe archæopteryx to belong to the
-group of birds, rather than to the reptiles, or to an intermediate
-group, does not in the least lessen its importance, as Fleischmann
-pretends it does, as a form possessing a number of reptilian characters,
-such as the transmutation theory postulates for the early ancestors of
-the birds.
-
-The origin of the mammalian phylum serves as the text for another attack
-on the transmutation theory. Fleischmann points out that the discovery
-of the monotremes, including the forms ornithorhynchus and echidna, was
-hailed at first as a demonstration of the supposed descent of the
-mammals from a reptilian ancestor. The special points of resemblance
-between ornithorhynchus and reptiles and birds are the complete fusion
-of the skull bones, the great development of the vertebræ of the neck
-region, certain similarities in the shoulder girdle, the paired oviducts
-opening independently into the last part of the digestive tract
-(cloaca), and the presence of a parchment-like shell around the large,
-yolk-bearing egg. These are all points of resemblance to reptiles and
-birds, and were interpreted as intermediate stages between the latter
-groups and the group of mammals. In addition to these intermediate
-characters, ornithorhynchus possesses some distinctive, mammalian
-features—mammary glands and hair, for instance. Fleischmann takes the
-ground, in this case, that there are so many points of difference
-between the monotremes and the higher mammals, that it is impossible to
-see how from forms like these the higher groups could have arisen, and
-that ornithorhynchus cannot be placed as an intermediate form, a link
-between saurians and mammals, as the followers of the transmutation
-theory maintain. He shows, giving citations, that anatomists themselves
-are by no means in accord as to the exact position of ornithorhynchus in
-relation to the higher forms.
-
-In reply to this criticism, the same answer made above for archæopteryx
-may be repeated here, namely, that because certain optimists have
-declared the monotremes to be connecting forms, it does not follow that
-the descent theory is untrue, and not even that these forms do not give
-support to the theory, if in a less direct way. I doubt if any living
-zoologist regards either ornithorhynchus or echidna as the ancestral
-form from which the mammals have arisen. But on the other hand it may be
-well not to forget that these two forms possess many characters
-intermediate between those of mammals and reptiles, and it is from a
-group having such intermediate characters that we should expect the
-mammals to have arisen. These forms show, if they show nothing else,
-that it is possible for a species to combine some of the characters of
-the reptiles with those of the mammals; and the transmutation theory
-does no more than postulate the existence at one time of such a group,
-the different species of which may have differed in a number of points
-from the two existing genera of monotremes.
-
-The origin of lung-bearing vertebrates from fishlike ancestors, in which
-the swim-bladder has been changed into lungs, has been pointed to by the
-advocates of the transmutation theory as receiving confirmation in the
-existence of animals like those in the group of dipnoan fishes. In these
-animals both gills and a swim-bladder, that can be used as a lung, are
-present; and through some such intermediate forms it is generally
-supposed that the lung-bearing animals have arisen. Fleischmann argues,
-however, that, on account of certain trivial differences in the position
-of the duct of the swim-bladder in living species, the supposed
-comparison is not to the point; but the issue thus raised is too
-unimportant to merit further discussion. Leaving aside also some even
-more doubtful criticisms which are made by Fleischmann, and which might
-be added to indefinitely without doing more than showing the credulity
-of some of the more ardent followers of the transmutation theory, or
-else the uncertainty of some of the special applications of the theory,
-let us pass to Fleischmann’s criticism of the problem of development.[4]
-
-Footnote 4:
-
-  The long argument of Fleischmann in regard to the origin of the
-  fresh-water snails, as illustrated by the planorbis series, and also
-  the origin of the nautiloid group, has been recently dealt with fully
-  by Plate, and, therefore, need not be considered here.
-
-With fine scorn Fleischmann points to the crudity of the ideas of Oken
-and of Haeckel in regard to the embryology (or the ontogeny) repeating
-the ancestral history (or the phylogeny). We may consider briefly (since
-we devote the next chapter almost entirely to the same topic) the
-exceptions to this supposed recapitulation, which Fleischmann has
-brought together. The young of beetles, flies, and butterflies creep out
-of the egg as small worm-like forms of apparently simple organization.
-They have a long body, composed of a series of rings; the head is small
-and lacks the feelers, and often the faceted eyes. The wings are absent,
-and the legs are short. At first sight the larva appears to resemble a
-worm, and this led Oken to conclude that the insects appear first in the
-form of their ancestors, the segmented worms. If we examine the
-structure of the larva more carefully, we shall find that there are a
-great many differences between it and the segmented worms; and that even
-the youngest larva is indeed a typical insect. The tracheæ, so
-characteristic of the group of insects, are present, the structure of
-the digestive tract with its Malpighian tubes, the form of the heart,
-the structure of the head, as well as the blastema of the reproductive
-organs, show in the youngest larva the type of the insects. In other
-words the body of the caterpillar is formed on exactly the same
-fundamental plan as that of the butterfly.
-
-In regard to the larval forms of other groups we find the same
-relations, as, for example, in the amphibians. The young of salamanders,
-toads, and frogs leave the egg not in the completed form, but as small
-tadpoles adapted to life in the water. A certain resemblance to fish
-cannot be denied. They possess a broad tail, gills (rich in blood
-vessels) on each side of the neck, and limbs are absent for a long time.
-These are characters similar to those of fish, but a more careful
-anatomical examination destroys the apparent resemblance. The
-superficial resemblances are due to adaptation to the same external
-conditions.
-
-Fleischmann ridicules the idea that the young chick resembles at any
-stage an adult, ancestral animal; the presence of an open digestive
-tract shows how absurd such an idea is. The obvious contradiction is
-explained away by embryologists, by supposing that the ancestral adult
-stages have been crowded together in order to shorten the period of
-development; and that, in addition, larval characters and provisional
-organs have appeared in the embryo itself, which confuse and crowd out
-the ancestral stages.
-
-In regard to the presence of gill-slits in the embryo of the higher
-vertebrates, in the chick, and in man, for example, Fleischmann says: “I
-cannot see how it can be shown by exact proof that the gill-slits of the
-embryos of the higher vertebrates that remain small and finally
-disappear could once have had the power of growing into functional
-slits.” With this trite comment the subject is dismissed.
-
-On the whole, Fleischmann’s attack cannot be regarded as having
-seriously weakened the theory of evolution. He has done, nevertheless,
-good service in recalling the fact that, however probable the theory may
-appear, the evidence is indirect and exact proof is still wanting.
-Moreover, as I shall attempt to point out in the next chapter, we are
-far from having arrived at a satisfactory idea of how the process has
-really taken place.
-
-
-------------------------------------------------------------------------
-
-
-
-
-                              CHAPTER III
-
-                  THE THEORY OF EVOLUTION (Continued)
-
-                      The Evidence from Embryology
-
-                       THE RECAPITULATION THEORY
-
-
-At the close of the eighteenth, and more definitely at the beginning of
-the nineteenth, century a number of naturalists called attention to the
-remarkable resemblance between the embryos of higher animals and the
-adult forms of lower animals. This idea was destined to play an
-important rôle as one of the most convincing proofs of the theory of
-evolution, and it is interesting to examine, in the first place, the
-evidence that suggested to these earlier writers the theory that the
-embryos of the higher forms pass through the adult stages of the lower
-animals.
-
-The first definite reference[5] to the recapitulation view that I have
-been able to find is that of Kielmeyer in 1793, which was inspired, he
-says, by the resemblance of the tadpole of the frog to an adult fish.[6]
-This suggested that the embryo of higher forms corresponds to the adult
-stages of lower ones. He adds that man and birds are in their first
-stages plantlike.
-
-Footnote 5:
-
-  The earlier references of a few embryologists are too vague to have
-  any bearing on the subject.
-
-Footnote 6:
-
-  Autenrieth in 1797 makes the briefest possible reference to some such
-  principle in speaking of the way in which the nose of the embryo
-  closes.
-
-Oken in 1805 gave the following fantastic account of this relation:
-“Each animal ‘metamorphoses itself’ through all animal forms. The frog
-appears first under the form of a mollusk in order to pass from this
-stage to a higher one. The tadpole stage is a true snail; it has gills
-which hang free at the sides of the body as is the case in _Unio
-pictorum_. It has even a byssus, as in Mytilus, in order to cling to the
-grass. The tail is nothing else than the foot of the snail. The
-metamorphosis of an insect is a repetition of the whole class,
-scolopendra, oniscus, julus, spider, crab.”
-
-Walther, in 1808, said: “The human fœtus passes through its
-metamorphosis in the cavity of the uterus in such a way that it repeats
-all classes of animals, but, remaining permanently in none, develops
-more and more into the innate human form. First the embryo has the form
-of a worm. It reaches the insect stage just before its metamorphosis.
-The origin of the liver, the appearance of the different secretions,
-etc., show clearly an advance from the class of the worm into that of
-the mollusk.”
-
-Meckel first in 1808, again in 1811, and more fully in 1821 made much
-more definite comparisons between the embryos of higher forms and the
-adult stages of lower groups. He held that the embryo of higher forms,
-before reaching its complete development, passes through many stages
-that correspond to those at which the lower animals appear to be checked
-through their whole life. In fact the embryos of higher animals, the
-mammals, and especially man, correspond in the form of their organs, in
-their number, position, and proportionate size to those of the animals
-standing below them. The skin is at first, and for a considerable period
-of embryonic life, soft, smooth, hairless, as in the zoophytes, medusæ,
-many worms, mollusks, fishes, and even in the lower amphibians. Then
-comes a period in which it becomes thicker and hairy, when it
-corresponds to the skin of the higher animals. It should be especially
-noted here, that the fœtus of the negro is more hairy than that of the
-European.
-
-The muscular system of the embryo, owing to its lack of union in the
-ventral wall, corresponds to the muscles of the shelled, headless
-mollusks, whose mantle is open in the same region. Meckel compares the
-bones of the higher vertebrates with the simpler bones of the lower
-forms, and even with the cartilages of the cephalopod. He points out
-that in the early human embryo the nerve cord extends the whole length
-of the spinal canal. He compares the simple heart of the embryo with
-that of worms, and a later stage, when two chambers are present, with
-that of the gasteropod mollusk. The circulation of the blood in the
-placenta recalls, he says, the circulation in the skin of the lower
-animals. The lobulated form of the kidney in the human embryo is
-compared with the adult condition in the fishes and amphibians. The
-internal position of the reproductive organs in the higher mammals
-recalls the permanent position of these organs in the lower animals. The
-posterior end of the body of the human embryo extends backwards as a
-tail which later disappears.
-
-Some of these comparisons of Meckel sound very absurd to us nowadays,
-especially his comparison between the embryos of the higher vertebrates,
-and the adults of worms, crustaceans, spiders, snails, bivalve mollusks,
-cephalopods, etc. On the other hand, many of these comparisons are the
-same as those that are to be found in modern text-books on embryology;
-and we may do well to ask ourselves whether these may not sound equally
-absurd a hundred years hence. Why do some of Meckel’s comparisons seem
-so naïve, while others have a distinctly modern flavor? In a word, can
-we justify the present belief of some embryologists that the embryos of
-higher forms repeat the adult stages of lower members of the same group?
-It is important to observe that up to this time the comparison had
-always been made between the embryo of the higher form and the adult
-forms of existing lower animals. The theory of evolution had, so far,
-had no influence on the interpretation that was later given to this
-resemblance.
-
-Von Baer opposed the theory of recapitulation that had become current
-when he wrote in 1828. According to Von Baer, the more nearly related
-two animals are, or rather the more nearly similar two forms are (since
-Von Baer did not accept the idea of evolution), the more nearly alike is
-their development, and so much longer in their development do they
-follow in the same path. For example two similar species of pigeons will
-follow the same method of development up to almost the last stage of
-their formation. The embryos of these two forms will be practically
-identical until each produces the special characters of its own species.
-On the other hand two animals belonging to different families of the
-same phylum will have only the earlier stages in common. Thus, a bird
-and a mammal will have the first stages similar, or identical, and then
-diverge, the mammal adding the higher characters of its group. The
-resemblance is between corresponding embryonic stages and not between
-the embryo of the mammal and the adult form of a lower group.
-
-Von Baer was also careful to compare embryos of the same phylum with
-each other, and states explicitly that there are no grounds for
-comparison between embryos of different groups.[7]
-
-Footnote 7:
-
-  In one place Von Baer raises the question whether the egg may not be a
-  form common to all the phyla.
-
-We shall return again to Von Baer’s interpretation and then discuss its
-value from our present point of view.
-
-Despite the different interpretation that Von Baer gave to this doctrine
-of resemblance the older view of recapitulation continued to dominate
-the thoughts of embryologists throughout the whole of the nineteenth
-century.
-
-Louis Agassiz, in the Lowell Lectures of 1848, proposed for the first
-time the theory that the embryo of higher forms resembled not so much
-lower adult animals living at the present time, as those that lived in
-past times. Since Agassiz himself did not accept the theory of
-evolution, the interpretation that he gave to the recapitulation theory
-did not have the importance that it was destined to have when the
-animals that lived in the past came to be looked upon as the ancestors
-of existing animals.[8] But with the acceptation of the theory of
-evolution, which was largely the outcome of the publication of Darwin’s
-“Origin of Species” in 1859, this new interpretation immediately
-blossomed forth. In fact, it became almost a part of the new theory to
-believe that the embryo of higher forms recapitulated the series of
-ancestral adult forms through which the species had passed. The one
-addition of any importance to the theory that was added by the Darwinian
-school was that the history of the past, as exemplified by the embryonic
-development, is often falsified.
-
-Footnote 8:
-
-  Carl Vogt in 1842 suggested that fossil species, in their historical
-  succession, pass through changes similar to those which the embryos of
-  living forms undergo.
-
-Let us return once more to the facts and see which of them are regarded
-at present as demanding an explanation. These facts are not very
-numerous and yet sufficiently apparent to attract attention at once when
-known.
-
-The most interesting case, and the one that has most often attracted
-attention, is the occurrence of gill-clefts in the embryos of reptiles,
-birds, and mammals. These appear on each side of the neck in the very
-early embryo. Each is formed by a vertical pouch, that grows out from
-the wall of the pharynx until it meets the skin, and, fusing with the
-latter, the walls of the pouch separate, and a cleft is formed. This
-vertical cleft, placing the cavity of the pharynx in communication with
-the outside, is the gill-slit. Similar openings in adult fishes put the
-pharynx in communication with the exterior, so that water taken through
-the mouth passes out at the sides of the neck between the gill filaments
-that border the gill-slits. In this way the blood is aerated. The number
-of gill-slits that are found in the embryos of different groups of
-higher vertebrates, and the number that open to the exterior are
-variable; but the number of gill-openings that are present in the adults
-of lower vertebrates is also variable. No one who has studied the method
-of development of the gill-slits in the lower and higher vertebrates
-will doubt for a moment that some kind of relation must subsist between
-these structures.
-
-In the lowest adult form of the vertebrates, amphioxus, the gill-system
-is used largely as a sieve for procuring food, partly also, perhaps, for
-respiration. In the sharks, bony fishes, and lower amphibians, water is
-taken in through the mouth, and passes through the gill-slits to the
-exterior. As it goes through the slits it passes over the gills, that
-stand like fringes on the sides of the slits. The blood that passes in
-large quantities through the gills is aerated in this way. In the
-embryos of the higher vertebrates the gill-slits may appear even before
-the mouth has opened, but in no case is there a passage of water through
-the gill-slits, nor is the blood aerated in the gill-region, although it
-passes through this part on its way from the heart to the dorsal side of
-the digestive tract. It is quite certain that the gill-system of the
-embryo performs no respiratory function.[9]
-
-Footnote 9:
-
-  This statement is not intended to prejudice the question as to whether
-  the presence of the gill-slits and arches may be essential to the
-  formation of other organs.
-
-In the higher amphibians, the frogs for example, we find an interesting
-transition. The young embryo, when it emerges from the egg-membranes,
-bears three pairs of external gills that project from the gill-arches
-into the surrounding water. Later these are absorbed, and a new system
-of internal gills, like those of fishes, develops on the gill-arches.
-These are used throughout the tadpole stage for respiratory purposes.
-When the tadpole is about to leave the water to become a frog, the
-internal gills are also absorbed and the gill-clefts close. Lungs then
-develop which become the permanent organs of respiration.
-
-There are two points to be noticed in this connection. First, the
-external gills, which are the first to develop, do not seem to
-correspond to any permanent adult stage of a lower group. Second, the
-transition from the tadpole to the frog can only be used by way of
-analogy of what is supposed to have taken place ancestrally in the
-reptiles, birds, and mammals, since no one will maintain that the frogs
-represent a group transitional between the amphibians and the higher
-forms. However, since the salamanders also have gills and gill-slits in
-the young stages, and lose them when they leave the water to become
-adult land forms, this group will better serve to illustrate how the
-gill-system has been lost in the higher forms. Not that in this case
-either, need we suppose that the forms living to-day represent
-ancestral, transitional forms, but only that they indicate how such a
-remarkable change from a gill-breathing form, living in the water, might
-become transformed into a lung-breathing land form. Such a change is
-supposed to have taken place when the ancestors of the reptiles and the
-mammals left the water to take up their abode on the land.
-
-The point to which I wish to draw especial attention in this connection
-is that in the higher forms the gill-slits appear at a very early stage;
-in fact, as early in the mammal as in the salamander or the fish, so
-that if we suppose their appearance in the mammal is a repetition of the
-adult amphibian stage, then, since this stage appears as early in the
-development of the mammal as in the amphibians themselves, the
-conclusion is somewhat paradoxical.
-
-The history of the notochord in the vertebrate series gives an
-interesting parallel. In amphioxus it is a tough and firm cord that
-extends from end to end of the body. On each side of it lie the plates
-of muscles. It appears at a very early stage of development as a fold of
-the upper wall of the digestive tract. In the cartilaginous fishes the
-notochord also appears at a very early stage, and also from the dorsal
-wall of the digestive tract. In later embryonic stages it becomes
-surrounded by a cartilaginous sheath, or tube, which then segments into
-blocks, the vertebræ. The notochord becomes partially obliterated as the
-centra of the vertebræ are formed, but traces of it are present even in
-adult stages. In the lower amphibians the notochord arises also at an
-early stage over and perhaps, in part, from the dorsal wall of the
-digestive tract. It is later almost entirely obliterated by the
-development of the vertebræ. These vertebræ first appear as a
-membraneous tube which breaks up into cartilaginous blocks, and these
-are the structures around and in which the bone develops to form the
-permanent vertebræ.
-
-In higher forms, reptiles, birds, and mammals, the notochord also
-appears at the very beginning of the development, but it is not certain
-that we can call the material out of which it forms the dorsal wall of
-the archenteron (the amphibians giving, perhaps, intermediate stages).
-It becomes surrounded by continuous tissue which breaks up into blocks,
-and these become the bases of the vertebræ. The notochord becomes so
-nearly obliterated in later stages that only the barest traces of it are
-left either in the spaces between, or in, the vertebræ.
-
-In this series we see the higher forms passing through stages similar at
-first to those through which the lower forms pass; and it is especially
-worthy of note that the embryo mammal begins to produce its notochord at
-the very beginning of its development, at a stage, in fact, so far as
-comparison is possible, as early as that at which the notochord of
-amphioxus develops.
-
-The development of the skull gives a somewhat similar case. The skulls
-of sharks and skates are entirely cartilaginous and imperfectly enclose
-the brain. The ganoids have added to the cartilaginous skull certain
-plates in the dermal layer of the skin. In the higher forms we find the
-skull composed of two sets of bones, one set developing from the
-cartilage of the first-formed cranium, and the other having a more
-superficial origin; the latter are called the membrane bones, and are
-supposed to correspond to the dermal plates of the ganoids.
-
-In the development of the kidneys, or nephridia, we find, perhaps,
-another parallel, although, owing to recent discoveries, we must be very
-cautious in our interpretation. As yet, nothing corresponding to the
-nephridia of amphioxus has been discovered in the other vertebrates. Our
-comparison must begin, therefore, higher up in the series. In the sharks
-and bony fishes the nephridia lie at the anterior end of the
-body-cavity. In the amphibia there is present in the young tadpole a
-pair of nephridial organs, the head-kidneys, also in the anterior end of
-the body-cavity. Later these are replaced by another organ, the
-permanent mid-kidney, that develops behind the head-kidney. In reptiles,
-birds, and mammals a third nephridial organ, the hind-kidney, develops
-later than and posterior to the mid-kidney, and becomes the permanent
-organ of excretion. Thus in the development of the nephridial system in
-the higher forms we find the same sequence, more or less, that is found
-in the series of adult forms mentioned above. The anterior end of the
-kidney develops first, then the middle part, and then the most
-posterior. The anterior part disappears in the amphibians, the anterior
-and the middle parts in the birds and mammals, so that in the latter
-groups the permanent kidney is the hind-kidney alone.
-
-The formation of the heart is supposed to offer certain parallels.
-Amphioxus is without a definite heart, but there is a ventral blood
-vessel beneath the pharynx, which sends blood to the gill-system. This
-blood vessel corresponds in position to the heart of other vertebrates.
-In sharks we find a thick-walled muscular tube below the pharynx; the
-blood enters at its posterior end, flows forward and out at the anterior
-end into a blood vessel that sends smaller vessels up through the
-gill-arches to the dorsal side.
-
-In the amphibia the heart is a tube, so twisted on itself that the
-original posterior end is carried forward to the anterior end, and this
-part, the auricle, is divided lengthwise by a partition into a right and
-a left side. In the reptiles the ventricle is also partially separated
-into two chambers, completely so in the crocodiles. In birds and mammals
-the auricular and ventricular septa are complete in the adult, and the
-ventral aorta that carries the blood forward from the heart is
-completely divided into two vessels, one of which now carries blood to
-the lungs. When we examine the development of the heart of a mammal, or
-of a bird, we find something like a parallel series of stages,
-apparently resembling conditions found in the different groups just
-described. The heart is, at first, a straight tube, it then bends on
-itself, and a constriction separates the auricular part from the
-ventricular, and another the ventricular from the ventral aorta.
-Vertical longitudinal partitions then arise, one of which separates the
-auricle into two parts, and another the ventricle into two parts, and a
-third divides the primitive aorta into two parts. In the early stages
-all the blood passes from the single ventral aorta through the
-gill-arches to the dorsal side, and it is only after the appearance of
-the lung-system that the gill-system is largely obliterated.
-
-We find here, then, a sort of parallel, provided we do not inquire too
-particularly into details. This comparison may be justified, at least so
-far that the circulation is at first through the arches and is later
-partially replaced by the double circulation, the systemic and the
-pulmonary.
-
-A few other cases may also be added. The proverbial absence of teeth in
-birds applies only to the adult condition, for, as first shown by
-Geoffroy Saint-Hilaire, four thickenings, or ridges, develop in the
-mouth of the embryo; two in the upper, two in the lower, jaw. These
-ridges appear to correspond to those of reptiles and mammals, from which
-the teeth develop. It may be said, therefore, that the rudiments of
-teeth appear in the embryo of the bird. This might be interpreted to
-mean that the embryo repeats the ancestral reptilian stage, or, perhaps,
-the ancestral avian stage that had teeth in the beak; but since only the
-beginnings of teeth appear, and not the fully formed structures, this
-interpretation would clearly overshoot the mark.
-
-The embryo of the baleen whale has teeth that do not break through the
-gums and are later absorbed. Since the ancestors of this whale probably
-had teeth, as have other whales at the present time, the appearance of
-teeth in the embryo has been interpreted as a repetition of the original
-condition. Some of the ant-eaters are also toothless, but teeth appear
-in the embryo and are lost later. In the ruminants that lack teeth in
-the front part of the upper jaw, _e.g._ the cow and the sheep, teeth
-develop in the embryo which are subsequently lost.
-
-One interpretation of these facts is that the ancestral adult condition
-is repeated by the embryo, but as I have pointed out above in the cases
-of the teeth in whales, since the teeth do not reach the adult form, and
-do not even break through the gums in some forms, it is obviously
-stretching a point to claim that an adult condition is repeated.
-Moreover, in the case of the birds only the dental ridges appear, and it
-is manifestly absurd to claim in this case that the ancestral adult
-condition of the reptiles is repeated.
-
-That a supposed ancestral stage may be entirely lost in the embryo of
-higher forms is beautifully shown in the development of some of the
-snakes. The snakes are probably derived from lizardlike ancestors, which
-had four legs, yet in the development the rudiments of legs do not
-appear, and this is the more surprising since a few snakes have small
-rudimentary legs. In these, of course, the rudiments of legs must appear
-in the embryo, but in the legless forms even the beginnings of the legs
-have been lost, or at any rate very nearly so.
-
-Outside the group of vertebrates there are also many cases that have
-been interpreted as embryonic repetitions of ancestral stages, but a
-brief examination will suffice to show that many of these cases are
-doubtful, and others little less than fanciful. A few illustrations will
-serve our purpose. The most interesting case is that given by the
-history of the nauplius theory.
-
-The free-living larva of the lower crustaceans—water-fleas, barnacles,
-copepods, ostracods—emerges from the egg as a small, flattened oval form
-with three pairs of appendages. This larva, known as the nauplius,
-occurs also in some of the higher crustaceans, not often, it is true, as
-a free form, as in penæus, but as an embryonic stage. The occurrence of
-this six-legged form throughout the group was interpreted by the
-propounders of the nauplius theory as evidence sufficient to establish
-the view that it represented the ancestor of the whole group of
-Crustacea, which ancestor is, therefore, repeated as an embryonic form.
-This hypothesis was accepted by a large number of eminent embryologists.
-The history of the collapse of the theory is instructive.
-
-It had also been found in one of the groups of higher crustaceans, the
-decapods, containing the crayfish, lobster, and crabs, that another
-characteristic larval form was repeated in many cases. This larva is
-known as the zoëa. It has a body made up of a fused head and thorax
-carrying seven pairs of appendages and of a segmented abdomen of six
-segments. The same kind of evidence that justified the formulation of
-the nauplius theory would lead us to infer that the zoëa is the ancestor
-of the decapods. The later development of the zoëa shows, however, that
-it cannot be such an ancestral form, for, in order to reach the full
-number of segments characteristic of the decapods, new segments are
-intercalated between the cephalothorax and abdomen. In fact, in many
-zoëas this intercalated region is already in existence in a rudimentary
-condition, and small appendages may even be present. A study of the
-comparative anatomy of the crustaceans leaves no grounds for supposing
-that the decapods with their twenty-one segments have been evolved from
-a thirteen-segmented form like the zoëa by the intercalation of eight
-segments in the middle of the body. It follows, if this be admitted, and
-it is generally admitted now, that the zoëa does not represent an
-original ancestral form at all, but a highly modified new form, as new,
-perhaps, as the group of decapods itself. We are forced to conclude,
-then, that the presence of a larval form throughout an entire group
-cannot be accepted as evidence that it represents an ancestral stage. We
-can account for the presence of the zoëa, however, by making a single
-supposition, namely, that the ancestor from which the group of decapod
-has evolved had a larva like the zoëa, and that this larval form has
-been handed down to all of the descendants.
-
-The fate of the zoëa theory cast a shadow over the nauplius theory,
-since the two rested on the same sort of evidence. The outcome was, in
-fact, that the nauplius theory was also abandoned, and this was seen to
-be the more necessary, since a study of the internal anatomy of the
-lowest group of crustaceans, the phyllopods, showed that they have
-probably come directly from many segmented, annelidian ancestors. The
-presence of the nauplius is now generally accounted for by supposing
-that it was a larval form of the ancestor from which the group of
-crustaceans arose.
-
-The most extreme, and in many ways the most uncritical, application of
-the recapitulation theory was that made by Haeckel, more especially his
-attempt to reduce all the higher animals to an ancestral double-walled
-sac with an opening at one end,—the gastræa. He dignified the
-recapitulation theory with an appellation of his own, “The Biogenetic
-Law.” Haeckel’s fanciful and extreme application of the older
-recapitulation theory has probably done more to bring the theory into
-disrepute amongst embryologists than the criticisms of the opponents of
-the theory.
-
-In one of the recognized masterpieces of embryological literature, His’s
-“Unsere Körperform,” we find the strongest protest that has yet been
-made against the Haeckelian pretension that the phylogenetic history is
-the “cause” of the ontogenetic series. His writes: “In the entire series
-of forms which a developing organism runs through, each form is the
-necessary antecedent step of the following. If the embryo is to reach
-the complicated end-forms, it must pass, step by step, through the
-simpler ones. Each step of the series is the physiological consequence
-of the preceding stage and the necessary condition for the following.
-Jumps, or short cuts, of the developmental process, are unknown in the
-physiological process of development. If embryonic forms are the
-inevitable precedents of the mature forms, because the more complicated
-forms must pass through the simpler ones, we can understand the fact
-that paleontological forms are so often like the embryonic forms of
-to-day. The paleontological forms are embryonal, because they have
-remained at the lower stage of development, and the present embryos must
-pass also through lower stages in order to reach the higher. But it is
-by no means necessary for the later, higher forms to pass through
-embryonal forms because their ancestors have once existed in this
-condition. To take a special case, suppose in the course of generations
-a species has increased its length of life gradually from one, two,
-three years to eighty years. The last animal would have had ancestors
-that lived for one year, two years, three years, etc., up to eighty
-years. But who would claim that because the final eighty-year species
-must pass necessarily through one, two, three years, etc., that it does
-so because its ancestors lived one year, two years, three years, etc.?
-The descent theory is correct so far as it maintains that older, simpler
-forms have been the forefathers of later complicated forms. In this case
-the resemblance of the older, simpler forms to the embryos of later
-forms is explained without assuming any law of inheritance whatsoever.
-The same resemblance between the older and simpler adult forms, and the
-present embryonic forms would even remain intelligible were there no
-relation at all between them.”
-
-Interesting and important as is this idea of His, it will not, I think,
-be considered by most embryologists as giving an adequate explanation of
-many facts that we now possess. It expresses, no doubt, a part of the
-truth but not the whole truth.
-
-We come now to a consideration of certain recently ascertained facts
-that put, as I shall try to show, the whole question of embryonic
-repetition in a new light.
-
-A minute and accurate study of the early stages of division or cleavage
-of the egg of annelids has shown a remarkable agreement throughout the
-group. The work of E. B. Wilson on nereis, and on a number of other
-forms, as well as the subsequent work of Mead, Child, and Treadwell on
-other annelids, has shown resemblances in a large number of details,
-involving some very complicated processes.[10]
-
-Footnote 10:
-
-  On the other hand it should not pass unnoticed that Eisigh as shown in
-  one form (in which, however, the eggs are under special conditions
-  being closely packed together) that the usual type of cleavage is
-  altered.
-
-Not only is the same method of cleavage found in most annelids, but the
-same identical form of division is also present in many of the mollusks,
-as shown especially by the work of Conklin, Lillie, and Holmes. This
-resemblance has been discussed at some length by those who have worked
-out these results in the two groups. The general conclusion reached by
-them is that the only possible interpretation of the phenomenon is that
-some sort of genetic connection must exist between the different forms;
-and while not explicitly stated, yet there is not much doubt that some
-at least of these authors have had in mind the view that the annelids
-and mollusks are descended from common ancestors whose eggs segmented as
-do those of most of the mollusks and annelids of the present day. This
-conclusion is, I believe, of more far-reaching importance than has been
-supposed, and may furnish the key that will unlock the whole question of
-the resemblance of embryos to supposed ancestral forms. It is a most
-fortunate circumstance that in the case of this cell lineage the facts
-are of such a kind as to preclude the possibility that the stages in
-common could ever have been ancestral adult stages. If this be granted
-then only two interpretations are possible: the results are due either
-to a coincidence, or to a common embryonic form that is repeated in the
-embryo of many of the descendants. That the similarity is not due to a
-coincidence is made probable from the number and the complexities of the
-cleavage stages.
-
-I believe that we can extend this same interpretation to all other cases
-of embryonic resemblance. It will explain the occurrence of gill-slits
-in the embryo of the bird, and the presence of a notochord in the higher
-forms in exactly the same way as the cleavage stages are explained. But
-how, it may be asked, can we explain the apparent resemblance between
-the embryo of the higher form and the adult of lower groups. The answer
-is that this resemblance is deceptive, and in so far as there is a
-resemblance it depends on the resemblance of the adult of the lower form
-to its own embryonic stages with which we can really make a comparison.
-The gill-slits of the embryo of the chick are to be compared, not with
-those of the adult fish, but with those of the embryo of the fish. It is
-a significant fact, in this connection, that the gill-slits appear as
-early in the embryo of the fish as they do in the bird! The notochord of
-the embryo bird is comparable with that of the embryo of amphioxus, and
-not with the persistent notochord in the adult amphioxus. Here also it
-is of the first importance to find that the notochord appears both in
-the embryo bird and in amphioxus at the very beginning of the
-development. The embryo bird is not fishlike except in so far as there
-are certain organs in the embryo fish that are retained in the adult
-form. The embryo bird bears the same relation to the embryo fish that
-the early segmentation stages of the mollusk bear to the early
-segmentation stages of the annelid. There are certain obvious
-resemblances between this view and that of Von Baer, but there are also
-some fundamental differences between the two conceptions.
-
-Von Baer thought that within each group the embryonic development is the
-same up to a certain point. He supposed that the characters of the group
-are the first to appear, then those of the order, class, family, genus,
-and, finally, of the species. He supposed that two similar species would
-follow the same method of development until the very last stage was
-reached, when each would then add the final touches that give the
-individual its specific character. We may call this the theory of
-embryonic parallelism. Here there is an important difference between my
-view and that of Von Baer, for I should not expect to find the two
-embryos of any two species identical at any stage of their development,
-but at most there might exist a close resemblance between them.
-
-Von Baer’s statement appears to be erroneous from a modern point of view
-in the following respects. We know that in certain large groups some
-forms develop in a very different way from that followed by other
-members of the group, as shown by the cephalopods, for instance, in the
-group of mollusks. Again, it is entirely arbitrary to assume that the
-group-characters are the first to appear, and then successively those of
-the order, family, genus, species. Finally, as has been said above, we
-do not find the early embryos of a group identical; for with a
-sufficient knowledge of the development it is always possible to
-distinguish between the embryos of different species, as well as between
-the adults, only it is more difficult to do so, because the embryonic
-forms are simpler. The most fundamental difference between the view of
-Von Baer and modern views is due to our acceptation of the theory of
-evolution which seems to make it possible to get a deeper insight into
-the meaning of the repetition, that carries us far ahead of Von Baer’s
-position. For with the acceptance of this doctrine we have an
-interpretation of how it is possible for the embryonic stages of most
-members of a group to have the same form, although they are not
-identical. There has been a continuous, although divergent, stream of
-living material, carrying along with it the substance out of which the
-similar embryonic forms are made. As the stream of embryonic material
-divided into different paths it has also changed many of the details,
-sometimes even all; but nevertheless it has often retained the same
-general method of development that is associated with its particular
-composition. We find the likeness, in the sense of similarity of plan,
-accounted for by the inheritance of the same sort of substance; the
-differences in the development must be accounted for in some other way.
-
-Among modern writers Hurst alone has advanced a view that is similar in
-several respects to that which I have here defended. It may be well to
-give his statement, since it brings out certain points of resemblance
-with, as well as certain differences from, my own view.[11] He says:
-“Direct observation has shown that, when an animal species _varies_
-(_i.e._ _becomes_ unlike what it was before) in adult structure, those
-stages in the development which are nearest the adult undergo a similar,
-but usually smaller, change. This is shown in domestic species by the
-observations of Darwin, and the result is in exact harmony with the
-well-known law of Von Baer, which refers to natural species, both nearly
-related and widely dissimilar. Von Baer’s observations as well as
-Darwin’s, and as well as those of every student who has ever compared
-the embryos of two vertebrate species, may be summarized as follows:—
-
-Footnote 11:
-
-  Hurst, C. H., “Biological Theories, III,” “The Recapitulation Theory,”
-  _Natural Science_, Vol. ii., 1893.
-
-“Animals which, though related, are very similar in the adult state,
-resemble each other more closely in early stages of development, often,
-indeed, so closely as to be indistinguishable in those early stages. As
-development proceeds _in such species_, the differences between the two
-embryos compared become more and more pronounced.” On this point, which
-is an essential one, I cannot agree with Hurst; for I do not think that
-the facts show that the early stages of two related forms are
-necessarily more and more alike the farther back we go. The resemblance
-that is sometimes so striking in the earlier stages is due to the fewer
-points there are for comparison, and to the less development of the
-parts then present. Hurst continues: “If similar comparisons could be
-instituted between the ancestral species and its much modified
-descendants, there is no reason for doubting that a similar result would
-be reached. This, indeed, has been done in the case of some breeds of
-pigeons, which we have excellent reasons for believing to be descended
-from _Columba livia_. True, _C. livia_ is not a very remote ancestor,
-but I do not think that will vitiate the argument. Let me quote Darwin
-verbatim: ‘As we have conclusive evidence that the breeds of the pigeon
-are descended from a single wild species, I have compared the young
-within twelve hours after being hatched; I have carefully measured the
-proportions (but will not here give the details) of the beak, width of
-mouth, length of nostril, and of eyelid, size of feet, and length of leg
-in the wild, parent species, in pouters, fantails, runts, barbs,
-dragons, carriers, and tumblers. Now some of these birds when mature
-differ in so extraordinary a manner in the length and form of the beak,
-and in other characters, that they would certainly have been ranked as
-distinct genera if found in a state of nature. But when the nestling
-birds of these several breeds were placed in a row, though most of them
-could just be distinguished, the proportional differences in the above
-specified points were incomparably less than in the full-grown birds.
-Some characteristic points of difference—for instance, that of the width
-of the mouth—could hardly be detected in the young. But there was one
-remarkable exception to this rule, for the young of the short-faced
-tumbler differed from the young of the wild-rock pigeon, and of the
-other breeds in almost exactly the same proportions as in the adult
-state.’”
-
-Hurst concludes that: “The more the adult structure comes to be unlike
-the adult structure of the ancestors, the more do the late stages of
-development undergo a modification of the same kind. This is not mere
-dogma, but it is a simple paraphrase of Von Baer’s law. It is proved
-true not only by the observations of Von Baer and of Darwin, already
-referred to, but by the direct observation of every one who takes the
-trouble to compare the embryos of any two vertebrates, provided only he
-will be content to see what actually lies before him and not the
-phantasms which the recapitulation theory may have printed on his
-imagination.”
-
-The growth of the antlers of stags is cited by Hurst in order to
-illustrate that what has been interpreted as a recapitulation may have a
-different interpretation. “Each stag develops a new pair of antlers in
-each successive year, and each pair of antlers is larger than the pair
-produced in the previous year. This yearly increase in the size of the
-antlers has been put forward as an example of an ontogenetic record of
-past evolution. I, however, deny that it is such a record.”
-
-“The series of ancestors may have possessed larger antlers in each
-generation than in the generation before it. It is not an occasional
-accidental parallelism between the ontogeny and the phylogeny which I
-deny, but the causal relation between the two. Had the ancestors had
-larger antlers than the existing ones, there is no justification for the
-assumption that existing stags would acquire antlers of which each pair,
-in later years, would be smaller than those of the previous year.”
-
-Hurst concludes: “There are many breeds of hornless sheep, but they do
-not bear large horns in early years and then shed them. If a rudiment
-ever appears in the embryo of such sheep, its growth is very early
-arrested.” The case of the appendix in man might have been cited here as
-a case in point. It is supposed to have been larger in the ancestors of
-man, but we do not find it appearing full size in the embryo and later
-becoming rudimentary. The preceding statements will show that, while
-Hurst’s view is similar in some respects to my own, yet it differs in
-one fundamental respect from it, and in this regard he approaches more
-nearly to the theory of Von Baer.
-
-Hertwig has recently raised some new points of issue in regard to the
-recapitulation theory, and since he may appear to have penetrated
-farther than most other embryologists of the present time, it will be
-necessary to examine his view somewhat carefully. He speaks of the
-germ-cell (egg, or spermatozoön) as a species-cell, because it contains,
-in its finer organization, the essential features of the species to
-which it belongs. There are as many of these kinds of cells as there are
-different kinds of animals and plants. Since the bodies of the higher
-animals have developed from these species-cells, so the latter must have
-passed in their phylogeny through a corresponding development from a
-simple to a more and more complex cell-structure. “Our doctrine is, that
-the species-cell, even as the adult, many-celled representative of the
-species, has passed through a progressive, and, indeed, in general a
-corresponding development in the course of phylogeny. This view appears
-to stand in contradiction to the biogenetic law. According to the
-formula that Haeckel has maintained, the germ development is an epitome
-of the genealogy; or the ontogeny is a recapitulation of the phylogeny;
-or, more fully, the series of forms through which the individual
-organism passes during its development from the egg-cell to the finished
-condition is a short, compressed repetition of the longer series of
-forms which the forefathers of the same organism, or the stem-form of
-the species, has passed through, from the earliest appearance of
-organisms to the present time.” “Haeckel admits that the parallel may be
-obliterated, since much may be absent in the ontogeny that formerly
-existed in the phylogeny. If the ontogeny were complete, we could trace
-the whole ancestry.” Hertwig states further, that “The theory of
-biogenesis[12] makes it necessary to change Haeckel’s expression of the
-biogenetic law, so that a contradiction contained in it may be removed.
-We must drop the expression ‘repetition of the form of extinct
-forefathers,’ and put in its place the repetition of forms which are
-necessary for organic development, and lead from the simple to the
-complex. This conception may be illustrated by the egg-cell.”
-
-Footnote 12:
-
-  This term, by which Hertwig designates a particular view of his own,
-  has been already preoccupied in a much wider sense by Huxley to mean
-  that all life comes from preëxisting life. Hertwig means by the theory
-  of biogenesis that as the egg develops there is a constant interchange
-  between itself and its surroundings.
-
-Since each organism begins its life as an egg we must not suppose that
-the primitive conditions of the time, when only single-celled amœbas
-existed on our planet, are repeated. The egg-cell of a living mammal is
-not, according to Hertwig’s hypothesis, an indifferent structure without
-much specialization like an amœba, but is an extraordinarily complex
-end-product of a long historical process, which the organized substance
-has passed through. If the egg of a mammal is different from that of a
-reptile, or of an amphibian, because in its organization it contains the
-basis of a mammal, just so much more must it be different from the
-hypothetical one-celled amœba, which has no other characteristics than
-those that go to make up an amœba. Expressed more generally, the
-developmental process in the many-celled organisms begins, not where it
-began in primitive times, but as the representation of the highest point
-which the organization has at present reached. The development commences
-with the egg, because it is the elemental and fundamental form in which
-organic life is represented in connection with the reproductive process,
-and also because it contains in itself the properties of the species in
-its primordia.
-
-“The egg-cell of the present time, and its one-celled predecessor in the
-phylogenetic history, the amœba, are only comparable in so far as they
-fall under the common definition of the cell, but beyond this they are
-extraordinarily different from each other.”
-
-“The phyletic series must be divided into two different kinds of
-processes:—First. The evolution of the species-cell, which is a steady
-advance from a simple to a complex organization. Second. The
-periodically repeated development of the many-celled individual out of
-the single cell, representative of the species (or the individual
-ontogeny), which in general follows the same rules as the preceding
-ontogeny, but is each time somewhat modified according to the amount to
-which the species-cell has itself been changed in the phylogeny. Similar
-restricting and explanatory additions to the biogenetic law, like those
-stated here for the one-celled stage, must be made in other directions.
-Undoubtedly there exists in a certain sense a parallel between the
-phylogenetic, and the ontogenetic, development.
-
-“On the basis of the general developmental hypothesis on which we stand,
-all forms which in the chain of ancestors were end-products of the
-individual development are now passed through by their descendants as
-embryonic stages, and so in a certain degree are recapitulated. We also
-admit that the embryonic forms of higher animals have many points of
-comparison with the mature forms of related groups standing lower in the
-system.
-
-“Nevertheless, a deeper insight into the conditions relating to these
-resemblances shows that there are very important differences that should
-not be overlooked. Three points need to be mentioned: 1. The
-cell-material which in the ancestral chain gives the basis for each
-ontogenetic process is each time a different material as far as concerns
-its finer organization and primordia. Indeed, the differences become
-greater the farther apart the links of the original chain become. This
-thought may be formulated in another way: The same ontogenetic stages
-that repeat themselves periodically in the course of the phylogeny
-always contain at bottom a somewhat different cell-material. From this
-the second rule follows as a consequence. 2. Between the mature end-form
-of an ancestor and the corresponding embryonic form of a widely remote
-descendant (let us say between the phylogenetic gastræa and the
-embryonic gastrula stage of a living mammal, according to the
-terminology of Haeckel) there exists an important difference, namely,
-that the latter is supplied with numerous primordia which are absent in
-the other, and which force it to proceed to the realization of its
-developmental process. The gastrula, therefore, as the bearer of
-important latent forces, is an entirely different thing from the
-gastræa, which has already reached the goal of its development. 3. In
-the third place, at each stage of the ontogeny outer and inner factors
-are at work, in fact even more intensely than in the fully formed
-organism. Each smallest change that acts anew in this way at the
-beginning of the ontogeny can start an impulse leading to more extensive
-changes in later stages. Thus the presence of yolk and its method of
-distribution in the egg alone suffice to bring about important changes
-in the cleavage, and in the formation of the germ-layers, the blastula,
-and gastrula stages,” etc. “Moreover, the embryo may adapt itself to
-special conditions of embryonic life, and produce organs of an ephemeral
-nature like the amnion, chorion, and placenta.”
-
-“A comparison of ontogenetic with antecedent phylogenetic stages must
-always keep in view the fact that the action of external and internal
-factors has brought about considerable changes in the ontogenetic
-system, and, indeed, in a generally advancing direction, so that in
-reality a later condition can never correspond to a preceding one.”
-
-Hertwig sums up his conclusion in the statement that ontogenetic stages
-give us, therefore, a greatly changed picture of the phylogenetic series
-of adult ancestors. “The two correspond not according to their actual
-contents but only as to their form.” Hertwig also repeats His’s idea,
-that the reason that certain kinds of form repeat themselves in the
-development of animals with a great constancy depends principally on
-this, that they supply the necessary conditions under which alone the
-following higher stage of the ontogeny can be formed. The development,
-for instance, begins with the division of the egg, because this is the
-only way that a one-celled condition can give rise to a many-celled
-form. Again, the organs can be formed only when groups of cells have
-made a closer union with one another. Thus the gastrula must begin with
-the antecedent blastula, etc. Definite forms are, despite all modifying
-influences, held to firmly, because by their presence the complicated
-end-stages can be reached in the simplest and most suitable way.
-
-Thus Hertwig adopts here a little from one doctrine and there a little
-from another, and between his attempt to reinstate the old biogenetic
-law of Haeckel, and to adopt a more modern point of view, he brings
-together a rather curious collection of statements which are not any too
-well coördinated. Take, for example, his description of the relation
-between Haeckel’s gastræa and the embryonic gastrula stage. The latter
-he maintains is a repetition of the other, but only in form, not in
-actual contents. And in another connection we are told that the cause of
-this repetition is that the gastrula is the simplest way in which the
-later stages can be reached, and, therefore, it has been retained. It
-seems to me that Hertwig has undertaken an unnecessary and impossible
-task when he attempts to adjust the old recapitulation theory to more
-modern standards. His statement that the egg is entirely different from
-its amœba prototype is, of course, only the view generally held by all
-embryologists. His mystical statement that the embryonic form _repeats
-the ancestral adult stage in its form, but not in its contents_, will
-scarcely recommend itself as a model of clear thinking. Can we be asked
-to believe for instance that a young chick repeats the ancestral adult
-fish form but not the contents of the fish?
-
-In conclusion, then, it seems to me that _the idea that adult ancestral
-stages have been pushed back into the embryo, and that the embryo
-recapitulates in part these ancestral adult stages is in principle
-false_. The resemblance between the embryos of higher forms and the
-adults of lower forms is due, as I have tried to show, to the presence
-in the embryos of the lower groups of certain organs that remain in the
-adult forms of this group. It is only the embryonic stages of the two
-groups that we are justified in comparing; and their resemblances are
-explained on the assumption that there has been an ancestral adult form
-having these embryonic stages in its development and these stages have
-been handed down to the divergent lines of its descendants.
-
-Since we have come to associate with the name of the recapitulation
-theory the idea of the recurrence of an ancestral adult form, it may be
-better to find a substitute for this term. I suggest, therefore, for the
-view, that the embryos of the higher group repeat the modified form of
-the embryos of the lower groups, the term, the theory of embryonic
-repetition, or, more briefly, the repetition theory.
-
-
-                              Conclusions
-
-In the light of the preceding discussion concerning the evidence in
-favor of the transmutation theory, we may now proceed to sum up our
-general conclusions, and at the same time discuss some further
-possibilities in regard to the descent theory.
-
-The most widely accepted view in regard to the theory of organic
-evolution is that which looks upon the resemblances between the members
-of a group as due to their common descent from one original species that
-has broken up, as it were, into a number of new forms. Strictly applied,
-this means that all the vertebrates have come from one original species,
-all the mollusks from another, the echinoderms from a third, etc. Even
-farther back there may have been a common ancestral species for any two
-of the large groups, as, for example, the annelids and the mollusks; and
-if the relationship of all the many-celled forms be looked upon as
-probable, then they too have originated from one ancestral species.
-
-Many zoologists appear to hesitate to apply strictly this fundamental
-idea contained in the transmutation theory, because, perhaps, they feel
-that it does not fit in with their general experience of living forms.
-Yet there can be no doubt that it is the primary conception of the
-transmutation theory. This is, however, not the whole question, for we
-must further consider the number of individuals of a species that are
-involved.
-
-In some species there are smaller groups of individuals that are more
-like one another than like other individuals of the same species. Such
-groups are called varieties, and are often associated with certain
-localities, or with a special environment. In the latter case they are
-called local varieties. Some of these appear to breed true, not only
-when kept under the same conditions, but even when transferred to a new
-environment. Others change with the environment. It is not improbable
-that the varieties are of a different kind in these two cases, as shown
-by their different behavior when put under new and different
-surroundings. The variety that owes its peculiarities, not to the
-immediate environment, but to some internal condition independent of the
-surroundings, is recognized by some biologists as a smaller species.
-Such species appear to be commoner in plants than in animals, although
-it is possible that this only means that more cases have been found by
-the botanists, owing to the greater ease with which plants can be
-handled. These smaller species, in contradistinction to the ordinary
-Linnæan species, differ from the latter in the smaller amount of
-differences between the groups, and probably also in that they freely
-interbreed, and leave fertile descendants; but whether this is only on
-account of the smaller differences between them than between larger
-species, or because of some more fundamental difference in the kind of
-variation that gives rise to these two kinds of groups, we do not know.
-
-These smaller species, or constant varieties, as we may call them, may
-be looked upon as incipient Linnæan species, which, by further
-variations of the same, or of other sorts, may end by giving rise to
-true species. A genus composed of several species might be formed in
-this way, and then, if each species again broke up into a number of new
-groups, each such group would now be recognized as a genus, and the
-group of genera would form a family, etc. The process continuing, a
-whole class, or order, or even phylum, might be the result of this
-process that began in a single species.
-
-But we must look still farther, and inquire whether the start was made
-from a single individual, that began to vary, or from a number of
-individuals, or even from all the individuals, of a species. If we
-suppose the result to depend on some external cause that affects all the
-individuals of a species alike, then it might appear that the species,
-or at least as many individuals of a species as are affected, will give
-the starting-point for the new group. But if the new variation arises
-not directly as a response to some change in the surroundings, then it
-might appear in one or in a few individuals at a time. Let us consider
-what the results might be under these two heads.
-
-If amongst the descendants of a single individual a new form or a number
-of new forms were to arise, then, if they represented only a variety,
-they would cross with the other forms like the parent species; and,
-under these conditions, it is generally assumed that the new variety
-would be swamped. If, however, the new forms have the value of new
-species, then, _ex hypothese_, they are no longer fertile with the
-original forms, and might perpetuate themselves by self-fertilization,
-as would be possible in some of the higher plants, and in those animals
-that are bisexual. But as a rule even bisexual forms are not
-self-fertilized, and, therefore, unless a number of offspring arose from
-the same form the chance of propagation would be small.
-
-If, however, a number of new forms appeared at the same time and left a
-number of descendants, then the probability that the new group might
-perpetuate itself is greater, and the chance that such a group would
-arise is in proportion to the number of individuals that varied in the
-same direction simultaneously. In this case the new species has not come
-from a single individual or even from a pair of individuals, but from a
-number of individuals that have varied more or less in the same
-direction.
-
-This point of view puts the descent theory in a somewhat unforeseen
-light, for we cannot assume in such a case that the similarities of the
-members of even the same species are due to direct descent from an
-original ancestor, because there are supposed to have been a number of
-ancestors that have all changed in the same direction. The question is
-further complicated by the fact that the new individuals begin to
-interbreed, so that their descendants come to have, after a time, the
-common blood, so to speak, of all the new forms. If with each union
-there is a blending of the substances of the individuals, there will
-result in the end a common substance representing the commingled racial
-germ-plasm.
-
-A new starting-point is then reached, and new species may continue to be
-formed out of this homogeneous material. Thus, in a sense, we have
-reached a position which, although it appears at first quite different
-from the ordinary view, yet, after all, gives us the same standpoint as
-that assumed by the transmutation theory; for, while the latter assumes
-that the resemblances of the members of a group are due to descent from
-the same original form, and often by implication from a single
-individual, we have here reached the conclusion that it is only a
-common, commingled germ-plasm that is the common inheritance.
-
-When we examine almost any group of living animals or plants, whether
-they are low or high in organization, we find that it is composed of a
-great many different species, and so far as geology gives any answer, we
-find that this must have been true in the past also. Why, then, do we
-suppose that all the members of the higher groups have come from a
-single original species or variety? Why may not all, or many, of the
-similar species of the lower group have changed into the species of the
-higher group,—species for species? If this happened, the resemblance of
-the new species of the group could be accounted for on the supposition
-that their ancestors were also like one another. The likeness would not
-be due, then, to a common descent, and it would be false to attempt to
-explain their likeness as due to a common inheritance. But before going
-farther, it may be well to inquire to what the resemblances of the
-individuals of the original species were due; for, if they have come
-from an older group that has given rise to divergent lines of descent,
-then we are only removing the explanation one step farther back. If this
-original group has come from numerous species of a still older group,
-and this, in turn, from an older one still, then we must go back to the
-first forms of life that appeared on the globe, and suppose that the
-individuals of these primitive forms are the originals of the species
-that we find living to-day. For instance, it is thinkable that each
-species of vertebrate arose from a single group of the earliest forms of
-life that appeared on the surface of the earth. If this were the case,
-there must have been as many different kinds of species of the original
-group as there are species alive at the present time, and throughout all
-the past. This view finds no support from our knowledge of fossil
-remains, and, although it may be admitted that this knowledge is very
-incomplete, yet, if the process of evolution had taken place as sketched
-out above, we should expect, at least, to have found some traces of it
-amongst fossil forms. Since this question is an historical one, we can,
-at best, only expect to decide which of all the possible suggestions is
-the more probable.
-
-We conclude, then, that it is more probable that the vertebrates, the
-mollusks, the insects, the crustaceans, the annelids, the cœlenterates,
-and the sponges, etc., have come each from a single original species.
-Their resemblances are due to a common inheritance from a common
-ancestral species. Even if it be probable that at the time when the
-group of vertebrates arose from a single species, there were in
-existence other closely related species, yet we must suppose, if we
-adhere to our point of view, that these other related species have had
-nothing to do with the group of vertebrates, but that they have died
-out. Moreover, we must suppose that each order, each class of
-vertebrate, has come from a single original species; each family has had
-a similar origin, as well as each genus, but, of course, at different
-periods of time. Let us not shrink from carrying this principle to its
-most extreme point, for, unless the principle is absolutely true, then
-our much boasted explanation of the resemblances of forms in the same
-group will be thrown into hopeless confusion.
-
-Let us ask another question in this connection. If a single species gave
-rise to a group of new species that represented the first vertebrates,
-they would have formed the first genus; and if the descendants of these
-diverged again so that new genera were formed, then a group which we
-should call a family would have been formed.
-
-As the divergence went on, an _order_ would be developed, and then a
-_class_, and then a _phylum_. The common characters possessed by the
-members of this phylum would have been present in the original species
-that began to diverge. Hence, we find the definition of the phylum
-containing only those points that are the features possessed by all of
-the descendants, and in the same way we should try to construct the
-definition of each of the subordinate groups. This is the ideal of the
-principle of classification based on the theory of descent with
-divergence. If we admit the possibility of the other view that I have
-mentioned above, or of any other of the numerous possibilities that will
-readily suggest themselves, then we must be prepared to give up some of
-the most attractive features of the explanation of resemblance as due to
-descent.
-
-That all biologists believe strictly in divergent descent, to the
-exclusion of any other processes, is not the case. And, as I have said
-before, since we are dealing with an historical question, it would be
-very unwise, in our present ignorance on many points, to pretend that we
-have any direct proof of the explanation that we find generally given to
-account for the resemblances of the species of a group to each other. At
-most we can claim that it is the simplest point of view, and that most
-biologists believe it to be also the most probable. It has been
-suggested that, in some cases, the new forms that arise from two or more
-species run a parallel course. If the original forms from which they
-came were very much alike, it would soon be impossible to say what the
-parentage of a particular form was; that is, to which of the two
-original forms it belonged. It has also been suggested that even a
-convergence has at times taken place, so that the descendants of
-different species have become more alike than the original forms, _at
-least in some one or more respects_. This last limitation is the saving
-clause, for species differ in so many points that, even when they
-converge in a few, it is unlikely that they will do so in all, and,
-therefore, the deception may be discovered by the acute observer. One
-famous paleontologist has gone so far even as to suppose that a species
-may change its generic characters, so that it goes over bodily into a
-new genus without losing its specific characters. If such things do
-occur, then our classifications may well be the laughing-stock of
-Nature.
-
-
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-
-
-
-
-                               CHAPTER IV
-
-        DARWIN’S THEORIES OF ARTIFICIAL AND OF NATURAL SELECTION
-
-                       The Principle of Selection
-
-
-Darwin’s theory of natural selection is preëminently a theory of
-adaptation. It appears, in fact, better suited to explain this
-phenomenon than that of the “origin of species.” Darwin prepared his
-reader for the ideas contained in the theory of natural selection by a
-brief consideration of the results of artificial selection; and since
-the key to the situation is, I believe, to be found in just this
-supposed resemblance, we cannot do better than examine the theories in
-the order followed by Darwin himself.
-
-One of the means by which the artificial races of animals and plants
-have been formed by man is selection. The breeder picks out individuals
-having a certain peculiarity, and allows them to breed together. He
-hopes to find among the offspring, not only individuals like the parent
-forms, but also some that have the special peculiarity even more
-strongly developed. If such are found, they are isolated and allowed to
-breed, and in the next generation it is hoped to find one or more new
-individuals that show still more developed the special character that is
-sought. This process, repeated through a number of generations, is
-supposed to have led to the formation of many of our various forms of
-domesticated animals and plants.
-
-This heaping up as a result of the union of similar individuals cannot
-for a moment be supposed to be the outcome of the addition of the two
-variations to each other. Such an idea is counter to all the most
-familiar facts of inheritance. For instance, when two similar forms
-unite, we do not find that the young show all the characters of the
-mother plus all those of the father, _i.e._ each peculiarity that is the
-same in both, increased twofold. On the contrary, the young are in the
-vast majority of cases not essentially different from either parent.
-
-A more thorough examination of the facts shows that the problem is by no
-means so simple as the preceding general statement might lead one to
-suppose, for our experience shows that it is not always possible to
-increase all variations by selection, and, furthermore, there is very
-soon found a limit, even in favorable cases, to the extent to which the
-process can be carried. The most important point appears to be the
-nature of the variations themselves which may arise from different
-causes, and which have different values in relation to the possibility
-of their continuation.
-
-We may begin, therefore, by following Darwin in his analysis of
-variation, as given in the opening chapter of the “Origin of Species.”
-He thinks that the great amount of variation shown by domesticated
-animals and plants is due, in the first place, to the new conditions of
-life to which they are exposed, and also to the lack of uniformity of
-these conditions. Darwin thinks, also, that there is some probability
-that this variability is due, in part, to an excess of food. “It seems
-clear that organic beings must be exposed during several generations to
-new conditions to cause any great amount of variation, and that when the
-organization has once begun to vary, it generally continues varying for
-many generations. No case is on record of a variable organism ceasing to
-vary under cultivation. Our oldest cultivated plants, such as wheat,
-still yield new varieties; our oldest domesticated animals are still
-capable of rapid improvement or modification.” In this statement of
-Darwin, full of significance, we must be careful to notice that he does
-not mean to imply, when he states that an organism that has once begun
-to vary continues to vary for many generations, that this continuous
-variation is always in the same direction, but only that new
-combinations, scattering in all directions, continue to appear.
-
-The nature of the organism seemed to Darwin to be a more important
-factor in the origin of new variations than the external conditions,
-“for nearly similar variations sometimes arise under, as far as we can
-judge, dissimilar conditions; and, on the other hand, dissimilar
-variations arise under conditions which appear to be nearly uniform.”
-The following statement is important in connection with the origin of
-“definite” variations. “Each of the endless variations which we see in
-the plumage of our fowls must have had some efficient cause; and if the
-same causes were to act uniformly during a long series of generations on
-many individuals, all probably would be modified in the same direction.”
-Here we find an explicit statement in regard to the accumulation of
-variation in a given direction as the result of an external agent, but
-Darwin hastens to add: “Indefinite variability is a much more common
-result of changed conditions than definite variability, and has probably
-played a more important part in the formation of our domestic races. We
-see indefinite variability in the endless slight peculiarities which
-distinguish the individuals of the same species, and which cannot be
-accounted for by inheritance from either parent or from some more remote
-ancestor. Even strongly marked differences occasionally appear in the
-young of the same litter, and in seedlings from the same seed capsule.
-At long intervals of time, out of millions of individuals reared in the
-same country and fed on nearly the same food, deviations of structure so
-strongly pronounced as to deserve to be called monstrosities arise; but
-monstrosities cannot be separated by any distinct line from slighter
-variations.”
-
-Another cause of variation, Darwin believes, is in the inherited effect
-of “habit and of the use and disuse of parts,” or what is generally
-known as the Lamarckian factor of heredity. Darwin believes that changes
-in the body of the parent, that are the result of the use or of the
-disuse of a part, may be transmitted to the descendants, and cites a
-number of cases which he credits to this process. As we shall deal more
-fully with this topic in another chapter, we may treat it here quite
-briefly. As an example of the inheritance of disuse, Darwin gives the
-following case: “I find in the domestic duck that the bones of the wing
-weigh less and the bones of the leg more in proportion to the whole
-skeleton than do the same bones in the wild duck, and this change may be
-safely attributed to the domestic duck flying much less and walking more
-than its wild parents.” The great and inherited development of the
-udders of cows and of goats in countries where they are habitually
-milked, in comparison with these organs in other countries, is given as
-another instance of the effect of use. “Not one of our domestic animals
-can be named that in some country has not drooping ears, and the view
-has been suggested that the drooping is due to the disuse of the muscles
-of the ears from the animals being seldom much alarmed.”
-
-It need scarcely be pointed out here, that, in the first case given,
-those ducks would have been most likely to remain in confinement that
-had less well-developed wings, and hence at the start artificial
-selection may have served to bring about the result. The great
-development of the udders of cows and of goats is obviously connected
-with the greater milk-giving qualities of these animals, which may have
-been selected for this purpose.
-
-Another “law” of variation recognized by Darwin is what is called
-correlated variation. For example, it has been found that cats which are
-entirely white and have blue eyes are generally deaf, and this is stated
-to be confined to the males. The teeth of hairless dogs are imperfect;
-pigeons with feathered feet have skin between the outer toes, and those
-with short beaks have small feet, and _vice versa_.
-
-Another source of variation is that of reversion, or the reappearance in
-the offspring of characters once possessed by the ancestors. Finally,
-Darwin thinks that a source of variation is to be found in modifications
-due to the influence of a previous union with another male, or, as it is
-generally called, telegony. As an example Darwin cites the famous case
-of Lord Morton’s mare. “A nearly purely bred Arabian chestnut mare bore
-a hybrid to a quagga. She subsequently produced two colts by a black
-Arabian horse. These colts were partially dun-colored and were striped
-on the legs more plainly than the real hybrid or even than the
-quagga.”[13] This case, however, is not above suspicion, since it is
-well known that stripes often appear on young horses, and the careful
-analysis made later by Ewart, as well as his other experiments on the
-possibility of the transmission of influences of this sort, puts the
-whole matter in a very dubious light.
-
-These citations show that Darwin recognized quite a number of sources of
-variation, and, although he freely admits that “our ignorance of the
-laws of variation is profound,” yet some at least of these sources of
-variation are very questionable. Be this as it may, it is important to
-emphasize that Darwin recognized two main sources of variation,—one of
-which is the indefinite, or fluctuating, variability that appears
-constantly in domesticated animals and plants, and the other, definite
-variability, or a change in a definite direction, that can often be
-traced to the direct action of the environment on the parent or on its
-reproductive cells. It is the former, _i.e._ the fluctuating
-variability, that, according to Darwin, has been used by the breeder to
-produce most of our domestic races. In regard to the other source of
-variation, the definite kind, we must analyze the facts more closely.
-
-Footnote 13:
-
-  “Animals and Plants under Domestication,” Chap. IX.
-
-A definite change in the surroundings might bring about a definite
-change in the next generation, because the new condition acts either on
-the developing organism, or on the egg itself from which the individual
-develops. The distinction may be one of importance, for, if the new
-condition only effects the developing organism directly, then, when the
-influence is removed, there should be a return to the former condition;
-but if the egg itself is affected, so that it is fundamentally changed,
-then the effect might persist even if the animal were returned to its
-former environment. More important still is Darwin’s recognition of the
-cumulative effect in a given direction of external influences, for a new
-variation, that was slight at first, might, through prolonged action,
-continue to become more developed without any other processes affecting
-the organism.
-
-From the Darwinian point of view, however, the all-important source for
-the origin of new forms is the fluctuating variation, which is made use
-of both in the process of artificial and of natural selection. We may
-now proceed to inquire how this is supposed to take place.
-
-It has been stated that, by means of artificial selection, Darwin
-believes the breeder has produced the greater number of domesticated
-animals and plants. The most important question is what sort of
-variations he has made use of in order to produce his result. Has he
-made use of the fluctuating variations, or of the definite ones? It is
-difficult, if not impossible, to answer this question in most cases,
-because the breeder does not always distinguish between the two. There
-can be little question, however, that he may sometimes have made use of
-the definite kinds, whether these are the outcome of external or of
-internal influences. The question has been seriously raised only in
-recent years, and we are still uncertain how far we can accumulate and
-fix a variation that is of the fluctuating kind. In a few cases it has
-been found that the upper limit is soon reached, as shown by De Vries’s
-experiments with clover, and it is always possible that a definite
-variation of the right sort may arise at any stage of the process. If
-this should occur, then a new standard is introduced from which, as from
-a new base, variations fluctuating in the desired direction may be
-selected.
-
-This question, before all others, ought to be settled before we begin to
-speculate further as to what selection is able to accomplish.
-
-Darwin’s theory is often stated in such a general way that it would be
-applicable to either sort of variation; but if definite variation can go
-on accumulating without selection, then possibly we could account for
-evolution without supposing any other process to intervene. Under these
-circumstances all that could be claimed for selection would be the
-destruction of those variations incapable of living, or of competing
-with other forms. Hence the process of selection would have an entirely
-negative value.
-
-The way in which domesticated animals and plants have originated is
-explained by Darwin in the following significant passage:—
-
-“Let us now briefly consider the steps by which domestic races have been
-produced, either from one or from several allied species. Some effect
-may be attributed to the direct and definite action of the external
-conditions of life, and some to habit; but he would be a bold man who
-would account by such agencies for the differences between a dray- and
-race-horse, a greyhound and bloodhound, a carrier and tumbler pigeon.
-One of the most remarkable features in our domesticated races is that we
-see in them adaptation, not indeed to the animal’s or plant’s own good,
-but to man’s use or fancy. Some variations useful to him have probably
-arisen suddenly, or by one step; many botanists, for instance, believe
-that the fuller’s-teasel, with its hooks, which cannot be rivalled by
-any mechanical contrivance, is only a variety of the wild Dipsacus; and
-this amount of change may have suddenly arisen in a seedling. So it has
-probably been with the turnspit dog; and this is known to have been the
-case with the ancon sheep. But when we compare the dray-horse and
-race-horse, the dromedary and camel, the various breeds of sheep fitted
-either for cultivated land or mountain pasture, with the wool of one
-breed good for one purpose, and that of another breed for another
-purpose; when we compare the many breeds of dogs, each good for man in
-different ways; when we compare the game-cock, so pertinacious in
-battle, with other breeds so little quarrelsome, with ‘everlasting
-layers’ which never desire to sit, and with the bantam so small and
-elegant; when we compare the host of agricultural, culinary, orchard,
-and flower-garden races of plants, most useful to man at different
-seasons and for different purposes, or so beautiful in his eyes, we
-must, I think, look further than to mere variability. We cannot suppose
-that all the breeds were suddenly produced as perfect and as useful as
-we now see them; indeed, in many cases, we know that this has not been
-their history. The key is man’s power of accumulative selection: nature
-gives successive variations; man adds them up in certain directions
-useful to him. In this sense he may be said to have made for himself
-useful breeds.”
-
-Darwin also gives the following striking examples, which make probable
-the view that domestic forms have really been made by man selecting
-those variations that are useful to him:—
-
-“In regard to plants, there is another means of observing the
-accumulated effects of selection—namely, by comparing the diversity of
-flowers in the different varieties of the same species in the
-flower-garden; the diversity of leaves, pods, or tubers, or whatever
-part is valued, in the kitchen-garden, in comparison with the flowers of
-the same varieties; and the diversity of fruit of the same species in
-the orchard, in comparison with the leaves and flowers of the same set
-of varieties. See how different the leaves of the cabbage are, and how
-extremely alike the flowers; how unlike the flowers of the heartsease
-are, and how alike the leaves; how much the fruit of the different kinds
-of gooseberries differ in size, color, shape, and hairiness, and yet the
-flowers present very slight differences. It is not that the varieties
-which differ largely in some one point do not differ at all in other
-points; this is hardly ever,—I speak after careful observation,—perhaps
-never, the case. The law of correlated variation, the importance of
-which should never be overlooked, will insure some differences; but, as
-a general rule, it cannot be doubted that the continued selection of
-slight variations, either in the leaves, the flowers, or the fruit, will
-produce races differing from each other chiefly in these characters.”
-
-Exception may perhaps be taken to the concluding sentence, for,
-interesting as the facts here recorded certainly are, it does not
-necessarily follow that all domestic products have arisen “by the
-continued selection of slight variations,” however probable the
-conclusion may appear. Darwin also believes that a process of
-“unconscious selection” has given even more important “results than
-methodical selection.” By unconscious selection is meant the outcome of
-“every one trying to possess and breed from best individual animals.”
-“Thus a man who intends keeping pointers naturally tries to get as good
-dogs as he can, and afterwards breeds from his own best dogs, but he has
-no wish, or expectation of permanently altering the breed. Nevertheless
-we may infer that this process, continued during centuries, would
-improve and modify any breed.... There is reason to believe that the
-King Charles spaniel has been unconsciously modified to a large extent
-since the time of that monarch.”
-
-The enormous length of time required to produce new species by the
-selection of fluctuating variations is everywhere admitted by Darwin;
-nowhere perhaps more strikingly than in the following statement: “If it
-has taken centuries or thousands of years to improve or modify most of
-our plants up to their present standard of usefulness to man, we can
-understand how it is that neither Australia, the Cape of Good Hope, nor
-any other region inhabited by quite uncivilized man has afforded us a
-single plant worth culture. It is not that these countries, so rich in
-species, do not by a strange chance possess the aboriginal stocks of any
-useful plants, but that the native plants have not been improved by
-continued selection up to a standard of perfection comparable with that
-acquired by the plants in countries anciently civilized.”
-
-In reply to this, it may be said that if the selection of fluctuating
-variations leads to an accumulation in the given direction, it is not
-apparent why it should take thousands of years to produce a new race, or
-require such a high degree of skill as Darwin supposes the breeder to
-possess.
-
-The conditions favorable to artificial selection are, according to
-Darwin: 1. The possession of a large number of individuals, for in this
-way the chance of the desired variation appearing is increased. 2.
-Prevention of intercrossing, such as results when the land is enclosed,
-so that new forms may be kept apart. 3. Changed conditions, as
-introducing variability. 4. The intercrossing of aboriginally distinct
-species. 5. The intercrossing of new breeds, “but the importance of
-intercrossing has been much exaggerated.” 6. In plants propagation of
-bud variations by means of cuttings. The chapter concludes with the
-statement, “Over all these causes of Change, the accumulative action of
-Selection, whether applied methodically and quickly, or unconsciously
-and slowly, but more efficiently, seems to have been the predominant
-Power.”
-
-Variability, Darwin says, is governed by many unknown laws, and the
-final result is “infinitely complex.” If this is so, we may at least
-hesitate before we accept the statement that selection of fluctuating
-variations has been the only principle that has brought about these
-results. This is a most important point, for, as we shall see, the
-central question in the theory of natural selection has come to be
-whether by the accumulation of fluctuating variations a new species
-could ever be produced. If it be admitted that the evidence from
-artificial selection is far from convincing, in showing that selection
-of fluctuating variations could have been the main source, even in the
-formation of new races, we need not be prejudiced in favor of such a
-process, when we come to examine the formation of species in nature.
-
-There are still other questions raised in this same chapter that demand
-serious consideration. Darwin writes as follows:—
-
-“When we look to the hereditary varieties or races of our domestic
-animals and plants, and compare them with closely allied species, we
-generally perceive in each domestic race, as already remarked, less
-uniformity of character than in true species. Domestic races often have
-a somewhat monstrous character; by which I mean, that, although
-differing from each other, and from other species of the same genus, in
-several trifling respects, they often differ in an extreme degree in
-some one part, both when compared one with another, and more especially
-when compared with the species under nature to which they are nearest
-allied. With these exceptions (and with that of the perfect fertility of
-varieties when crossed,—a subject hereafter to be discussed), domestic
-races of the same species differ from each other in the same manner as
-do the closely allied species of the same genus in a state of nature,
-but the differences in most cases are less in degree. This must be
-admitted as true, for the domestic races of many animals and plants have
-been ranked by some competent judges as the descendants of aboriginally
-distinct species, and by other competent judges as mere varieties. If
-any well-marked distinction existed between a domestic race and a
-species, this source of doubt would not so perpetually recur.”
-
-The point here raised in regard to the systematic value of the new forms
-is the question that first demands our attention. We must exclude all
-those cases in which several original species have been blended to make
-a new form, because the results are too complicated to make use of at
-present. The domesticated races of dogs appear to have had such a
-multiple origin, the origin of horses is in doubt; but the domesticated
-pigeons, ducks, rabbits, and fowls are supposed, by Darwin, to have come
-each from one original wild species. The great variety of the domestic
-pigeons gives perhaps the most striking illustration of changes that
-have taken place under domestication; and Darwin lays great stress on
-the evidence from this source.
-
-It seems probable in this case, (1) that all the different races of
-pigeons have come from one original species; (2) that the structural
-differences are in some respects as great as those recognized by
-systematists as specifically distinct; (3) that the different races
-breed true to their kind; (4) that the result has been reached mainly by
-selecting and isolating variations that have appeared under
-domestication, and that probably some, at least, of these variations
-were fluctuating ones.
-
-Does not this grant all that Darwin contends for? In one sense, yes; in
-another, no! The results appear to show that by artificial selection of
-some kind a group of new forms may be produced that in many respects
-resemble a natural family, or a genus; but if this is to be interpreted
-to mean that the result is the same as that by which natural groups have
-arisen, then I think that there are good reasons for dissenting from
-such a conclusion. Moreover, we must not grant too readily that the
-different races of pigeons have arisen by the selection of _fluctuating
-variations_ alone, for this is not established with any great degree of
-probability by the evidence.
-
-In regard to the first point we find that one of the most striking
-differences between species in nature is their infertility, and the
-infertility of their offspring when intercrossed. This is a very general
-rule, so far as we know. In regard to the different races of
-domesticated forms, the most significant fact is that, no matter how
-different they may be, they are perfectly fertile _inter se_. In this
-respect, as well as in others, there are important differences between
-domesticated races and wild species. The further difference, that has
-been pointed out by a number of writers, should also not pass unnoticed,
-namely, that the domestic forms differ from each other in the extreme
-development of some one character, and not in a large number of less
-conspicuous characters, as is the case in wild species.
-
-These considerations show that, interesting and suggestive as are the
-facts of artificial selection, they fail to demonstrate the main point
-for which they are used by Darwin. With the most rigorous attention to
-the process of artificial selection, new species comparable in all
-respects to wild ones have not been formed, even in those cases in which
-the variation has been carried farthest (where the history of the forms
-is most completely known).
-
-There is another point on which emphasis should be laid. If by selecting
-the most extreme forms in each generation and breeding from them the
-standard can be raised, it might appear that we could go on indefinitely
-in the same direction, and produce, for instance, pigeons with legs five
-metres long, and with necks of corresponding length. But experience has
-shown that this cannot be done. As Darwin frequently remarks, the
-breeder is entirely helpless until the desired variation appears. It
-seems possible, by selecting the more extreme of the fluctuating
-variations in each generation, that a higher plane of variation is
-established, and even that more extreme forms are likely to arise for a
-few generations; but, even if this is the case, a limit is soon reached
-beyond which it is impossible to go.
-
-The facts of observation show, that when a new variety appears its
-descendants are more likely, on the average, to produce proportionately
-more individuals that show the same variation, and some even that may go
-still farther in the same direction. If these latter are chosen to be
-the parents of the next generation, then once more the offspring may
-show the same advance; but little by little the advance slows down,
-until before very long it may cease altogether. Unless, then, a new kind
-of variation appears, or a new standard of variation develops of a
-different kind, the result of selection of fluctuating variations has
-reached its limit. Our experience seems, therefore, to teach us that
-selection of fluctuating variations leads us to only a certain point,
-and then stops in this direction. We get no evidence from the facts in
-favor of the view that the process, if carried on for a long time, could
-ever produce such great changes, or the kind of changes, as those seen
-in wild animals and plants.
-
-
-                  Variation and Competition in Nature
-
-Darwin rests his theory on the small individual variations which occur
-in nature, as the following quotation shows:—
-
-“It may be doubted whether sudden and considerable deviations of
-structure such as we occasionally see in our domestic productions, more
-especially with plants, are ever permanently propagated in a state of
-nature. Almost every part of every organic being is so beautifully
-related to its complex conditions of life that it seems as improbable
-that any part should have been suddenly produced perfect, as that a
-complex machine should have been invented by man in a perfect state.
-Under domestication monstrosities sometimes occur which resemble normal
-structures in widely different animals. Thus pigs have occasionally been
-born with a sort of proboscis, and if any wild species of the same genus
-had naturally possessed a proboscis, it might have been argued that this
-had appeared as a monstrosity; but I have as yet failed to find, after
-diligent search, cases of monstrosities resembling normal structures in
-nearly allied forms, and these alone bear on the question. If monstrous
-forms of this kind ever do appear in a state of nature and are capable
-of reproduction (which is not always the case), as they occur rarely and
-singly, their preservation would depend on unusually favorable
-circumstances. They would, also, during the first and succeeding
-generations cross with the ordinary form, and thus their abnormal
-character would almost inevitably be lost.”
-
-It is clear that Darwin does not think that the sudden and large
-variations that sometimes occur furnish the basis for natural selection,
-and the final statement in the last citation (which was added in later
-editions of the “Origin of Species”), to the effect that if such
-monstrous variations appeared as single or occasional variations they
-would be lost by intercrossing implies that, in general, single
-variations would likewise be lost unless they appeared in a sufficient
-number of individuals to maintain themselves against the swamping
-effects of intercrossing.
-
-It is necessary to quote again, in order to show that, in some cases at
-least, Darwin believed selection plays little or no part in the origin
-and maintenance of certain peculiarities that are of no use to the
-species. “There is one point connected with individual differences,
-which is extremely perplexing: I refer to those genera which have been
-called protean or ‘polymorphic,’ in which the species present an
-inordinate amount of variation. With respect to many of these forms,
-hardly two naturalists agree, whether to rank them as species or as
-varieties. We may instance Rubus, Rosa, and Hieracium amongst plants,
-several genera of insects and of Brachiopod shells. In most polymorphic
-genera some of the species have fixed and definite characters. Genera
-which are polymorphic in one country seem to be, with a few exceptions,
-polymorphic in other countries, and likewise, judging from Brachiopod
-shells, at former periods of time. These facts are very perplexing, for
-they seem to show that this kind of variability is independent of the
-conditions of life. I am inclined to suspect that we see, at least in
-some of these polymorphic genera, variations which are of no service or
-disservice to the species, and which consequently have not been seized
-on by selection to act on and accumulate, in the same manner as man
-accumulates in any given direction individual differences in his
-domesticated productions. These individual differences generally affect
-what naturalists consider unimportant parts; but I could show by a long
-catalogue of facts, that parts which must be called important, whether
-viewed under a physiological or classificatory point of view, sometimes
-vary in the individuals of the same species. I am convinced that the
-most experienced naturalist would be surprised at the number of cases of
-variability, even in important parts of structure, which he could
-collect on good authority, as I have collected, during a course of
-years.”
-
-After pointing out that naturalists have no definite standard to
-determine whether a group of individuals is a variety or a species,
-Darwin makes the highly important admissions contained in the following
-paragraph: “Hence, I look at individual differences, though of small
-interest to the systematist, as of the highest importance for us, as
-being the first steps toward such slight varieties as are barely thought
-worth recording in works on natural history. And I look at varieties
-which are in any degree more distinct and permanent, as steps toward
-more strongly marked and permanent varieties; and at the latter, as
-leading to subspecies, and then to species. The passage from one stage
-of difference to another may, in many cases, be the simple result of the
-nature of the organism and of the different physical conditions to which
-it has long been exposed; but with respect to the more important and
-adaptive characters, the passage from one stage of difference to another
-may be safely attributed to the cumulative action of natural selection,
-hereafter to be explained, and to the effects of the increased use or
-disuse of parts. A well-marked variety may therefore be called an
-incipient species; but whether this belief is justifiable must be judged
-by the weight of the various facts and considerations to be given
-throughout this work.”
-
-In this paragraph attention should be called especially, first, to the
-statement in respect to the origin of varieties, which are said to arise
-through individual differences. It is not clear whether these
-differences are supposed to have appeared first in one, or in a few
-individuals, or in large numbers at the same time. Again, especial note
-should be made of the striking admission, that the passage from one
-stage to another may, in many cases, be the simple result of the nature
-of the organism and of the physical conditions surrounding it; but with
-respect to the more important and adaptive differences, natural
-selection “may safely” be supposed to have intervened. Is it to be
-wondered at that Darwin’s critics have sometimes accused him of playing
-fast and loose with the origin of varieties? And since this question is
-fundamental for the theory of natural selection, it is much to be
-regretted that Darwin leaves the matter in such a hazy condition. It may
-be said that, at the time when he wrote, he made the best of the
-evidence in regard to the origin of varieties. Be this as it may, a
-theory standing on no better foundations than this is not likely to be
-found satisfactory at the present time.
-
-We come now to the most important chapters, the third and the fourth, of
-the “Origin of Species,” dealing with “the struggle for existence,”
-“natural selection,” or the “survival of the fittest.” Behind these
-fatal phrases, which have become almost household words, lurk many
-dangers for the unwary.
-
-“It has been seen in the last chapter that amongst organic beings in a
-state of nature there is some individual variability: indeed I am not
-aware that this has ever been disputed. It is immaterial for us whether
-a multitude of doubtful forms be called species or subspecies or
-varieties; what rank, for instance, the two or three hundred doubtful
-forms of British plants are entitled to hold, if the existence of any
-well-marked varieties be admitted. But the mere existence of individual
-variability and of some few well-marked varieties, though necessary as
-the foundation for the work, helps us but little in understanding how
-species arise in nature. How have all those exquisite adaptions of one
-part of the organization to another part, and to the conditions of life,
-and of one organic being to another being, been perfected? We see these
-beautiful coadaptions most plainly in the woodpecker and the mistletoe;
-and only a little less plainly in the humblest parasite which clings to
-the hairs of a quadruped or feathers of a bird; in the structure of the
-beetle which dives through the water; in the plumed seed which is wafted
-by the gentlest breeze; in short, we see beautiful adaptions everywhere
-and in every part of the organic world.
-
-“Again, it may be asked, how is it that varieties, which I have called
-incipient species, become ultimately converted into good and distinct
-species, which in most cases obviously differ from each other far more
-than do the varieties of the same species? How do those groups of
-species, which constitute what are called distinct genera, and which
-differ from each other more than do the species of the same genus,
-arise? All these results, as we shall more fully see in the next
-chapter, follow from the struggle for life. Owing to this struggle,
-variations, however slight and from whatever cause proceeding, if they
-be in any degree profitable to the individuals of a species, in their
-infinitely complex relations to other organic beings and to their
-physical conditions of life, will tend to the preservation of such
-individuals, and will generally be inherited by the offspring. The
-offspring, also, will thus have a better chance of surviving, for, of
-the many individuals of any species which are periodically born, but a
-small number can survive. I have called this principle, by which each
-slight variation, if useful, is preserved, by the term Natural
-Selection, in order to mark its relation to man’s power of selection.
-But the expression often used by Mr. Herbert Spencer of the Survival of
-the Fittest is more accurate, and is sometimes equally convenient. We
-have seen that man by selection can certainly produce great results, and
-can adapt organic beings to his own uses, through the accumulation of
-slight but useful variations, given to him by the hand of Nature. But
-Natural Selection, as we shall hereafter see, is a power incessantly
-ready for action, and is as immeasurably superior to man’s feeble
-efforts, as the works of Nature are to those of Art.”
-
-Darwin gives the following explicit statement of the way in which he
-intends the term “struggle for existence” to be understood: “I should
-premise that I use this term in a large and metaphorical sense,
-including dependence of one being on another, and including (which is
-more important) not only the life of the individual, but success in
-leaving progeny. Two canine animals, in time of dearth, may be truly
-said to struggle with each other which shall get food and live. But a
-plant on the edge of a desert is said to struggle for life against the
-drought, though more properly it should be said to be dependent on the
-moisture. A plant which actually produces a thousand seeds of which only
-one on an average comes to maturity may be more truly said to struggle
-with the plants of the same and other kinds which already clothe the
-ground. The mistletoe is dependent on the apple, and a few other trees,
-but can only in a far-fetched sense be said to struggle with these
-trees, for if too many of these parasites grow on the same tree, it
-languishes and dies. But several seedling mistletoes, growing close
-together on the same branch, may more truly be said to struggle with
-each other. As the mistletoe is disseminated by birds, its existence
-depends on them, and it may metaphorically be said to struggle with
-other fruit-bearing plants, in tempting the birds to devour and thus
-disseminate its seeds. In these several senses, which pass into each
-other, I use for convenience’ sake the general term ‘Struggle for
-Existence.’”
-
-A number of writers have objected to the general and often vague way in
-which Darwin makes use of this phrase; but it does not seem to me that
-this is a serious objection, provided we are on our guard as to what the
-outcome will be in each case. In each instance we must consider the
-question on its own merits, and if it is found convenient to have a
-sufficiently general and non-committal term, such as the “struggle for
-existence,” to include all cases, I see no serious objection to the use
-of such an expression, although it is true the outcome has been that it
-has become a catchword, that is used too often by those who have no
-knowledge of its contents.
-
-Were it not that each animal and plant gives birth, on an average, to
-more than two offspring, the species would soon become exterminated by
-accidents, etc. We find in some of the lower animals, and in some of the
-higher plants, that thousands and even millions of eggs are produced by
-a single individual in the course of its life. A single nematode may lay
-sixty million eggs, and a tapeworm one thousand million. A starfish may
-produce about thirty-nine million eggs, a salmon may contain fifteen
-thousand, and a large shad as many as one hundred thousand. The queen of
-a termite nest is said to lay eighty thousand eggs a day.
-
-In the higher vertebrates the number of young is considerably less, but
-since the young stages are passed within the body of the parent,
-proportionately more of them reach maturity, so that even in man the
-population may be doubled in twenty-five years, and in the elephant,
-slowest breeder of all animals, Darwin has calculated that, if it begins
-breeding when about thirty years old and goes on until ninety years,
-bringing forth six young in the interval, after 750 years there will be
-nearly nineteen million elephants alive which have descended from the
-first pair.
-
-Obviously, then, if all the descendants of all the individuals of a
-species were to remain alive, the world would be over-crowded in a very
-short time, and the want of room would in itself lead to the destruction
-of countless individuals, if for no other reason than lack of food. We
-can easily carry out on a small scale an experiment that shows how the
-overstocking, resulting from favorable conditions, comes about, and how
-it checks itself. If we make a meat broth suitable for the life of a
-particular bacterium, and sow in the broth a very few individuals, we
-find in the course of several days the fluid swarming with the
-descendants of the original individuals. Thus it has been shown that, if
-we start with a few hundred bacteria, there will be five thousand after
-twenty-four hours, and twenty thousand, forty-eight hours later; and
-after four days they are beyond calculation.
-
-Cohn found that a single bacterium produces two individuals in one hour,
-and four in two hours, and if they continue to multiply at this rate
-there will be produced at the end of three days 4,772 billions of
-descendants. If these are reduced to weight, they would weigh
-seventy-five hundred tons. Thus when the conditions are favorable,
-bacteria are able to increase at such an enormous rate that they could
-cover the surface of the earth in a very few days. The reason that they
-do not go on increasing at this rate is that they soon exhaust the food
-supply, and the rate of increase slows down, and will finally cease
-altogether. If the bacteria were dependent on a continuous supply of
-food, they would perish after the supply had been exhausted, so that the
-rapid rate of multiplication would serve only to bring the career of the
-organism to an untimely end. If the weaker individuals were to die
-first, the products of their disintegration might serve to nourish the
-stronger individuals; hunger coming on again, the next weakest might
-die; and the same process continuing, we might imagine that the bacteria
-were finally reduced to a single one which would then die in turn for
-lack of food. Like a starving shipload of men, reduced by hunger to
-cannibalism, the life of some and finally of the last individual might
-be prolonged in the hope of rescue, but if this did not arrive, the last
-and perhaps the strongest individual would perish. But this is not what
-we find occurring in these lower organisms, for, as a rule, they
-gradually cease to increase when the food supply becomes lessened, and
-their activities slow down. Finally, when the food is gone, they pass
-into a resting stage, in which condition they can remain dormant for a
-long time, even for years. If they should again find themselves in
-favorable surroundings, they become active, and begin once more their
-round of multiplication. We cannot follow the individuals in such a
-culture of bacteria, but there is nothing to be seen that suggests a
-struggle for existence, if this idea conveys the impression of the
-destruction of certain individuals by competition with others. In fact,
-the results are in some respects exactly the reverse. Millions of
-individuals are present at the time when the food supply becomes
-exhausted, and they all pass into a protected resting stage.
-
-The enormous rate of increase in this case finds its counterpart in
-higher animals when the food supply, or the absence of enemies, allows a
-species to multiply at its maximum rate of increase. The introduction of
-rabbits into Australia was followed by an enormous increase in a few
-years, and the introduction of the English sparrow into the United
-States has had a similar result. But in no country can such a process
-continue beyond a certain point, because, in the first place, the
-scarcity of food will begin to keep the birth-rate down, and in the
-second place, the increase in numbers may lead to an increase in the
-number of its enemies, or even induce other forms to feed on it.
-Crowding will also give an opportunity for the spread of disease, which
-again may check the increase. Sooner or later a sort of ever shifting
-balance will be reached for each species, and after this, if the
-conditions remain the same, the number of individuals will keep
-approximately constant.
-
-Darwin admits that the “causes which check the natural tendency of each
-species to increase are most obscure.” “We know not exactly what the
-checks are even in a single instance.” This admission may well put us on
-our guard against a too ready acceptation of a theory in which the whole
-issue turns on just this very point, namely, the nature of the checks to
-increase. Darwin gives the following general cases to show what some of
-the checks to increase are. He states that eggs and very young animals
-and seeds suffer more than the adults; that “the amount of food for each
-species of course gives the extreme limit to which each can increase;
-but very frequently it is not the obtaining food, but the serving as
-prey to other animals which determines the average numbers of a species.
-Thus, there seems to be little doubt that the stock of partridges,
-grouse, and hares on any large estate depends largely on the destruction
-of the vermin.” “On the other hand, in some cases, as with the elephant,
-none are destroyed by beasts of prey; for even the tiger in India most
-rarely dares to attack a young elephant protected by its dam.” “Climate
-plays an important part in determining the average number of a species,
-and periodical seasons of extreme cold or drought seem to be the most
-effective of all checks.” “The action of climate seems at first sight to
-be quite independent of the struggle for existence; but in so far as
-climate acts in reducing food, it brings on the most severe struggle
-between the individuals, whether of the same, or of distinct species
-which subsist on the same kind of food.”
-
-We need not follow Darwin through his account of how complex are the
-relations of all animals and plants to one another in the struggle for
-existence, for, if true, it only goes to show more plainly how
-impossible it is to establish any safe scientific hypothesis, where the
-conditions are so complex and so impossible to estimate. To show that
-the young Scotch fir in an enclosed pasture is kept down by the browsing
-of the cattle, and in other parts of the world, Paraguay for instance,
-the number of cattle is determined by insects, and that the increase of
-these flies is _probably_ habitually checked by other insects, leads to
-a bewilderingly complex set of conditions. We cannot do better than to
-quote Darwin’s conclusion: “Hence, if certain insectivorous birds were
-to decrease in Paraguay, the parasitic insects would probably increase;
-and this would lessen the number of the navel-frequenting flies—then
-cattle and horses would become feral, and this would certainly greatly
-alter (as indeed I have observed in parts of South America) the
-vegetation: this again would largely affect the insects; and this, as we
-have just seen in Staffordshire, the insectivorous birds, and so onwards
-in ever increasing circles of complexity. Not that under nature the
-relations will ever be as simple as this. Battle within battle must be
-continually recurring with varying success; and yet in the long run the
-forces are so nicely balanced, that the face of nature remains for long
-periods of time uniform, though assuredly the merest trifle would give
-the victory to one organic being over another. Nevertheless, so profound
-is our ignorance, and so high our presumption, that we marvel when we
-hear of the extinction of an organic being; and as we do not see the
-cause, we invoke cataclysms to desolate the world, or invent laws on the
-duration of the forms of life!”
-
-The effect of the struggle for existence in determining _the
-distribution of species_ is well illustrated in the following cases:—
-
-“As the species of the same genus usually have, though by no means
-invariably, much similarity in habits and constitution, and always in
-structure, the struggle will generally be more severe between them, if
-they come into competition with each other, than between the species of
-distinct genera. We see this in the recent extension over parts of the
-United States of one species of swallow having caused the decrease of
-another species. The recent increase of the missel-thrush in parts of
-Scotland has caused the decrease of the song-thrush. How frequently we
-hear of one species of rat taking the place of another species under the
-most different climates! In Russia the small Asiatic cockroach has
-everywhere driven before it its great congener. In Australia the
-imported hive-bee is rapidly exterminating the small, stingless native
-bee. One species of charlock has been known to supplant another species;
-and so in other cases. We can dimly see why the competition should be
-most severe between allied forms, which fill nearly the same place in
-the economy of nature; but probably in no one case could we precisely
-say why one species has been victorious over another in the great battle
-of life.”
-
-All this goes to show, if it really shows anything at all, that the
-distribution of a species is determined, in part, by its relation to
-other animals and plants—a truism that is recognized by every
-naturalist. The statement has no necessary bearing on the origin of new
-species through competition, as the incautious reader might infer. Not
-that I mean in any way to imply that Darwin intended to produce this
-effect on the reader; but Darwin is not always careful to discriminate
-as to the full bearing of the interesting illustrations with which his
-book so richly abounds.
-
-At the end of his treatment of the subject, Darwin emphasizes once more
-how little we know about the subject of the struggle for existence.
-
-“It is good thus to try in imagination to give to any one species an
-advantage over another. Probably in no single instance should we know
-what to do. This ought to convince us of our ignorance on the mutual
-relations of all organic beings; a conviction as necessary, as it is
-difficult, to acquire. All that we can do, is to keep steadily in mind
-that each organic being is striving to increase in a geometrical ratio;
-that each at some period of its life, during some season of the year,
-during each generation or at intervals, has to struggle for life and to
-suffer great destruction. When we reflect on this struggle, we may
-console ourselves with the full belief, that the war of nature is not
-incessant, that no fear is felt, that death is generally prompt, and
-that the vigorous, the healthy, and the happy survive and multiply.”
-
-The kindliness of heart that prompted the concluding sentence may arouse
-our admiration for the humanity of the writer, but need not, therefore,
-dull our criticism of his theory. For whether no fear is felt, and
-whether death is prompt or slow, has no bearing on the question at
-issue—except as it prepares the gentle reader to accept the dreadful
-calamity of nature, pictured in this battle for existence, and make more
-contented with their lot “the vigorous, the healthy, and the happy.”
-
-
-                    The Theory of Natural Selection
-
-We have already anticipated, to some extent, Darwin’s conclusion in
-regard to the outcome of the competition of animals and plants. This
-result is supposed to lead to the survival of the fittest. The
-competition is carried out by nature, who is personified as selecting
-those forms for further experiments that have won in the struggle for
-existence.
-
-“Can the principle of selection, which we have seen is so potent in the
-hands of man, apply under Nature? I think we shall see that it can act
-most efficiently. Let the endless number of slight variations and
-individual differences occurring in our domestic productions, and, in a
-lesser degree, in those under Nature, be borne in mind; as well as the
-strength of the hereditary tendency. Can it, then, be thought
-improbable, seeing that variations useful to man have undoubtedly
-occurred, that other variations useful in some way to each being in the
-great and complex battle for life, should occur in the course of many
-successive generations? If such do occur can we doubt (remembering how
-many more individuals are born than can possibly survive) that
-individuals having any advantage, however slight, over others, would
-have the best chance of surviving and of procreating their kind? On the
-other hand, we may feel sure that any variation in the least degree
-injurious would be rigidly destroyed.”
-
-The process of natural selection is defined as follows, “The
-preservation of favorable individual differences and variations and the
-destruction of those that are injurious I have called Natural Selection
-or the Survival of the Fittest.” And immediately there follows the
-significant statement, that, “Variations neither useful nor injurious
-would not be affected by natural selection, and would be left either a
-fluctuating element, as perhaps we see in certain polymorphic species,
-or would ultimately become fixed, owing to the nature of the organism
-and the nature of the conditions.” It will be seen from this quotation,
-as well as from others already given, that Darwin leaves many structures
-outside of the pale of natural selection, and uses his theory to explain
-only those cases that are of sufficient use to be decisive in the life
-and death struggle of the individuals with each other and with the
-surrounding conditions.
-
-Darwin states that we can best understand “the probable course of
-natural selection by taking the case of a country undergoing some slight
-physical change, for instance, of climate. The proportional numbers of
-its inhabitants will almost immediately undergo a change, and some
-species will probably become extinct. We may conclude, from what we have
-seen of the intimate and complex manner in which the inhabitants of each
-country are bound together, that any change in the numerical proportions
-of the inhabitants, independency of the change of climate itself, would
-seriously affect the others.... In such cases, slight modifications,
-which in any way favored the individuals of any species, by better
-adapting them to their altered conditions, would tend to be preserved;
-and natural selection would have free scope for the work of
-improvement.”
-
-The first half of the first of these two quotations seems so plausible,
-that without further thought we may be tempted to give a ready assent to
-the second, yet the whole issue is contained in this statement. In the
-abstract, it undoubtedly appears true that any slightly useful
-modification might tend to be preserved. Whether it will, in reality, be
-preserved must depend on many things that should be taken into account.
-This question will come up later for further consideration; but it
-should be pointed out here, that, even assuming that one or more
-individuals happen to possess a favorable variation, it by no means
-follows that natural selection would have free scope for the work of
-improvement, because the question of the inheritance of this variation,
-and of its accumulation and building up through successive generations,
-must be determined before we can be expected to give assent to this
-argument, that appears so attractive when stated in an abstract and
-vague way.
-
-Darwin again makes the statement that under the term _variation_ it must
-never be forgotten that mere individual differences are meant. “As a man
-can produce a great result with his domestic animals and plants by
-adding up in any given direction individual differences, so could
-natural selection, but far more easily from having incomparably longer
-time for action.” Too much emphasis cannot be laid on the fact that
-Darwin believed that selection takes place amongst the small individual
-differences that we find in animals and plants. Some of his followers,
-as we shall see, are apt to put into the background this fundamental
-conception of Darwin’s view. His constant comparison between the results
-of artificial and natural selection leaves no room for doubt as to his
-meaning. Darwin himself seems, at times, not unconscious of the weakness
-of this comparison. He says: “How fleeting are the wishes and efforts of
-man! how short his time! and consequently how poor will be his results,
-compared with those accumulated by Nature during whole geological
-periods. Can we wonder then that Nature’s productions should be far
-‘truer’ in character than man’s productions; that they should be
-infinitely better adapted to the most complex conditions of life, and
-should plainly bear the stamp of far higher workmanship?” We should not
-lose sight of the fact that even after the most rigorous selective
-process has been brought to bear on organisms, namely, by isolation
-under domestication, we do not apparently find ourselves gradually
-approaching nearer and nearer to the formation of new species, but we
-find, on the contrary, that we have produced something quite different.
-In the light of this truth, the relation between the two selective
-theories may appear quite different from the interpretation that Darwin
-gives of it. We may well doubt whether nature does select so much better
-than does man, and whether she has ever _made_ new species in this way.
-
-We come now to a point that touches the theory of natural selection in a
-very vital spot.
-
-“It may be well here to remark that with all beings there must be much
-fortuitous destruction, which can have little or no influence on the
-course of natural selection. For instance, a vast number of eggs or
-seeds are annually devoured, and these could be modified through natural
-selection only if they varied in some manner which protected them from
-their enemies. Yet many of these eggs or seeds would perhaps, if not
-destroyed, have yielded individuals better adapted to their conditions
-of life than any of those which happened to survive. So again a vast
-number of mature animals and plants, whether or not they be the best
-adapted to their conditions, must be annually destroyed by accidental
-causes, which would not be in the least degree mitigated by certain
-changes of structure or constitution which would in other ways be
-beneficial to the species. But let the destruction of the adults be ever
-so heavy, if the number which can exist in any district be not wholly
-kept down by such causes,—or again let the destruction of eggs or seeds
-be so great that only a hundredth or a thousandth part are
-developed,—yet of those which do survive, the best adapted individuals,
-supposing that there is any variability in a favorable direction, will
-tend to propagate their kind in larger numbers than the less well
-adapted. If the numbers be wholly kept down by the causes just
-indicated, as will often have been the case, natural selection will be
-powerless in certain beneficial directions; but this is no valid
-objection to its efficiency at other times and in other ways; for we are
-far from having any reason to suppose that many species ever undergo
-modification and improvement at the same time in the same area.”
-
-Some of the admissions made in this paragraph have an important bearing
-on the theory of natural selection. Far from supposing that fortuitous
-destruction would have no influence on the course of natural selection,
-it can be shown that it would have a most disastrous effect. In many
-cases the destruction comes in the form of a catastrophe to the
-individuals, so that small differences in structure, whether
-advantageous or not, are utterly unavailing. Our experience shows us
-that a destruction of this sort is going on around us all the time, and
-accounts in large part for the way in which the majority of animals and
-plants are destroyed. Unless, for example, a seed happen to fall on a
-place suitable for its growth, it will perish without respect to a
-slight advantage it may have over other seeds of its kind. Of the
-thousands of eggs laid by one starfish, chance alone will decide whether
-one or another embryo is destroyed by larger animals, or if they escape
-this danger, the majority of them may be carried out to sea, where it
-will not be of the least avail if one individual has a slight advantage
-over the others. Darwin admits this, but adds that, if only a thousandth
-part is developed, yet of those that do survive the best adapted
-individuals will tend to propagate their kind in larger numbers than the
-less well adapted. The argument is not, however, so simple as it appears
-to be on the surface. I pass over, for the present, the apparent
-inconsequence in this statement that the best adapted individuals will
-tend to propagate their kind in larger numbers. It is not by any means
-certain that this is the case. Darwin’s meaning is, however, fairly
-clear, and can be interpreted to mean this: after the fortuitous
-destruction has finished, there will be a further competition of the
-survivors amongst themselves and with the surrounding conditions. In
-this higher competition, which is less severe, small individual
-differences suffice to determine the survival of certain individuals.
-These are, therefore, selected.
-
-In this argument it is assumed that a second competition takes place
-after the first destruction of individuals has occurred, and this
-presupposes that more individuals reach maturity than there is room for
-in the economy of nature. But we do not know to what extent this takes
-place. If only as many mature as can survive, then the second
-competition does not take place. If, on the other hand, fewer mature
-than there is room for, then again competition does not take place. And
-if at all times selection is not rigorously carried out, everything may
-be lost that has been so laboriously gained. We see then that the result
-that Darwin imagines would take place, can be carried out only when more
-individuals reach maturity than there is room for (if it is a case of
-competition with one another), or that escape their enemies (if it is a
-question of competition with other forms).
-
-It is instructive to consider some of the examples that Darwin has given
-to illustrate how the process of natural selection is carried out. The
-first example is the imaginary case of a species of wolf, the
-individuals of which secure their prey sometimes by craft, sometimes by
-strength, and sometimes by fleetness. If the prey captured by the first
-two methods should fail, then all the wolves would be obliged to capture
-their food by fleetness, and consequently the fleetest alone would
-survive. “I can see no more reason to doubt that this would be the
-result than that man should improve the fleetness of his greyhounds.”
-But even if the fleetness of the race could be kept up in this way, it
-does not follow that a new species of wolf would be formed in
-consequence, as Darwin implies. His own comment on this illustration is,
-perhaps, the best criticism that can be made.
-
-“It should be observed that, in the above illustration, I speak of the
-slimmest individual wolves, and not of any single strongly marked
-variation having been preserved. In former editions of this work I
-sometimes spoke as if this latter alternative had frequently occurred. I
-saw the great importance of individual differences, and this led me
-fully to discuss the results of unconscious selection by man, which
-depends on the preservation of all the more or less valuable
-individuals, and on the destruction of the worst. I saw, also, that the
-preservation in a state of nature of any occasional deviation of
-structure, such as a monstrosity, would be a rare event; and that, if at
-first preserved, it would generally be lost by subsequent intercrossing
-with ordinary individuals. Nevertheless, until reading an able and
-valuable article in the _North British Review_ (1867), I did not
-appreciate how rarely single variations, whether slight or strongly
-marked, could be perpetuated. The author takes the case of a pair of
-animals, producing during their lifetime two hundred offspring, of
-which, from various causes of destruction, only two on an average
-survive to procreate their kind. This is rather an extreme estimate for
-most of the higher animals, but by no means so for many of the lower
-organisms. He then shows that if a single individual were born, which
-varied in some manner, giving it twice as good a chance of life as that
-of the other individuals, yet the chances would be strongly against its
-survival. Supposing it to survive and to breed, and that half its young
-inherited the favourable variation; still, as the reviewer goes on to
-show, the young would have only a slightly better chance of surviving
-and breeding; and this chance would go on decreasing in the succeeding
-generations. The justice of these remarks cannot, I think, be disputed.
-If, for instance, a bird of some kind could procure its food more easily
-by having its beak curved, and if one were born with its beak strongly
-curved, and which consequently flourished, nevertheless there would be a
-very poor chance of this one individual perpetuating its kind to the
-exclusion of the common form; but there can hardly be a doubt, judging
-by what we see taking place under domestication, that this result would
-follow from the preservation during many generations of a large number
-of individuals with more or less strongly curved beaks, and from the
-destruction of a still larger number with the straightest beaks.”
-
-There then follows what, I believe, is one of the most significant
-admissions in the “Origin of Species”:—
-
-“It should not, however, be overlooked that certain rather strongly
-marked variations, which no one would rank as mere individual
-differences, frequently recur owing to a similar organization being
-similarly acted on—of which fact numerous instances could be given with
-our domestic productions. In such cases, if the varying individual did
-not actually transmit to its offspring its newly acquired character, it
-would undoubtedly transmit to them, as long as the existing conditions
-remained the same, a still stronger tendency to vary in the same manner.
-There can also be little doubt that the tendency to vary in the same
-manner has often been so strong that all the individuals of the same
-species have been similarly modified without the aid of any form of
-selection. Or only a third, fifth, or tenth part of the individuals may
-have been thus affected, of which fact several instances could be given.
-Thus Graba estimates that about one-fifth of the guillemots in the Faroe
-Islands consist of a variety so well marked, that it was formerly ranked
-as a distinct species under the name of _Uria lacrymans_. In cases of
-this kind, if the variation were of a beneficial nature, the original
-form would soon be supplanted by the modified form, through the survival
-of the fittest.”
-
-Do not the admissions in this paragraph almost amount to a withdrawal of
-much that has preceded in regard to the survival of fluctuating,
-individual differences? In the last edition, from which we have just
-quoted, Darwin, in response to the criticisms which his book met,
-inserted here and there statements that are in many ways in
-contradiction to the statements in the first edition, and yet the
-earlier statements have been allowed to stand for the most part.
-
-The next example is also worthy of careful examination, since it appears
-to prove too much:—
-
-“It may be worth while to give another and more complex illustration of
-the action of natural selection. Certain plants excrete sweet juice,
-apparently for the sake of eliminating something injurious from the sap:
-this is effected, for instance, by glands at the base of the stipules in
-some Leguminosæ, and at the backs of the leaves of the common laurel.
-This juice, though small in quantity, is greedily sought by insects; but
-their visits do not in any way benefit the plant. Now, let us suppose
-that the juice or nectar was excreted from the inside of the flowers of
-a certain number of plants of any species. Insects in seeking the nectar
-would get dusted with pollen, and would often transport it from one
-flower to another. The flowers of two distinct individuals of the same
-species would thus get crossed; the act of crossing, as can be fully
-proved, gives rise to vigorous seedlings, which consequently would have
-the best chance of flourishing and surviving. The plants which produced
-flowers with the largest glands or nectaries, excreting most nectar,
-would oftenest be visited by insects, and would oftenest be crossed; and
-so in the long run would gain the upper hand and form a local variety.”
-
-The reader will notice that the sweet juice or nectar secreted by
-certain plants is supposed to have first appeared independently of the
-action of natural selection. Why then account for its presence in
-flowers as the outcome of an entirely different process? If the nectar
-is eagerly sought for by insects, without the plant benefiting in any
-way by their visitations, why give a different explanation of its origin
-in flowers where it is of benefit to the plant?
-
-Darwin carries his illustration further: “When our plant, by the above
-process long continued, had been rendered highly attractive to insects,
-they would unintentionally, on their part, regularly carry pollen from
-flower to flower; and that they do this effectually, I could easily show
-by many striking facts. I will give only one, as likewise illustrating
-one step in the separation of the sexes of plants.... As soon as the
-plant had been rendered so highly attractive to insects that pollen was
-regularly carried from flower to flower, another process might commence.
-No naturalist doubts the advantage of what has been called the
-‘physiological division of labour’; hence we may believe that it would
-be advantageous to a plant to produce stamens alone in one flower or on
-one whole plant, and pistils alone in another flower or on another
-plant. In plants under culture and placed under new conditions of life,
-sometimes the male organs and sometimes the female organs become more or
-less impotent; now if we suppose this to occur in ever so slight a
-degree under nature, then, as pollen is already carried regularly from
-flower to flower, and as a more complete separation of the sexes of our
-plant would be advantageous on the principle of the division of labour,
-individuals with this tendency more and more increased would be
-continually favoured or selected, until at last a complete separation of
-the sexes might be effected. It would take up too much space to show the
-various steps, through dimorphism and other means, by which the
-separation of the sexes in plants of various kinds is apparently now in
-progress; but I may add that some of the species of holly in North
-America are, according to Asa Gray, in an exactly intermediate
-condition, or, as he expresses it, are more or less diœciously
-polygamous.”
-
-From this it will be seen that Darwin supposes that the separation of
-the sexes in some of the higher plants has been brought about by natural
-selection. Despite the supposed advantage of the so-called “division of
-labor,” one may, I venture to suggest, be sceptical as to whether the
-separation of the sexes can be explained in this way. The whole case is
-largely supposititious, since in most of the higher hermaphroditic
-plants and in nearly all hermaphroditic animals the sexual products
-ripen at different times in the same individual. Hence there is no basis
-for the assumption that unless the sexes are separated there will be
-self-fertilization. Shall we assume that this difference in time of
-ripening of the two kinds of sex-cells is also the outcome of natural
-selection, and that there has existed an earlier stage in all animals
-and plants, that now have different times for the ripening of their
-sexual elements, a time when these products ripened simultaneously? I
-doubt if even a Darwinian would give such loose rein to his fancy.
-
-But this is not yet the whole story that Darwin has made out in this
-connection, for he continues:—
-
-“Let us now turn to the nectar-feeding insects; we may suppose the
-plant, of which we have been slowly increasing the nectar by continued
-selection, to be a common plant; and that certain insects depended in
-main part on its nectar for food. I could give many facts showing how
-anxious bees are to save time: for instance, their habit of cutting
-holes and sucking the nectar at the bases of certain flowers, which with
-a very little more trouble, they can enter by the mouth. Bearing such
-facts in mind, it may be believed that under certain circumstances
-individual differences in the curvature or length of the proboscis,
-etc., too slight to be appreciated by us, might profit a bee or other
-insect, so that certain individuals would be able to obtain their food
-more quickly than others; and thus the communities to which they
-belonged would flourish and throw off many swarms inheriting the same
-peculiarities.”
-
-Aside from the general criticism that will suggest itself here also, it
-should be pointed out that even if “certain individuals” of the bees had
-slightly longer proboscides, this would, in the case of the hive-bees at
-least, be of no avail, since they do not reproduce, and hence leave no
-descendants with longer mouth-parts. Of course, it may be replied that
-those colonies in which the queens produce more of the long-proboscis
-kind of worker would have an advantage over other colonies not having so
-many individuals of this sort. It would then be a competition of one
-colony with another, as Darwin supposes to take place in colonial forms.
-But whether slight differences of this sort would lead to the
-elimination of the least well-endowed colonies is entirely a matter of
-speculation. Since there are flowers with corolla-tubes of all lengths,
-we can readily suppose that if one kind of flower excluded individuals
-of certain colonies, they would search elsewhere for their nectar rather
-than perish. While different races might arise in this way, the process
-would not be the survival of the fittest, but a process of adaptation to
-a new environment.
-
-We come now to a topic on which Darwin lays much stress: the divergence
-of character. He tries to show how the “lesser differences between the
-varieties become augmented into the greater differences between
-species.”
-
-“Mere chance, as we may call it, might cause one variety to differ in
-some character from its parents, and the offspring of this variety again
-to differ from its parent in the very same character and in a greater
-degree; but this alone would never account for so habitual and large a
-degree of difference as that between the species of the same genus. As
-has always been my practice, I have sought light on this head from our
-domestic productions.”
-
-Then, after pointing out that under domestication two different races,
-the race-horse and the dray-horse, for instance, might arise by
-selecting different sorts of variations, Darwin inquires:—
-
-“But how, it may be asked, can any analogous principle apply in nature?
-I believe it can and does apply most efficiently (though it was a long
-time before I saw how), from the simple circumstance that the more
-diversified the descendants from any one species become in structure,
-constitution, and habits, by so much will they be better enabled to
-seize on many and widely diversified places in the polity of nature, and
-so be enabled to increase in numbers.”
-
-Here we touch on one of the fundamental principles of the doctrine of
-evolution. It is intimated that the new form of animal or plant first
-appears (without regard to any kind of selection), and then finds that
-place in nature where it can remain in existence and propagate its kind.
-Darwin refers here, of course, only to the less extensive variations,
-the individual or fluctuating kind; but as we shall discuss at greater
-length in another place, this same process, if extended to other kinds
-of variation, may give us an explanation of evolution without
-competition, or selection, or destruction of the individuals of the same
-kind taking place at all.
-
-
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-
-
-
-
-                               CHAPTER V
-
-             THE THEORY OF NATURAL SELECTION (_Continued_)
-
-             Objections to the Theory of Natural Selection
-
-
-Although in the preceding chapter a number of criticisms have been made
-of the special parts of the theory of natural selection, there still
-remain to be considered some further objections that have been made
-since the first publication of the theory. It is a fortunate
-circumstance from every point of view that Darwin himself was able in
-the later editions of the “Origin of Species” to reply to those
-criticisms that he thought of sufficient importance. He says:—
-
-“Long before the reader has arrived at this part of my work, a crowd of
-difficulties will have occurred to him. Some of them are so serious that
-to this day I can hardly reflect on them without being in some degree
-staggered; but, to the best of my judgment, the greater number are only
-apparent, and those that are real are not, I think, fatal to the
-theory.”
-
-The first difficulty is this: “Why, if species have descended from other
-species by fine gradations, do we not everywhere see innumerable
-transitional forms? Why is not all nature in confusion, instead of the
-species being, as we see them, well defined?”
-
-The answer that Darwin gives is, that by competition the new form will
-crowd out its own less-improved parent form, and other less-favored
-forms. But is this a sufficient or satisfactory answer? If we recall
-what Darwin has said on the advantage that those forms will have, in
-which a great number of new variations appear to fit them to the great
-diversity of natural conditions, and if we recall the gradations that
-exist in external conditions, I think we shall find that Darwin’s reply
-fails to give a satisfactory answer to the question.
-
-It is well known, and Darwin himself has commented on it, that the same
-species often remains constant under very diverse external conditions,
-both inorganic and organic. Hence I think the explanation fails, in so
-far as it is based on the accumulation by selection of small individual
-variations that are supposed to give the individuals some slight
-advantage under each set of external conditions. Darwin admits that
-“this difficulty for a long time quite confounded me. But I think it can
-be in large part explained.” The first explanation that is offered is
-that areas now continuous may not have been so in the past. This may be
-true in places, but the great continents have had continuous areas for a
-long time, and Darwin frankly acknowledges that he “will pass over this
-way of explaining the difficulty.” The second attempt is based on the
-supposed narrowness of the area, where two species, descended from a
-common parent, overlap. In this region the change is often very abrupt,
-and Darwin adds:—
-
-“To those who look at climate and the physical conditions of life as the
-all-important elements of distribution, these facts ought to cause
-surprise, as climate and height or depth graduate away insensibly. But
-when we bear in mind that almost every species, even in its metropolis,
-would increase immensely in numbers, were it not for other competing
-species; that nearly all either prey on or serve as prey for others; in
-short, that each organic being is either directly or indirectly related
-in the most important manner to other organic beings,—we see that the
-range of the inhabitants of any country by no means exclusively depends
-on insensibly changing physical conditions, but in a large part on the
-presence of other species, on which it lives, or by which it is
-destroyed, or with which it comes into competition; and as these species
-are already defined objects, not blending one into another by insensible
-gradations, the range of any one species, depending as it does on the
-range of others, will tend to be sharply defined.”
-
-Here we have a _petitio principii_. The sharp definition of species,
-that we started out to account for, is explained by the sharp definition
-of other species!
-
-A third part of the explanation is that, owing to the relative fewness
-of individuals at the confines of the range during the fluctuations of
-their enemies, or of their prey, or in the nature of the seasons, they
-would be extremely liable to utter extermination. If this were really
-the case, then new species themselves which, on the theory, are at first
-few in numbers ought to be exterminated. On the whole, then, it does not
-appear that Darwin has been very successful in his attempt to meet this
-objection to the theory.
-
-Darwin tries to meet the objection, that organs of extreme perfection
-and complication cannot be accounted for by natural selection, as
-follows:—
-
-“To suppose that the eye with all its inimitable contrivances for
-adjusting the focus to different distances, for admitting different
-amounts of light, and for the correction of spherical and chromatic
-aberration, could have been formed by natural selection, seems, I freely
-confess, absurd in the highest degree.”
-
-The following sketch that Darwin gives to show how he imagined the
-vertebrate eye to have been formed is very instructive, as illustrating
-how he supposed that natural selection acts:—
-
-“If we must compare the eye to an optical instrument, we ought in
-imagination to take a thick layer of transparent tissue, with spaces
-filled with fluid, and with a nerve sensitive to light beneath, and then
-suppose every part of this layer to be continually changing slowly in
-density, so as to separate into layers of different densities and
-thicknesses, placed at different distances from each other, and with the
-surfaces of each layer slowly changing in form. Further we must suppose
-that there is a power, represented by natural selection or the survival
-of the fittest, always intently watching each slight alteration in the
-transparent layers; and carefully preserving each which, under varied
-circumstances, in any way or in any degree, tends to produce a
-distincter image. We must suppose each new state of the instrument to be
-multiplied by the million; each to be preserved until a better one is
-produced, and then the old ones to be all destroyed. In living bodies,
-variation will cause the slight alterations, generation will multiply
-them almost infinitely, and natural selection will pick out with
-unerring skill each improvement. Let this process go on for millions of
-years; and during each year on millions of individuals of many kinds;
-and may we not believe that a living optical instrument might thus be
-formed as superior to one of glass, as the works of the Creator are to
-those of man.”
-
-We may conclude in Darwin’s own words:—
-
-“To arrive, however, at a just conclusion regarding the formation of the
-eye, with all its marvellous yet not absolutely perfect characters, it
-is indispensable that the reason should conquer the imagination; but I
-have felt the difficulty far too keenly to be surprised at others
-hesitating to extend the principle of natural selection to so startling
-a length.”
-
-The electric organs, present in several fish, offer a case of special
-difficulty to the selection theory. When well developed, as in the
-Torpedo and in Gymnotus, it is conceivable that it may serve as an organ
-of defence, but in other forms the shock is so weak that it is not to be
-supposed that it can have any such function. Romanes, who in many ways
-was one of the stanchest followers of Darwin, admits that, so far as he
-can see, the evolution of the electric organs cannot be explained by the
-selection theory. Darwin offers no explanation, but bases his defence on
-the grounds that we do not know of what use this organ can be to the
-animal.
-
-Darwin also refers to the phosphorescent, or luminous, organs as a
-supposed case of difficulty for his theory.
-
-“The luminous organs which occur in a few insects, belonging to widely
-different families, and which are situated in different parts of the
-body, offer, under our present state of ignorance, a difficulty almost
-exactly parallel with that of the electric organs.”
-
-In this case also, as in that of the electric organs, the structures
-appear in entirely different parts of the body of the insect in
-different species, so that their occurrence in this group cannot be
-accounted for on a common descent. In whatever way they have arisen,
-they must have evolved independently in different species. Darwin
-advances no explanation of the origin of the luminous organs, but states
-that they “offer under our present state of ignorance a difficulty
-almost exactly parallel with that of the electric organs.” It will be
-noticed that the difficulty referred to rests on the assumption that
-since the organs are well developed they must have some important use!
-
-We may next consider “organs of little apparent importance as affected
-by natural selection.” Darwin says:—
-
-“As natural selection acts by life and death,—by the survival of the
-fittest, and by the destruction of the less well-fitted individuals,—I
-have sometimes felt great difficulty in understanding the origin or
-formation of parts of little importance; almost as great, though of a
-very different kind, as in the case of the most perfect and complex
-organs.”
-
-His answers to this difficulty are: (1) we are too ignorant “in regard
-to the whole economy of any one organic being to say what slight
-modifications would be of importance or not,”—thus such apparently
-trifling characters as the down on fruit, or the colors of the skin and
-hair of quadrupeds, which from being correlated with constitutional
-differences or from determining the attacks of insects might be acted on
-by natural selection; (2) organs now of trifling importance have in some
-cases been of high importance to an early progenitor; (3) the changed
-conditions of life may account for some of the useless organs; (4)
-reversion accounts for others; (5) the complex laws of growth account
-for still others, such as correlation, compensation of the pressure of
-one part on another, etc.; (6) the action of sexual selection is
-responsible for many characters not to be explained by natural
-selection. Admitting that there may be cases that can be accounted for
-on one or the other of these six possibilities, yet there can be no
-doubt that there are still a considerable number of specific characters
-that cannot be explained in any of these ways. I do not think that
-Darwin has by any means met this objection, even if all these six
-possibilities be admitted as generally valid.
-
-Amongst the “miscellaneous objections” to his theory that Darwin
-considers we may select the most important cases. The following
-paragraph has been sometimes quoted by later writers to show that Darwin
-saw, to a certain extent, the insufficiency of fluctuating variations as
-a basis for selection. What he calls here “spontaneous variability”
-refers to sudden and extensive variations, or what we may call
-discontinuous variations. “In the earlier editions of this work I
-underrated, as it now seems probable, the frequency and importance of
-modifications due to spontaneous variability. But it is impossible to
-attribute to this cause the innumerable structures which are so well
-adapted to the habits of life of each species. I can no more believe in
-this, that the well-adapted form of a race-horse or greyhound, which
-before the principle of selection by man was well understood, excited so
-much surprise in the minds of the older naturalists, can thus be
-explained.”
-
-Darwin appears to mean by the latter part of this statement, that he
-cannot believe that such sudden and great variations as have caused a
-peach tree to produce nectarines can account for the wonderful
-adaptations of organisms; but it is not really necessary to suppose that
-this would often occur, for the same result could be reached by several
-stages, even if the discontinuous variations had been small, and had
-appeared in many individuals simultaneously. After showing that in a
-number of flowers, especially of the Compositæ and Umbelliferæ, the
-individual flowers in the closely crowded heads are sometimes formed on
-a different type, Darwin concludes: “In these several cases, with the
-exception of that of the well-developed ray-florets, which are of
-service in making the flowers conspicuous to insects, natural selection
-cannot, as far as we can judge, have come into play, or only in a quite
-subordinate manner. All these modifications follow from the relative
-position and interaction of the parts; and it can hardly be doubted that
-if all the flowers and leaves on the same plant had been subjected to
-the same external and internal condition, as are the flowers and leaves
-in certain positions, all would have been modified in the same manner.”
-
-Further on we meet with the following remarkable statement: “But when,
-from the nature of the organism and of the conditions, modifications
-have been induced which are unimportant for the welfare of the species,
-they may be, and apparently often have been, transmitted in nearly the
-same state to numerous, otherwise modified, descendants. It cannot have
-been of much importance to the greater number of mammals, birds, or
-reptiles, whether they were clothed with hair, feathers, or scales; yet
-hair has been transmitted to almost all mammals, feathers to all birds,
-and scales to all true reptiles. A structure, whatever it may be, which
-is common to many allied forms, is ranked by us as of high systematic
-importance, and consequently is often assumed to be of high vital
-importance to the species. Thus, as I am inclined to believe,
-morphological differences, which we consider as important,—such as the
-arrangement of the leaves, the divisions of the flower or of the
-ovarium, the position of the ovules, etc.,—first appeared in many cases
-as fluctuating variations, which sooner or later became constant through
-the nature of the organism and of the surrounding conditions, as well as
-through the intercrossing of distinct individuals, but not through
-natural selection; for as these morphological characters do not affect
-the welfare of the species, any slight deviations in them could not have
-been governed or accumulated through this latter agency. It is a strange
-result which we thus arrive at, namely, that characters of slight vital
-importance to the species are the most important to the systematist;
-but, as we shall hereafter see when we treat of the genetic principle of
-classification, this is by no means so paradoxical as it may at first
-appear.”
-
-If all this be granted, it is once more evident that the only variations
-that come under the action of selection are the limited number that are
-of vital importance to the organism. How little the theory of natural
-selection can be used to explain the origin of species will be apparent
-from the above quotation. This is, of course, not an argument against
-the theory itself, which would still be one of vast importance if it
-explained adaptive characters alone; but enough has been said, I think,
-to show that it is improbable that the origin of adaptive and
-non-adaptive characters are to be explained by entirely different
-principles.
-
-In reply to a criticism of Mivart, Darwin makes the further admission as
-to the insufficiency of the theory of natural selection: “When
-discussing special cases, Mr. Mivart passes over the effects of the
-increased use and disuse of parts, which I have always maintained to be
-highly important, and have treated in my ‘Variation under Domestication’
-at greater length than, as I believe, any other writer. He likewise
-often assumes that I attribute nothing to variation, independent of
-natural selection, whereas in the work just referred to I have collected
-a greater number of well-established cases than is to be found in any
-other work known to me.” If this is admitted, and if it can be shown
-that the evidence in favor of the inheritance of acquired characters is
-very doubtful at best, may we not conclude that Mivart’s criticisms have
-sometimes hit the mark?
-
-The following objection appears to be a veritable stumbling-block to the
-theory. Flatfishes and soles lie on one side, and do not stand in a
-vertical position as do other fish. Some species lie on one side and
-some on the other, and some species contain both right-sided and
-left-sided individuals. In connection with this unusual habit we find a
-striking change in the structure. The eye that would be on the under
-side has shifted, so that it has come to lie on the upper side of the
-head, _i.e._ both eyes lie on the same side,—a condition found in no
-other vertebrate. As a result of the shifting of the eye, the bones of
-the skull have also become profoundly modified. The young fish that
-emerge from the egg swim at first upright, as do ordinary fish, and only
-after they have led a free existence for some time do they turn to one
-side and sink to the bottom. Unless the under eye moved to the upper
-side it would be of no use to the flatfish, and might even be a source
-of injury. Mivart points out that a sudden, spontaneous transformation
-in the position of eye is hardly conceivable, and to this Darwin, of
-course, assents. Mivart adds: “If the transit was gradual, then how such
-transit of one eye a minute fraction of the journey towards the other
-side of the head could benefit the individual is, indeed, far from
-clear. It seems even that such an incipient transformation must rather
-have been injurious.” Darwin’s reply is characteristic:—
-
-“We thus see that the first stages of the transit of the eye from one
-side of the head to the other, which Mr. Mivart considers would be
-injurious, may be attributed to the habit, no doubt beneficial to the
-individual and to the species, of endeavoring to look upwards with both
-eyes, whilst resting on one side at the bottom. We may also attribute to
-the inherited effects of use the fact of the mouth in several kinds of
-flatfish being bent towards the lower surface, with the jaw-bones
-stronger and more effective on this, the eyeless side of the head, than
-on the other side, for the sake, as Dr. Traquair supposes, of feeding
-with ease on the ground. Disuse, on the other hand, will account for the
-less developed condition of the whole inferior half of the body,
-including the lateral fins; though Yarrell thinks that the reduced size
-of these fins is advantageous to the fish, as ‘there is so much less
-room for their action, than with the larger fins above.’ Perhaps the
-lesser number of teeth in the proportion of four to seven in the upper
-halves of the two jaws of the plaice, to twenty-five to thirty in the
-lower halves, may likewise be accounted for by disuse. From the
-colorless state of the ventral surface of most fishes and of many other
-animals, we may reasonably suppose that the absence of color in flatfish
-on the side, whether it be the right or left, which is undermost, is due
-to the exclusion of light.”
-
-By falling back on the theory of inheritance of acquired characters
-Darwin tacitly admits the incompetence of natural selection to explain
-the evolution of the flatfish. If the latter theory prove incorrect, it
-must then be admitted that the evolution of the flatfishes cannot be
-accounted for by either of the two main theories on which Darwin relies.
-
-Mivart further points out that the beginning stages of the mammary
-glands cannot be explained by Darwin’s theory. To which Darwin replies,
-that an American naturalist, Mr. Lockwood, believes from what he has
-seen of the development of the young of the pipe-fish (Hippocampus) that
-“they are nourished by a secretion from the cutaneous glands of the sac”
-in which the young are enclosed. This can scarcely be said to be a
-satisfactory reply; for, if it is true that this is the case for the
-pipe-fish,—and I cannot find on inquiry that this statement has been
-confirmed,—it is still rather speculative to suppose that the ancestral
-mammals nourished their young by secreting a fluid into the marsupial
-sac around the embryos.
-
-Darwin deals with instincts of animals in the same way as he deals with
-their structures. After pointing out that instincts are variable, and
-that the variations are hereditary, he proceeds to show how selection
-may act by picking out those individuals possessing the more favorable
-instincts. In other words, the theory of natural selection is applied to
-functions, as well as to structure. Darwin makes use here also of the
-Lamarckian factor of inheritance, and concludes that “in most cases
-habit and selection have probably both occurred.”
-
-A few examples will sufficiently serve to illustrate Darwin’s meaning.
-The first case given is that of the cuckoo, which lays its eggs in the
-nests of other birds, where they are hatched and the young reared by
-their foster-parents. The starting-point for such a perversion of the
-ordinary habits of birds is to be found, he thinks, in the occasional
-deposition of eggs in the nests of other birds, which has at times been
-observed for a number of species. For instance, this has been seen in
-the American cuckoo, which ordinarily builds a nest of its own. It is
-recorded and believed to be true that the young English cuckoo, when
-only two or three days old, ejects from the nest the offspring of its
-foster-parents, and this “strange and odious instinct” is supposed by
-Darwin to have been acquired in order that the young cuckoo might get
-more food, and that the young bird has acquired during successive
-generations the strength and structure necessary for the work of
-ejection. This is of course largely speculative, and it is by no means
-obvious that it was a greater benefit to the cuckoo to have other birds
-rear its young than to do so itself. We can equally well imagine, since
-this is the turn the argument takes, that the occasional instinct to
-deposit eggs in the nests of other birds would be disadvantageous, and
-could not have been acquired by the selection of a fluctuating instinct
-of this sort. We have no right to assume, that because a new habit has
-been acquired, that it is a more advantageous one than the one that has
-been lost. All that we can legitimately infer is, that, although the
-normal instinct has been changed into another, the race has still been
-able to remain in existence. The same conclusion applies to the case of
-_Molothrus bonariensis_, cited by Darwin, and is here even more
-obvious:—
-
-“Some species of Molothrus, a widely distinct genus of American birds,
-allied to our starlings, have parasitic habits like those of the cuckoo;
-and the species present an interesting gradation in the perfection of
-their instincts. The sexes of _Molothrus badius_ are stated by an
-excellent observer, Mr. Hudson, sometimes to live promiscuously together
-in flocks, and sometimes to pair. They either build a nest of their own,
-or seize on one belonging to some other bird, occasionally throwing out
-the nestlings of the stranger. They either lay their eggs in the nest
-thus appropriated, or oddly enough build one for themselves on the top
-of it. They usually sit on their own eggs and rear their own young; but
-Mr. Hudson says it is probable that they are occasionally parasitic, for
-he has seen the young of this species following old birds of a distinct
-kind and clamoring to be fed by them. The parasitic habits of another
-species of Molothrus, the _M. bonariensis_, are much more highly
-developed than those of the last, but are still far from perfect. This
-bird, as far as is known, invariably lays its eggs in the nest of
-strangers; but it is remarkable that several together sometimes commence
-to build an irregular untidy nest of their own, placed in singularly
-ill-adapted situations, as on the leaves of a large thistle. They never,
-however, as far as Mr. Hudson has ascertained, complete a nest for
-themselves. They often lay so many eggs—from fifteen to twenty—in the
-same foster-nest, that few or none can possibly be hatched. They have,
-moreover, the extraordinary habit of pecking holes in the eggs, whether
-of their own species or of their foster-parents, which they find in the
-appropriated nests. They drop also many eggs on the bare ground, which
-are thus wasted.”
-
-Can we possibly be expected to believe that it has been to the advantage
-of this species to give up its original regular method of incubating its
-own eggs, and acquire such a haphazard, new method? Does not the
-explanation prove too much, rather than give support to Darwin’s
-hypothesis? Is it not better to conclude, that despite the disadvantages
-entailed by a change in the original instincts, the species is still
-able to remain in existence?
-
-Darwin points out, in the case of the slave-making ants, that the
-slave-making instinct may have arisen in the first instance by ants
-carrying pupæ, that they have captured, into their own nests. Later this
-habit might become fixed, and, finally, after passing through several
-stages of development, the ants might become absolutely dependent on
-their slaves. It is also supposed that those colonies in which this
-instinct was better developed would survive in competition with other
-colonies of the same species on account of the supposed advantage of
-owning slaves. In this way natural selection steps in and perfects the
-process.
-
-It is far from proven, or even made probable, that a species of ant that
-becomes gradually dependent on its slaves is more likely to survive than
-other colonies that are not so dependent. All we can be certain of is
-that with slaves they have still been able to maintain their own.
-Moreover, we must not forget that it is not enough to show that a
-particular habit might be useful to a species, but it should also be
-shown that it is of sufficient importance, at every stage of its
-evolution, to give a decisive advantage in the “struggle for existence.”
-For unless a life and death struggle takes place between the different
-colonies, natural selection is powerless to bring about its supposed
-results. And who will be bold enough to affirm that the presence of
-slaves in a nest will give victory to that colony in competition with
-its neighbors? Has the history of mankind taught us that the
-slave-making countries have exterminated the countries without slaves?
-Is the question so simple as this? May not the degeneration of the
-masters more than compensate for the acquirement of slaves, and may not
-the loss of life in obtaining slaves more than counterbalance the
-advantage of the slaves after they are captured? In the face of these
-possibilities it is not surprising to find that Darwin, when summing up
-the chapter, makes the following admission: “I do not pretend that the
-facts in this chapter strengthen in any degree my theory; but none of
-the cases of difficulty, to the best of my judgment, annihilate it.”
-Darwin, with his usual frankness, adds:—
-
-“No doubt many instincts of very difficult explanation could be opposed
-to the theory of natural selection,—cases, in which we cannot see how an
-instinct could have originated; cases, in which no intermediate
-gradations are known to exist; cases of instincts of such trifling
-importance, that they could hardly have been acted on by natural
-selection; cases of instincts almost identically the same in animals so
-remote in the scale of nature, that we cannot account for their
-similarity by inheritance from a common progenitor, and consequently
-must believe that they were independently acquired through natural
-selection. I will not here enter on these several cases, but will
-confine myself to one special difficulty, which at first appeared to me
-insuperable, and actually fatal to the whole theory. I allude to the
-neuters or sterile females in insect communities; for these neuters
-often differ widely in instinct and in structure from both the males and
-fertile females, and yet, from being sterile, they cannot propagate
-their kind.
-
-“The subject well deserves to be discussed at great length, but I will
-here take only a single case, that of working or sterile ants. How the
-workers have been rendered sterile is a difficulty; but not much greater
-than that of any other striking modification of structure; for it can be
-shown that some insects and other articulate animals in a state of
-nature occasionally become sterile; and if such insects had been social,
-and it had been profitable to the community that a number should have
-been annually born capable of work, but incapable of procreation, I can
-see no especial difficulty in this having been effected through natural
-selection. But I must pass over this preliminary difficulty. The great
-difficulty lies in the working ants differing widely from both the males
-and the fertile females in structure, as in the shape of the thorax, and
-in being destitute of wings and sometimes of eyes, and in instinct. As
-far as instinct alone is concerned, the wonderful difference in this
-respect between the workers and the perfect females, would have been
-better exemplified by the hive-bee. If a working ant or other neuter
-insect had been an ordinary animal, I should have unhesitatingly assumed
-that all its characters had been slowly acquired through natural
-selection; namely, by individuals having been born with slight
-profitable modifications, which were inherited by the offspring; and
-that these again varied and again were selected, and so onwards. But
-with the working ant we have an insect differing greatly from its
-parents, yet absolutely sterile; so that it could never have transmitted
-successively acquired modifications of structure or instinct to its
-progeny. It may well be asked, how is it possible to reconcile this case
-with the theory of natural selection?”
-
-Darwin’s answer is that the differences of structure are correlated with
-certain ages and with the two sexes, but this is obviously only shifting
-the difficulty, not meeting it. He concludes, “I can see no great
-difficulty in any character becoming correlated with the sterile
-condition of certain members of the insect communities, the difficulty
-lies in understanding how such correlated modifications of structure
-could have been slowly accumulated by natural selection.” “This
-difficulty, though appearing insuperable, is lessened, or, as I believe,
-disappears, when it is remembered that selection may be applied to the
-family, as well as to the individual, and may thus give the desired
-end.”
-
-Darwin did not fail to see that there is a further difficulty even
-greater than the one just mentioned. He says: “But we have not as yet
-touched on the acme of the difficulty; namely, the fact that the neuters
-of several ants differ, not only from the fertile females and males, but
-from each other, sometimes to an almost incredible degree, and are thus
-divided into two or even three castes. The castes, moreover, do not
-commonly graduate into each other, but are perfectly well defined; being
-as distinct from each other as are any two species of the same genus, or
-rather as any two genera of the same family. Thus in Eciton, there are
-working and soldier neuters, with jaws and instincts extraordinarily
-different: in Cryptocerus, the workers of one caste alone carry a
-wonderful sort of shield on their heads, the use of which is quite
-unknown: in the Mexican Myrmecocystus, the workers of one caste never
-leave the nest; they are fed by the workers of another caste, and they
-have an enormously developed abdomen which secretes a sort of honey,
-supplying the place of that excreted by the aphides, or the domestic
-cattle as they may be called, which our European ants guard and
-imprison.”
-
-“It will indeed be thought that I have an overweening confidence in the
-principle of natural selection, when I do not admit that such wonderful
-and well-established facts at once annihilate the theory. In the simpler
-case of neuter insects all of one caste, which, as I believe, have been
-rendered different from the fertile males and females through natural
-selection, we may conclude from the analogy of ordinary variations, that
-the successive, slight, profitable modifications did not first arise in
-all the neuters in the same nest, but in some few alone; and that by the
-survival of the communities with females which produced most neuters
-having the advantageous modification, all the neuters ultimately came to
-be thus characterized. According to this view we ought occasionally to
-find in the same nest neuter insects, presenting gradations of
-structure; and this we do find, even not rarely, considering how few
-neuter insects out of Europe have been carefully examined.”
-
-From this the conclusion is reached:—
-
-“With these facts before me, I believe that natural selection, by acting
-on the fertile ants or parents, could form a species which should
-regularly produce neuters, all of large size with one form of jaw, or
-all of small size with widely different jaws; or lastly, and this is the
-greatest difficulty, one set of workers of one size and structure, and
-simultaneously another set of workers of a different size and
-structure;— a graduated series having first been formed, as in the case
-of the driver ant, and then the extreme forms having been produced in
-greater and greater numbers, through the survival of the parents which
-generated them, until none with an intermediate structure were produced.
-
-“I have now explained how, as I believe, the wonderful fact of two
-distinctly defined castes of sterile workers existing in the same nest,
-both widely different from each other and from their parents, has
-originated. We can see how useful their production may have been to a
-social community of ants, on the same principle that the division of
-labor is useful to civilized man. Ants, however, work by inherited
-instincts and by inherited organs or tools, whilst man works by acquired
-knowledge and manufactured instruments. But I must confess, that, with
-all my faith in natural selection, I should never have anticipated that
-this principle could have been efficient in so high a degree, had not
-the case of these neuter insects led me to this conclusion. I have,
-therefore, discussed this case, at some little but wholly insufficient
-length, in order to show the power of natural selection, and likewise
-because this is by far the most serious special difficulty which my
-theory has encountered. The case, also, is very interesting, as it
-proves that with animals, as with plants, any amount of modification may
-be effected by the accumulation of numerous, slight, spontaneous
-variations, which are in any way profitable, without exercise or habit
-having been brought into play. For peculiar habits confined to the
-workers or sterile females, however long they might be followed, could
-not possibly affect the males and fertile females, which alone leave
-descendants. I am surprised that no one has hitherto advanced this
-demonstrative case of neuter insects, against the well-known doctrine of
-inherited habit, as advanced by Lamarck.”
-
-We may dissent at once from Darwin’s statement which, he thinks, “proves
-that any amount of modification may be affected by the accumulation of
-numerous slight variations which are in any way profitable without
-exercise or habit having been brought into play”; we may dissent if for
-no other reason than that this begs the whole point at issue, and is not
-proven. It does not follow because in some colonies all intermediate
-stages of neuters exist, that in other colonies, where no such
-intermediate stages are present, these have been slowly weeded out by
-natural selection, causing to disappear all colonies slightly below the
-mark. It is this that begs the question. Because we can imagine that
-intermediate stages between the different castes may have been present,
-it neither follows that such fluctuating variations have been the basis
-for the evolution of the more sharply defined types, nor that the
-imagined advantage of such a change would have led through competition
-to the extermination of the other colonies. However much we may admire
-the skill with which Darwin tried to meet this difficulty, let us not
-put down the results to the good of the theory, but rather repeat once
-more Darwin’s own words at the end of this chapter, to the effect that
-the facts do not strengthen the theory.
-
-
-                       Sterility between Species
-
-The care with which Darwin examined every bearing of his theory is
-nowhere better exemplified than in his treatment of the question of
-sterility between the individuals of different species. It would be so
-obviously to the advantage of the selection theory if it were true that
-sterility between species had been acquired by selection in order to
-prevent intercrossing, that it would have been easy for a less cautious
-thinker to have fallen into the error of supposing that sterility might
-have been acquired in this way. Tempting as such a view appears, Darwin
-was not caught by the specious argument, as the opening sentence in the
-chapter of hybridism shows:—
-
-“The view commonly entertained by naturalists is that species, when
-intercrossed, have been specially endowed with sterility, in order to
-prevent their confusion. This view certainly seems at first highly
-probable, for species living together could hardly have been kept
-distinct had they been capable of freely crossing. The subject is in
-many ways important for us, more especially as the sterility of species
-when first crossed, and that of their hybrid offspring, cannot have been
-acquired, as I shall show, by the preservation of successive profitable
-degrees of sterility. It is an incidental result of differences in the
-reproductive systems of the parent species.”
-
-In dealing with this subject Darwin points out that we must be careful
-to distinguish between “the sterility of species when first crossed, and
-the sterility of hybrids produced from them.” In the former case, the
-reproductive organs of each individual are in a perfectly normal
-condition, while hybrids appear to be generally impotent owing to some
-imperfection in the reproductive organs themselves. They are not
-perfectly fertile, as a rule, either with each other, or with either of
-the parent forms.
-
-In striking contrast to the sterility between species is the fertility
-of varieties. If, as Darwin believes, varieties are incipient species,
-we should certainly expect to find them becoming less and less fertile
-with other fraternal varieties, or with the parent forms in proportion
-as they become more different. Yet experience appears to teach exactly
-the opposite; but the question is not a simple one, and the results are
-not so conclusive as appears at first sight. Let us first see how Darwin
-met this obvious contradiction to his view.
-
-In the first place, he points out that all species are not infertile
-when crossed with other species. The sterility of various species, when
-crossed, is so different in degree, and graduates away so insensibly,
-and the fertility of pure species is so easily affected by various
-circumstances, that it is most difficult to say where perfect fertility
-ends and sterility begins. “It can thus be shown that neither sterility
-nor fertility afford any certain distinction between species and
-varieties.” Darwin cites several cases in plants in which crosses
-between species have been successfully accomplished. The following
-remarkable results are also recorded: “Individual plants in certain
-species of Lobelia, Verbascum, and Passiflora can easily be fertilized
-by pollen from a distinct species, but not by pollen from the same
-plant, though this pollen can be proved to be perfectly sound by
-fertilizing other plants or species. In the genus Hippeastrum, in
-Corydalis as shown by Professor Hildebrand, in various orchids as shown
-by Mr. Scott and Fritz Müller, all the individuals are in this peculiar
-condition. So that with some species, certain abnormal individuals, and
-in other species all the individuals, can actually be hybridized much
-more readily than they can be fertilized by pollen from the same
-individual plant!”[14]
-
-Footnote 14:
-
-  A somewhat parallel case has recently been discovered by Castle for
-  the hermaphroditic ascidian _Ciona intestinalis_. In this case the
-  spermatozoa of any individual fail to fertilize the eggs of the same
-  individual, although they will fertilize the eggs of any other
-  individual.
-
-In regard to animals, Darwin concludes that “if the genera of animals
-are as distinct from each other as are the genera of plants, then we may
-infer that animals more widely distinct in the scale of nature can be
-crossed more easily than in the case of plants; but the hybrids
-themselves are, I think, more sterile.”
-
-The most significant fact in this connection is that the more widely
-different two species are, so that they are placed in different
-families, so much the less probable is it that cross-fertilization will
-produce any result. From this condition of infertility there may be
-traced a gradation between less different forms of the same genus to
-almost complete, or even complete, fertility between closely similar
-species. Darwin further points out that: “The hybrids raised from two
-species which are very difficult to cross, and which rarely produce any
-offspring, are generally very sterile; but the parallelism between the
-difficulty of making a first cross, and the sterility of the hybrids
-thus produced—two classes of facts which are generally confounded
-together—is by no means strict. There are many cases, in which two pure
-species, as in the genus Verbascum, can be united with unusual facility,
-and produce numerous hybrid offspring, yet these hybrids are remarkably
-sterile. On the other hand, there are species which can be crossed very
-rarely, or with extreme difficulty, but the hybrids, when at last
-produced, are very fertile. Even within the limits of the same genus,
-for instance in Dianthus, these two opposite cases occur.”
-
-In regard to reciprocal crosses Darwin makes the following important
-statements: “The diversity of the result in reciprocal crosses between
-the same two species was long ago observed by Kölreuter. To give an
-instance: _Mirabilis jalapa_ can easily be fertilized by the pollen of
-_M. longiflora_, and the hybrids thus produced are sufficiently fertile;
-but Kölreuter tried more than two hundred times, during eight following
-years, to fertilize reciprocally _M. longiflora_ with the pollen of _M.
-jalapa_, and utterly failed.”
-
-A formal interpretation of this difference can be easily imagined. The
-infertility in one direction may be due to some physical difficulty met
-with in penetrating the stigma, or style. For instance, the tissue in
-one species may be too compact, or the style too long. Pflüger, who
-carried out a large number of experiments by cross-fertilizing different
-species of frogs, reached the conclusion that the spermatozoa having
-small and pointed heads could cross-fertilize more kinds of eggs, than
-could the spermatozoa with large blunt heads. This is probably due to
-the ability of the smaller spermatozoa to penetrate the jelly around the
-eggs, or the pores in the surface of the egg itself. But there are also
-other sides to this question, as recent results have shown, for, even if
-a foreign spermatozoon can enter an egg, it does not follow that the
-development of the egg will take place. Here the difficulty is due to
-some obscure processes in the egg itself. Now that we know more of the
-nicely balanced combinations that take place during fertilization of the
-egg, and during the process of cell division, we can easily see that if
-the processes were in the least different in the two species it might be
-impossible to combine them in a single act.
-
-“Now do these complex and singular rules indicate that species have been
-endowed with sterility simply to prevent their becoming confounded in
-nature? I think not. For why should the sterility be so extremely
-different in degree, when various species are crossed, all of which we
-must suppose it would be equally important to keep from blending
-together?”
-
-“The foregoing rules and facts, on the other hand, appear to me clearly
-to indicate that the sterility both of first crosses and of hybrids is
-simply incidental or dependent on unknown differences in their
-reproductive systems; the differences being of so peculiar and limited a
-nature, that, in reciprocal crosses between the same two species, the
-male sexual element of the one will often freely act on the female
-sexual element of the other, but not in a reversed direction.”
-
-Does Darwin give here a satisfactory answer to the difficulty that he
-started out to explain away? On the whole, the reader will admit, I
-think, that he has fairly met the situation, in so far as he has shown
-that there is no absolute line of demarcation between the power of
-intercrossing of varieties and races, and of species. It is also
-_extremely important to have found that the difficulties increase, so to
-speak, even beyond the limits of the species_; since species, belonging
-to different genera, are as a rule more difficult to intercross than
-when they belong to the same genus. The further question, as to whether
-there are differences in respect to the power of intercrossing between
-different kinds of varieties, such as those dependent on selection of
-fluctuating variations, of local conditions, of mutations, etc., is far
-from being settled at the present time.
-
-That this property of species is useful to them, in the somewhat unusual
-sense that it keeps them from freely mingling with other species, is
-true; but, as has been said, this would be a rather peculiar kind of
-adaptation. If, however, it be claimed that this property is useful to
-species, as Darwin himself claims, then, as he also points out, it is a
-useful acquirement that cannot have arisen through natural selection. It
-is not difficult to show why this must be so. If two varieties were to
-some extent at the start less fertile, _inter se_, than with their own
-kind, the only way in which they could become more infertile through
-selection would be by selecting those individuals in each generation
-that are still more infertile, but the forms of this sort would, _ex
-hypothese_, become less numerous than the descendants of each species
-itself, which would, therefore, supplant the less fertile ones.
-
-Darwin’s own statement in regard to this point is as follows:—
-
-“At one time it appeared to me probable, as it has to others, that the
-sterility of first crosses and of hybrids might have been slowly
-acquired through the natural selection of slightly lessened degrees of
-fertility, which, like any other variation, spontaneously appeared in
-certain individuals of one variety when crossed with those of another
-variety. For it would clearly be advantageous to two varieties or
-incipient species, if they could be kept from blending, on the same
-principle that, when man is selecting at the same time two varieties, it
-is necessary that he should keep them separate.
-
-“In considering the probability of natural selection having come into
-action, in rendering species mutually sterile, the greatest difficulty
-will be found to lie in the existence of many graduated steps from
-slightly lessened fertility to absolute sterility. It may be admitted
-that it would profit an incipient species, if it were rendered in some
-slight degree sterile when crossed with its parent form or with some
-other variety; for thus fewer bastardized and deteriorated offspring
-would be produced to commingle their blood with the new species in
-process of formation. But he who will take the trouble to reflect on the
-steps by which this first degree of sterility could be increased through
-natural selection to that high degree which is common with so many
-species, and which is universal with species which have been
-differentiated to a generic or family rank, will find the subject
-extraordinarily complex. After mature reflection it seems to me that
-this could not have been effected through natural selection. Take the
-case of any two species which, when crossed, produced few and sterile
-offspring; now, what is there which could favor the survival of those
-individuals which happened to be endowed in a slightly higher degree
-with mutual infertility, and which thus approached by one small step
-toward absolute sterility? Yet an advance of this kind, if the theory of
-natural selection be brought to bear, must have incessantly occurred
-with many species, for a multitude are mutually quite barren.”
-
-Darwin points out the interesting parallel existing between the results
-of intercrossing, and those of grafting together parts of different
-species.
-
-“As the capacity of one plant to be grafted or budded on another is
-unimportant for their welfare in a state of nature, I presume that no
-one will suppose that this capacity is a _specially_ endowed quality,
-but will admit that it is incidental on differences in the laws of
-growth of the two plants. We can sometimes see the reason why one tree
-will not take on another, from differences in their rate of growth, in
-the hardness of their wood, in the period of the flow or nature of their
-sap, etc.; but in a multitude of cases we can assign no reason whatever.
-Great diversity in the size of two plants, one being woody and the other
-herbaceous, one being evergreen and the other deciduous, and adapted to
-widely different climates, do not always prevent the two grafting
-together. As in hybridization, so with grafting, the capacity is limited
-by systematic affinity, for no one has been able to graft together trees
-belonging to quite distinct families; and, on the other hand, closely
-allied species, and varieties of the same species, can usually, but not
-invariably, be grafted with ease. But this capacity, as in
-hybridization, is by no means absolutely governed by systematic
-affinity. Although many distinct genera within the same family have been
-grafted together, in other cases species of the same genus will not take
-on each other. The pear can be grafted far more readily on the quince,
-which is ranked as a distant genus, than on the apple, which is a member
-of the same genus. Even different varieties of the pear take with
-different degrees of facility on the quince; so do different varieties
-of the apricot and peach on certain varieties of the plum.”
-
-“We thus see, that although there is a clear and great difference
-between the mere adhesion of grafted stocks, and the union of the male
-and female elements in the act of reproduction, yet that there is a rude
-degree of parallelism in the results of grafting and of crossing of
-distinct species. And we must look at the curious and complex laws
-governing the facility with which trees can be grafted on each other as
-incidental on unknown differences in their vegetative systems, so I
-believe that the still more complex laws governing the facility of first
-crosses are incidental on unknown differences in their reproductive
-systems.... The facts by no means seem to indicate that the greater or
-lesser difficulty of either grafting or crossing various species has
-been a special endowment; although in the case of crossing, the
-difficulty is as important for the endurance and stability of specific
-forms, as in the case of grafting it is unimportant for their welfare.”
-
-
-                     Weismann’s Germinal Selection
-
-We cannot do better, in bringing this long criticism of the Darwinian
-theory to an end, than by considering the way in which Weismann has
-attempted in his paper on “Germinal Selection” to solve one of the
-“patent contradictions” of the selection theory. He calls attention, in
-doing so, to what he regards as a vital weakness of the theory in the
-form in which it was left by Darwin himself. Weismann says:—
-
-“The basal idea of the essay—the existence of Germinal Selection—was
-propounded by me some time since,[15] but it is here for the first time
-fully set forth and tentatively shown to be the necessary complement of
-the process of selection. Knowing this factor, we remove, it seems to
-me, the patent contradiction of the assumption that the general fitness
-of organisms, or the adaptations _necessary_ to their existence, are
-produced by _accidental_ variations—a contradiction which formed a
-serious stumbling-block to the theory of selection. Though still
-assuming that the _primary_ variations are ‘accidental,’ I yet hope to
-have demonstrated that an interior mechanism exists which compels them
-to go on increasing in a definite direction, the moment selection
-intervenes. _Definitely directed variation exists_, but not predestined
-variation, running on independently of the life conditions of the
-organism, as Nägeli, to mention the most extreme advocate of this
-doctrine, has assumed; on the contrary, the variation is such as is
-elicited and controlled by those conditions themselves, though
-indirectly.”
-
-Footnote 15:
-
-  _Neue Gedanken zur Vererbungsfrage, eine Antwort an Herbert Spencer_,
-  Jena, 1895.
-
-“The real aim of the present essay is to rehabilitate the principle of
-selection. If I should succeed in reinstating this principle in its
-emperilled rights, it would be a source of extreme satisfaction to me;
-for I am so thoroughly convinced of its indispensability as to believe
-that its demolition would be synonymous with the renunciation of all
-inquiry concerning the causal relation of vital phenomena. If we could
-understand the adaptations of nature, whose number is infinite, only
-upon the assumption of a teleological principle, then, I think, there
-would be little inducement to trouble ourselves about the causal
-connection of the stages of ontogenesis, for no good reason would exist
-for excluding teleological principles from this field. Their
-introduction, however, is the ruin of science.”[16]
-
-Footnote 16:
-
-  Translated by J. McCormack. The Open Court Publishing Company. The
-  following quotations are also taken from this translation.
-
-Weismann states that those critics who maintain that selection cannot
-create, but only reject, “fail to see that precisely through this
-rejection its creative efficacy is asserted.” There is raised here,
-though not for the first time, a point that is of no small importance
-for both Darwinians and anti-Darwinians to consider; for, without
-further examination, it is by no means self-evident, as Weismann
-implies, that by exterminating all variations that are below the average
-the standard of successive generations could ever be raised beyond the
-most extreme fluctuating variation. At least this appears to be the case
-if individual, fluctuating variations be the sort selected, and it is to
-this kind of variation to which Weismann presumably refers. Without
-discussing this point here, let us examine further what Weismann has to
-say. He thinks that while in each form there may be a very large number
-of possible variations, yet there are also impossible variations as
-well, which do not appear. “The cogency, the irresistible cogency as I
-take it, of the principle of selection is precisely its capacity of
-explaining why fit structures always arise, and this certainly is the
-great problem of life.” Weismann points out that it is a remarkable fact
-that to-day, after science has been in possession of this principle for
-something over thirty years, “during which time she has busily occupied
-herself with its scope, the estimation in which the theory is held
-should be on the decline.” “It would be easy to enumerate a long list of
-living writers who assign to it a subordinate part only in evolution, or
-none at all.” “Even Huxley implicitly, yet distinctly, intimated a doubt
-regarding the principle of selection when he said: ‘Even if the
-Darwinian hypothesis were swept away, evolution would still stand where
-it is.’ Therefore he, too, regarded it as not impossible that this
-hypothesis should disappear from among the great explanatory principles
-by which we seek to approach nearer to the secrets of nature.”
-
-Weismann is not, however, of this opinion, and believes that the present
-depression is only transient, because it is only a reaction against a
-theory that had been exalted to the highest pinnacle. He thinks that the
-principle of selection is not overestimated, but that naturalists
-imagined too quickly that they understood its workings. “On the
-contrary, the deeper they penetrated into its workings the clearer it
-appeared that something was lacking, that the action of the principle,
-though upon the whole clear and representable, yet when carefully looked
-into encountered numerous difficulties, which were formidable, for the
-reason that we were unsuccessful in tracing out the actual details of
-the individual process, and, therefore, in _fixing_ the phenomenon as it
-actually occurred. We can state in no single case how great a variation
-must be to have selective value, nor how frequently it must occur to
-acquire stability. We do not know when and whether a desired useful
-variation really occurs, nor on what its appearance depends; and we have
-no means of ascertaining the space of time required for the fulfilment
-of the selective processes of nature, and hence cannot calculate the
-exact number of such processes that do and can take place at the same
-time in the same species. Yet all this is necessary if we wish to follow
-out the precise details of a given case.
-
-“But perhaps the most discouraging circumstance of all is, that we can
-assert in scarcely a single actual instance in nature whether an
-observed variation is useful or not—a drawback that I distinctly
-emphasized some time ago. Nor is there much hope of betterment in this
-respect, for think how impossible it would be for us to observe all the
-individuals of a species in all their acts of life, be their habitat
-ever so limited—and to observe all this with a precision enabling us to
-say that this or that variation possessed selective value, that is, was
-a decisive factor in determining the existence of the species.”
-
-“And thus it is everywhere. Even in the most indubitable cases of
-adaptation as, for instance, in that of the striking protective coloring
-of many butterflies, the sole ground of inference that the species on
-the whole is adequately adapted to its conditions of life, is the simple
-fact that the species is, to all appearances, preserved undiminished,
-but the inference is not at all permissible that just this protective
-coloring has selective value for the species, that is, if it were
-lacking, the species would necessarily have perished.”
-
-Few opponents of Darwinism could give a more pessimistic account of the
-accomplishments of the theory of natural selection than this, by one of
-the leaders of the modern school: “Discouraging, therefore, as it may be
-that the control of nature in her minutest details is here gainsaid us,
-yet it were equivalent to sacrificing the gold to the dross, if simply
-from our inability to follow out the details of the individual case we
-should renounce altogether the principle of selection, or should
-proclaim it as only subsidiary, on the ground that we believe the
-protective coloring of the butterfly is not a protective coloring, but a
-combination of colors inevitably resulting from internal causes. The
-protective coloring remains a protective coloring whether at the time in
-question it is or is not necessary for the species; and it arose as
-protective coloring—arose not because it was a constitutional necessity
-of the animal’s organism that here a red and there a white, black, or
-yellow spot should be produced, but because it was advantageous, because
-it was necessary for the animal. There is only one explanation possible
-for such patent adaptations, and that is selection. What is more, no
-other natural way of their originating is conceivable, for we have no
-right to assume teleological forces in the domain of natural phenomena.”
-
-Weismann states that he does not accept Eimers’s view that the markings
-of the wings of the butterflies of the genus Papilio are due to a
-process of evolution in a direct line, independent of external causes.
-
-“On the contrary, I believe it can be clearly proved that the wing of
-the butterfly is a tablet on which Nature has inscribed everything she
-has deemed advantageous to the preservation and welfare of her
-creatures, and nothing else; or, to abandon the simile, that these color
-patterns have not proceeded from inward evolutional forces but are the
-result of selection. At least in all places where we do understand their
-biological significance these patterns are constituted and distributed
-over the wing exactly as utility would require.”
-
-Again: “I should be far from maintaining that the markings arose
-unconformably to law. Here, as elsewhere, the dominance of law is
-certain. But I take it, that the laws involved, that is, the
-physiological conditions of the variation, here are without exception
-subservient to the ends of a higher power—utility; and that it is
-utility primarily that determines the kind of colors, spots, streaks,
-and bands that shall originate, as also their place and mode of
-disposition. The laws come into consideration only to the extent of
-conditioning the quality of the constructive materials—the variations,
-out of which selection fashions the designs in question. And this also
-is subject to important restrictions, as will appear in the sequel.”
-This conclusion contains all that the most ardent Darwinian could ask.
-
-He rejects the idea that internal laws alone could have produced the
-result, because:—
-
-“If internal laws controlled the markings on butterflies’ wings, we
-should expect that some general rule could be established, requiring
-that the upper and under surfaces of the wings should be alike or that
-they should be different, or that the fore wings should be colored the
-same as or differently from the hind wings, etc. But in reality all
-possible kinds of combinations occur simultaneously, and no rule holds
-throughout. Or, it might be supposed that bright colors should occur
-only on the upper surface or only on the under surface, or on the fore
-wings or only on the hind wings. But the fact is they occur
-indiscriminately, now here, now there, and no one method of appearance
-is uniform throughout all the species. But the fitness of the various
-distributions of colors is apparent, and the moment we apply the
-principle of utility we know why in the diurnal butterflies the upper
-surface alone is usually variegated and the under surface protectively
-colored, or why in the nocturnal butterflies the fore wings have the
-appearance of bark, of old wood, or of a leaf, whilst the hind wings,
-which are covered when resting, alone are brilliantly colored. On this
-theory we also understand the exceptions to these rules. We comprehend
-why Danaids, Heliconids, Euploids, and Acracids, in fact all diurnal
-butterflies offensive to the taste and smell, are mostly brightly marked
-and equally so on both surfaces, whilst all species not thus exempt from
-persecution have the protective coloring on the under surface and are
-frequently quite differently colored there from what they are on the
-upper.
-
-“In any event, the supposed formative laws are not obligatory.
-Dispensations from them can be issued and are issued _whenever utility
-requires it_.”
-
-Dispensations from the laws of growth! Does not a philosophy of this
-sort seem to carry us back into the dark ages? Is this the best that the
-Darwinian school can do to protect itself against the difficulties into
-which its chief disciple confesses it has fallen?
-
-Weismann lays great emphasis on the case of the Indian leaf-butterfly,
-_Kallima inachis_; and points out that the leaf markings are executed
-“in absolute independence of the other uniformities governing the wing.”
-
-“The venation of the wing is utterly ignored by the leaf markings, and
-its surface is treated as a _tabula rasa_ upon which anything
-conceivable can be drawn. In other words, we are presented here with a
-_bilaterally symmetrical_ figure engraved on a surface which is
-essentially _radially symmetrical_ in its divisions.
-
-“I lay unusual stress upon this point because it shows that we are
-dealing here with one of those cases which cannot be explained by
-mechanical, that is, by natural means, unless natural selection actually
-exists and is actually competent to create new properties; for the
-Lamarckian principle is excluded here _ab initio_, seeing that we are
-dealing with a formation which is only passive in its effects: the leaf
-markings are effectual simply by their existence and not by any function
-which they perform; they are present in flight as well as at rest,
-during the absence of a danger, as well as during the approach of an
-enemy.
-
-“Nor are we helped here by the assumption of _purely internal motive
-forces_, which Nägeli, Askenasy, and others have put forward as
-supplying a _mechanical_ force of evolution. It is impossible to regard
-the coincidence of an Indian butterfly with the leaf of a tree now
-growing in an Indian forest as fortuitous, as a _lusus naturæ_. Assuming
-this seemingly mechanical force, therefore, we should be led back
-inevitably to a teleological principle which produces adaptive
-characters and which must have deposited the directive principle in the
-very first germ of terrestrial organisms, so that after untold ages at a
-definite time and place the illusive leaf markings should be developed.
-The assumption of preëstablished harmony between the evolution of the
-ancestral line of the tree with its prefigurative leaf, and that of the
-butterfly with its imitating wing, is absolutely necessary here, as I
-pointed out many years ago, but as is constantly forgotten by the
-promulgators of the theory of internal evolutionary forces.”
-
-Weismann concludes, therefore, that for his present purpose it suffices
-to show “that cases exist wherein all natural explanations except that
-of selection fail us,” and he then proceeds to point out that even the
-natural selection of Darwin and of Wallace also fail to give us a
-reasonable explanation of how, for example, the markings on the wings of
-the Kallima butterfly have come about. The main reason that he gives to
-show that this is the case rests on the difficulty of the assumption
-that the right variations should always be present in the right place.
-Here “is the insurmountable barrier for the explanatory power of the
-principle [natural selection] for who, or what, is to be our guarantee
-that the dark scales shall appear at the exact spots on the wing where
-the midrib of the leaf must grow? And that later dark scales shall
-appear at the exact spots to which the midrib must be prolonged? And
-that still later such dark scales shall appear at the places whence the
-lateral ribs start, and that here also a definite acute angle shall be
-preserved.” Thus the philosopher in his closet multiplies and magnifies
-the difficulties for which he is about to offer a panacea. Had the same
-amount of labor been spent in testing whether the life of this butterfly
-is so closely dependent on the exact imitation of the leaf, we might
-have been spared the pains of this elaborate exordium. There are at
-least some grounds for suspicion that the whole case of Kallima is “made
-up.” If this should prove true, it will be a bad day for the Darwinians,
-unless they fall back on Weismann’s statement that their theory is
-insufficient to prove a single case!
-
-Weismann has used Kallima only as the most instructive illustration. The
-objections that are here evident are found not only in the cases of
-protective coloration, but “are applicable in all cases where the
-process of selection is concerned. Take, for example, the case of
-instincts that are called into action only once in life, as the pupal
-performances of insects, the fabrication of cocoons, etc. How is it that
-the useful variations were always present here?” Weismann concludes that
-“something is still wanting to the selection theory of Darwin and
-Wallace, which it is obligatory on us to discover, if we possibly can,
-and without which selection as yet offers no complete explanation of the
-phyletic processes of transformation.” Weismann’s first step in the
-solution of the difficulty is contained in the following statement:—
-
-“My inference is a very simple one: if we are forced by the facts on all
-hands to the assumption that the useful variations which render
-selection possible are always present, then, _some profound connection
-must exist between the utility of a variation and its actual
-appearance_, or, in other words, _the direction of the variation of a
-part must be determined by utility_, and we shall have to see whether
-facts exist that confirm our conjecture.”
-
-Weismann finds the solution in the method by which the breeder has
-obtained his results in artificial selection. For instance, the
-long-tailed variety of the domestic cock of Japan owes its existence, it
-is claimed, to skilful selection, and not at all to the circumstance
-that, at some period of the race’s history, a cock with tail-feathers
-six feet in length suddenly and spasmodically appeared.
-
-Weismann continues: “Now what does this mean? Simply that the hereditary
-diathesis, the germinal constitution (the _Anlage_) of the breed was
-changed in the respect in question, and our conclusion from this and
-numerous similar facts of artificial selection runs as follows: _by the
-selection alone of the plus or minus variations of a character is the
-constant modification of that character in the plus or minus direction
-determined_. Obviously the hereditary _diminution_ of a part is also
-effected by the simple selection of the individuals in each generation
-possessing the smallest parts, as is proved, for example, by the tiny
-bills and feet of numerous breeds of doves. We may assert, therefore, in
-general terms: a definitely directed progressive variation of a given
-part is produced by continued selection in that definite direction. This
-is no hypothesis, but a direct inference from the facts and may also be
-expressed as follows: _by a selection of the kind referred to the germ
-is progressively modified in a manner corresponding with the production
-of a definitely directed progressive variation of the part_.”
-
-So far there is nothing essentially new offered, since Darwin often
-tacitly recognized that the standard of variation could be raised in
-this way, and in some places he has made definite statements that this
-will take place. Weismann thinks that after each selection, fluctuation
-will then occur around a higher average (mode). He says “that this is a
-fact,” and is proved by the case of the Japanese cock. It need scarcely
-be pointed out that it is an assumption, based on what is supposed to
-have taken place in this bird, and is not a “fact.”
-
-Weismann continues: “But the question remains, _why_ is this the fact?”
-He believes his hypothesis of the existence of determinants in the germ
-gives a satisfactory answer to this “why.” “According to this theory
-every independent and hereditarily variable part is represented in the
-germ by a _determinant_, whose size and power of assimilation
-corresponds to the size and vigor of the part. These determinants
-multiply as do all vital units by growth and division, and necessarily
-they increase rapidly in every individual, and the more rapidly the
-greater the quantity of the germinal cells the individual produces. And
-since there is no more reason for excluding irregularities of passive
-nutrition, and of the supply of nutriment in these minute,
-microscopically invisible parts, than there is in the larger visible
-parts of the cells, tissues, and organs, consequently the descendants of
-a determinant can never all be exactly alike in size and capacity of
-assimilation, but they will oscillate in this respect to and fro about
-the maternal determinant as about their zero point, and will be partly
-greater, partly smaller, and partly of the same size as that. In these
-oscillations, now, the material for further selection is presented, and
-in the inevitable fluctuations of the nutrient supply, I see the reason
-why every step attained immediately becomes the zero point of new
-fluctuations, and consequently why the size of a part can be augmented
-or diminished by selection without limit, solely by the displacement of
-the zero point of variation as the result of selection.”
-
-The best illustration of this process of germinal selection is found,
-Weismann believes, in the case of the degeneration of organs. “For in
-most retrogressive processes _active_ selection in Darwin’s sense plays
-no part, and advocates of the Lamarckian principle, as above remarked,
-have rightly denied that active selection, that is, the selection of
-individuals possessing the useless organ in its most reduced state, is
-sufficient to explain the process of degeneration. I, for my part, have
-never assumed this, and have on this very account enunciated the
-_principle of panmixia_. Now, although this, as I have still no reason
-for doubting, is a perfectly correct principle, which really does have
-an essential and indispensable share in the process of retrogression,
-still it is not _alone_ sufficient for a full explanation of the
-phenomena. My opponents, in advancing this objection, were right, to the
-extent indicated, and as I expressly acknowledge, although they were
-unable to substitute anything positive in its stead or to render my
-explanation complete. The very fact of the cessation of control over the
-organ is sufficient to explain its _degeneration_, that is, its
-deterioration, the disharmony of its parts, but not the fact which
-actually and always occurs where an organ has become useless—viz., _its
-gradual and unceasing diminution continuing for thousands and thousands
-of years and culminating in its final and absolute effacement_.”
-
-If then neither selection of persons nor the cessation of personal
-selection can explain the phenomenon, we must look elsewhere for the
-answer. This Weismann finds in the application of Roux’s hypothesis of
-the struggle of the parts to obtain nourishment.
-
-“The production of the long tail-feathers of the Japanese cock does not
-repose solely on the displacement directly effected by personal
-selection, of the zero point of variation upward, but that _it is also
-fostered and strengthened by germinal selection_. Were that not so, the
-phenomena of the transmutation of species, in so far as fresh growth and
-the enlargement and complication of organs already present are
-concerned, _would not be a whit more intelligible than they were
-before_.”
-
-Thus Weismann has piled up one hypothesis on another as though he could
-save the integrity of the theory of natural selection by adding new
-speculative matter to it. The most unfortunate feature is that the new
-speculation is skilfully removed from the field of verification, and
-invisible germs whose sole functions are those which Weismann’s
-imagination bestows on them, are brought forward as though they could
-supply the deficiencies of Darwin’s theory. This is, indeed, the old
-method of the philosophizers of nature. An imaginary system has been
-invented which attempts to explain all difficulties, and if it fails,
-then new inventions are to be thought of. Thus we see where the theory
-of the selection of fluctuating germs has led one of the most widely
-known disciples of the Darwinian theory.
-
-The worst feature of the situation is not so much that Weismann has
-advanced new hypotheses unsupported by experimental evidence, but that
-the speculation is of such a kind that it is, from its very nature,
-unverifiable, and therefore useless. Weismann is mistaken when he
-assumes that many zoologists object to his methods because they are
-largely speculative. The real reason is that the speculation is so often
-of a kind that cannot be tested by observation or by experiment.
-
-
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-
-
-
-
-                               CHAPTER VI
-
-                  DARWIN’S THEORY OF SEXUAL SELECTION
-
-                            Sexual Selection
-
-
-The theory of sexual selection was formulated by Darwin, even in the
-first edition of the “Origin of Species,” but was developed at much
-greater length in “The Descent of Man.” “This form of selection depends,
-not on a struggle for existence in relation to other organic beings or
-to external conditions, but on a struggle between the individuals of one
-sex, generally the males, for the possession of the other sex. The
-result is not death to the unsuccessful competitor, but few or no
-offspring. Sexual selection is, therefore, less rigorous than natural
-selection. Generally the most vigorous males, those which are best
-fitted for their place in nature, will leave most progeny. But in many
-cases victory depends, not so much on general vigor, as on having
-special weapons, confined to the male sex. A hornless stag or spurless
-cock would have a poor chance of leaving numerous offspring. Sexual
-selection, by always allowing the victor to breed, might surely give
-indomitable courage, length to the spur, and strength to the wing to
-strike in the spurred leg in nearly the same manner as the brutal
-cock-fighter by the careful selection of his best cocks.” It is
-important to notice that the theory of sexual selection is admittedly an
-extension of the selection principle into a new field. Having accounted
-for domesticated animals and plants by artificial selection, and for the
-adaptations of wild species by natural selection, there remained only to
-account for the secondary sexual differences between the sexes by the
-principle of sexual selection.
-
-There are two ways in which Darwin supposes sexual selection to act: (1)
-through competition of the individuals of the same sex with each
-other,—the strongest or best-equipped for fighting or for finding the
-individuals of the other sex gaining an advantage; (2) through selection
-by the individuals of one sex of certain preferred individuals of the
-other sex.
-
-The first category is natural selection applied to the members of one
-sex in competition with each other, although the result does not lead to
-the death of the unsuccessful individual, but excludes it from leaving
-progeny. In the second category a new element is introduced, namely, the
-_selective power_ of the individuals of one sex, usually the female. It
-is this part that adds a distinctly new element to Darwin’s other two
-theories of selection, and it is this part that we naturally think of as
-the theory of sexual selection _par excellence_. Darwin makes, however,
-no sharp distinction between these two sides of his theory, but includes
-both under the heading of sexual selection.
-
-In order to get the theory itself before us in as concrete form as
-possible, let us examine some of the cases that Darwin has given to show
-how he supposes the process to be carried out.
-
-“There are many other structures and instincts which must have been
-developed through sexual selection—such as the weapons of offence and
-the means of defence of the males for fighting with and driving away
-their rivals—their courage and pugnacity—their various ornaments—their
-contrivances for producing vocal or instrumental music—and their glands
-for emitting odors, most of these latter structures serving only to
-allure or excite the female. It is clear that these characters are the
-result of sexual and not of ordinary selection, since unarmed,
-unornamented, or unattractive males would succeed equally well in the
-battle for life and in leaving a numerous progeny, but for the presence
-of better-endowed males. We may infer that this would be the case,
-because the females, which are unarmed and unornamented, are able to
-survive and procreate their kind. Secondary sexual characters of the
-kind just referred to will be fully discussed in the following chapters,
-as being in many respects interesting, but especially as depending on
-the will, choice, and rivalry of the individuals of either sex. When we
-behold two males fighting for the possession of the female, or several
-male birds displaying their gorgeous plumage, and performing strange
-antics before an assembled body of females, we cannot doubt that, though
-led by instinct, they know what they are about, and consciously exert
-their mental and bodily powers.”
-
-This general statement gives an idea of the class of phenomena that
-Darwin proposes to explain by the theory of sexual selection. The close
-resemblance between this process and that of artificial selection may be
-gathered from the following statement:—
-
-“Just as man can improve the breed of his game-cocks by the selection of
-those birds which are victorious in the cockpit, so it appears that the
-strongest and most vigorous males, or those provided with the best
-weapons, have prevailed under nature, and have led to the improvement of
-the natural breed or species. A slight degree of variability leading to
-some advantage, however slight, in reiterated deadly contests would
-suffice for the work of sexual selection; and it is certain that
-secondary sexual characters are eminently variable. Just as man can give
-beauty, according to his standard of taste, to his male poultry, or more
-strictly can modify the beauty originally acquired by the parent
-species, can give to the Sebright bantam a new and elegant plumage, an
-erect and peculiar carriage—so it appears that female birds in a state
-of nature have, by a long selection of the more attractive males, added
-to their beauty or other attractive qualities. No doubt this implies
-powers of discrimination and taste on the part of the female which will
-at first appear extremely improbable; but by the facts to be adduced
-hereafter, I hope to be able to show that the females actually have
-these powers. When, however, it is said that the lower animals have a
-sense of beauty, it must not be supposed that such sense is comparable
-with that of a cultivated man, with his multiform and complex associated
-ideas. A more just comparison would be between the taste for the
-beautiful in animals, and that in the lowest savages, who admire and
-deck themselves with any brilliant, glittering, or curious object.”
-
-Darwin did not close his eyes to the difficulties which the theory had
-to contend against. One of the most formidable of these objections is
-described in the following words: “Our difficulty in regard to sexual
-selection lies in understanding how it is that the males which conquer
-other males, or those which prove the most attractive to the females,
-leave a greater number of offspring to inherit their superiority than
-their beaten and less attractive rivals. Unless this result does follow,
-the characters which give to certain males an advantage over others
-could not be perfected and augmented through sexual selection. When the
-sexes exist in exactly equal numbers, the worst-endowed males will
-(except where polygamy prevails) ultimately find females, and leave as
-many offspring, as well fitted for their general habits of life, as the
-best-endowed males. From various facts and considerations, I formerly
-inferred that with most animals, in which secondary sexual characters
-are well developed, the males considerably exceeded the females in
-number; but this is not by any means always true. If the males were to
-the females as two to one, or as three to two, or even in a somewhat
-lower ratio, the whole affair would be simple; for the better-armed or
-more attractive males would leave the largest number of offspring. But
-after investigating, as far as possible, the numerical proportion of the
-sexes, I do not believe that any great inequality in number commonly
-exists. In most cases sexual selection appears to have been effective in
-the following manner.
-
-“Let us take any species, a bird for instance, and divide the females
-inhabiting a district into two equal bodies, the one consisting of the
-more vigorous and better-nourished individuals, and the other of the
-less vigorous and healthy. The former, there can be little doubt, would
-be ready to breed in the spring before the others; and this is the
-opinion of Mr. Jenner Weir, who has carefully attended to the habits of
-birds during many years. There can also be no doubt that the most
-vigorous, best-nourished and earliest breeders would on an average
-succeed in rearing the largest number of fine offspring. The males, as
-we have seen, are generally ready to breed before the females; the
-strongest, and with some species the best-armed of the males, drive away
-the weaker; and the former would then unite with the more vigorous and
-better-nourished females, because they are the first to breed. Such
-vigorous pairs would surely rear a larger number of offspring than the
-retarded females, which would be compelled to unite with the conquered
-and less powerful males, supposing the sexes to be numerically equal;
-and this is all that is wanted to add, in the course of successive
-generations, to the size, strength and courage of the males, or to
-improve their weapons.”
-
-I shall comment later on the points here raised, but we should not let
-this opportunity pass without noticing, that even if the pairing were to
-follow according to the method here imagined, still the argument breaks
-down at the critical point, for there is no evidence that the more
-precocious females would rear a larger number of offspring than the more
-normal females, or even those that breed somewhat later.
-
-The greater eagerness of the males which has been observed in so many
-different classes of animals is accounted for as follows:—
-
-“But it is difficult to understand why the males of species, of which
-the progenitors were primordially free, should invariably have acquired
-the habit of approaching the females, instead of being approached by
-them. But in all cases, in order that the males should seek efficiently,
-it would be necessary that they should be endowed with strong passions;
-and the acquirement of such passions would naturally follow from the
-more eager leaving a larger number of offspring than the less eager.”
-
-Thus we are led to the rather complex conclusion, that the more eager
-males will leave more descendants, and those that are better endowed
-with ornaments will be the ones selected. But unless it can be shown
-that there is some connection between greater eagerness and better
-ornamentation, it might often occur that the less ornamented were the
-more eager individuals, in which case there would be an apparent
-conflict between the two acquirements.
-
-After giving some cases of the greater variability of the males, in
-respect to characters that are not connected with sexual selection, and
-presumably not the result of any kind of selection, Darwin concludes:
-“Through the action of sexual and natural selection male animals have
-been rendered in very many instances widely different from their
-females; but independently of selection the two sexes, from differing
-constitutionally, tend to vary in a somewhat different manner. The
-female has to expend much organic matter in the formation of her ova,
-whereas the male expends much force in fierce contests with his rivals,
-in wandering about in search of the female, in exerting his voice,
-pouring out odoriferous secretions, etc.: and this expenditure is
-generally concentrated within a short period. The great vigor of the
-male during the season of love seems often to intensify his colors,
-independently of any marked difference from the female. In mankind, and
-even as low down in the organic scale as in the Lepidoptera, the
-temperature of the body is higher in the male than in the female,
-accompanied in the case of man by a slower pulse. On the whole, the
-expenditure of matter and force by the two sexes is probably nearly
-equal, though effected in very different ways and at different rates.”
-
-Again: “From the causes just specified, the two sexes can hardly fail to
-differ somewhat in constitution, at least during the breeding season;
-and although they may be subjected to exactly the same conditions, they
-will tend to vary in a different manner. If such variations are of no
-service to either sex, they will not be accumulated and increased by
-sexual or natural selection. Nevertheless, they may become permanent if
-the exciting cause acts permanently; and in accordance with a frequent
-form of inheritance they may be transmitted to that sex alone in which
-they first appeared. In this case, the two sexes will come to present
-permanent, yet unimportant, differences of character. For instance, Mr.
-Allen shows that with a large number of birds inhabiting the northern
-and southern United States, the specimens from the south are
-darker-colored than those from the north; and this seems to be the
-direct result of the difference in temperature, light, etc., between the
-two regions. Now, in some few cases, the two sexes of the same species
-appear to have been differently affected; in the _Agelæus phœniceus_ the
-males have had their colors greatly intensified in the south; whereas
-with _Cardinalis virginianus_ it is the females which have been thus
-affected: with _Quiscalus major_ the females have been rendered
-extremely variable in tint, whilst the males remain nearly uniform.”
-
-The admissions contained in this statement would seem to jeopardize the
-entire question, for, if it is admitted that, on account of the
-difference in the constitution of the two sexes, the influence of the
-surrounding conditions would produce a different effect on them, it
-would seem that there is no need whatsoever for the theory of sexual
-selection. What Darwin is probably attempting to show is that the
-material for the further action of sexual selection is already given;
-but the question may well be asked, if the external conditions have done
-so much, why may they not have gone farther and produced the entire
-result?
-
-Darwin makes the following suggestion to account for those cases in
-which the female is the more highly colored:—
-
-“A few exceptional cases occur in various classes of animals, in which
-the females instead of the males have acquired well-pronounced secondary
-sexual characters, such as brighter colors, greater size, strength, or
-pugnacity. With birds there has sometimes been a complete transposition
-of the ordinary characters proper to each sex; the females having become
-the more eager in courtship, the males remaining comparatively passive,
-but apparently selecting the more attractive females, as we may infer
-from the results. Certain hen birds have thus been rendered more highly
-colored or otherwise ornamented, as well as more powerful and pugnacious
-than the cocks; these characters being transmitted to the female
-offspring alone.”
-
-Then follows immediately the discussion as to whether a double process
-of sexual selection may not be supposed to go on at the same time. “It
-may be suggested that in some cases a double process of selection has
-been carried on; that the males have selected the more attractive
-females, and the latter the more attractive males. This process,
-however, though it might lead to the modification of both sexes, would
-not make the one sex different from the other, unless indeed their
-tastes for the beautiful differed; but this is a supposition too
-improbable to be worth considering in the case of any animal, excepting
-man. There are, however, many animals in which the sexes resemble each
-other, both being furnished with the same ornaments, which analogy would
-lead us to attribute to the agency of sexual selection. In such cases it
-may be suggested with more plausibility, that there has been a double or
-mutual process of sexual selection; the more vigorous and precocious
-females selecting the more attractive and vigorous males, the latter
-rejecting all except the more attractive females. But from what we know
-of the habits of animals, this view is hardly probable, for the male is
-generally eager to pair with any female. It is more probable that the
-ornaments common to both sexes were acquired by one sex, generally the
-male, and then transmitted to the offspring of both sexes. If, indeed,
-during a lengthened period the males of any species were greatly to
-exceed the females in number, and then during another lengthened period,
-but under different conditions, the reverse were to occur, a double but
-not simultaneous process of sexual selection might easily be carried on,
-by which the two sexes might be rendered widely different.”
-
-The improbability of such a process is so manifest that the suggestion
-can scarcely be looked upon as anything more than pure speculation. We
-shall have occasion later to return to the same subject, and point out
-its bearing more explicitly.
-
-Nearly the whole animal kingdom is passed in review by Darwin from the
-point of view of the sexual selection theory. There is brought together
-a large number of extremely interesting facts, and if the theory did no
-more than merely hold them together, it has served, in this respect, a
-useful end. We may select some of the most instructive cases by way of
-illustrating the theory.
-
-In many of the lower animals in which the sexes are separated, and these
-alone, of course, can be supposed to come within the range of the
-theory, there are no striking differences between the sexes, in regard
-to ornamentation, although in other respects differences may exist.
-
-“Moreover it is almost certain that these animals have too imperfect
-senses and much too low mental powers, to appreciate each other’s beauty
-or other attractions, or to feel rivalry.
-
-“Hence in these classes or subkingdoms, such as the Protozoa,
-Cœlenterata, Echinodermata, Scolecida, secondary sexual characters, of
-the kind which we have to consider, do not occur; and this fact agrees
-with the belief that such characters in the higher classes have been
-acquired through sexual selection, which depends on the will, desire,
-and choice of either sex.”
-
-There are some cases, however, in which animals low in the scale show a
-difference in the ornamentation of the two sexes. A few cases have been
-recorded in the roundworms, where different shades of the same tint
-distinguish the sexes. In the annelids the sexes are sometimes so
-different, that, as Darwin remarks, they have been placed in different
-genera and even families, “yet the differences do not seem to be of the
-kind which can be safely attributed to sexual selection.” In regard to
-the nemertian worms, although they “vie in variety and beauty of
-coloring with any other group in the invertebrate series,” yet McIntosh
-states that he “cannot discover that these colors are of any service.”
-In the copepods, belonging to the group of lower Crustacea, Darwin
-excludes those cases in which the males alone “are furnished with
-perfect swimming legs, antennæ, and sense-organs; the females being
-destitute of these organs, with their bodies often consisting of a mere
-distorted mass,” because these extraordinary differences between the two
-sexes are no doubt related to their widely different habits of life.
-Nevertheless, it is important to observe that such extreme differences
-may exist in cases where sexual selection cannot come in, because of the
-absence of eyes in the female.
-
-In regard to another copepod, Saphirina, Darwin points out that the
-males are furnished with minute scales, which exhibit beautiful changing
-colors, and these are absent in the females; yet he states that it would
-be extremely rash to conclude that these curious organs serve to attract
-the females. Differences in the sexes are also found in one species of
-Squilla, and a species of Gelasimus. In the latter case Darwin thinks
-that the difference is probably due to sexual selection. In addition to
-these cases, recorded by Darwin, there may be added the two remarkable
-cases, shown in our Figure 2 A, B, of _Calocalanus pavo_, the female of
-which has a gorgeous tail worthy of a peacock, and of _Calocalanus
-plumulosus_, in which one of the setæ of the tail is drawn out into a
-long featherlike structure. In the former, the male is much more
-modestly adorned, as shown in Figure 2 C; in the latter species the male
-is unknown.
-
-
-[Illustration:
-
-  Fig. 2.—A male of the copepod, _Calocalanus plumulosus_.
-  B and C, a male and a female of _Calocalanus pavo_. (After
-    Giesbrecht.)]
-
-
-In spiders, where as a rule the sexes do not differ much from each other
-in color, the males are often of a darker shade than the females. “In
-some species, however, the difference is conspicuous; thus the female of
-_Sparassus smaragdulus_ is dullish green, whilst the adult male has the
-abdomen of a fine yellow with three longitudinal stripes of rich red.”
-Darwin believes that sexual selection must take place in this group,
-because Canestrini has observed that the males fight for the possession
-of the females. He has also stated that the males pay court to the
-female, and that she rejects some of the males who court her, and
-sometimes devours them, until finally one is chosen. Darwin believed, on
-this evidence, that the difference in color of the sexes had been
-acquired by sexual selection, “though we have here not the best kind of
-evidence—the display by the male of his ornaments.” This evidence has,
-however, now been supplied through the interesting observations of Mr.
-and Mrs. Peckham. These accurate observers have studied the courtship of
-the male, and observed that during the process, he twists and turns his
-body in such a way as to show to best advantage his colors to the
-female. From their account this certainly appears to be the result of
-his movements, but whether this is really the case, and whether the
-female makes any choice amongst her suitors, according to whether they
-are more or less brilliantly marked, we are absolutely ignorant. The
-following account given by Darwin should not pass unnoticed:—
-
-“The male is generally much smaller than the female, sometimes to an
-extraordinary degree, and he is forced to be extremely cautious in
-making his advances, as the female often carries her coyness to a
-dangerous pitch. De Geer saw a male that ‘in the midst of his
-preparatory caresses was seized by the object of his attentions,
-enveloped by her in a web and then devoured, a sight which, as he adds,
-filled him with horror and indignation.’ The Rev. O. P. Cambridge
-accounts in the following manner for the extreme smallness of the male
-in the genus Nephila. ‘M. Vinson gives a graphic account of the agile
-way in which the diminutive male escapes from the ferocity of the
-female, by gliding about and playing hide and seek over her body and
-along her gigantic limbs: in such a pursuit it is evident that the
-chances of escape would be in favor of the smallest males, while the
-larger ones would fall early victims; thus gradually a diminutive race
-of males would be selected, until at last they would dwindle to the
-smallest possible size compatible with the exercise of their generative
-functions,—in fact probably to the size we now see them, _i.e._ so small
-as to be a sort of parasite upon the female, and either beneath her
-notice, or too agile and too small for her to catch without great
-difficulty.’”
-
-It is certainly surprising to find Darwin ascribing even this difference
-in size between the sexes to the action of selection. Is it not a little
-ludicrous to suppose that the females have reduced the males to a size
-too small for them to catch?
-
-There are many cases known in the animal kingdom where there is a
-difference in size between the two sexes, especially in the group of
-insects; but I doubt very much if they are to be accounted for as the
-result of sexual selection. In some of these cases Darwin accounts for
-the larger size of the female, on account of the large number of eggs
-which she has to carry. In other insects where the male is larger, as in
-the stag-beetle, the size is ascribed to the conflicts of the males,
-leading to the survival of the larger individuals. In still other cases,
-where the males are larger, but do not fight, an explanation is
-admittedly wanting; but it is suggested that here there would be no
-necessity for the males to be smaller than the females in order to
-mature before them (as is supposed to happen in other species), for in
-these cases the individuals are not short-lived, and there would be
-ample time for pairing. Again, although the males of nearly all bees are
-smaller than the females, yet the reverse is true in those forms in
-which the females are fertilized during the marriage flight. The
-explanation offered is that in these forms the male carries the female,
-and this is assumed to require greater size on his part. This loose way
-of guessing, as to a possible explanation, is characteristic of the
-whole hypothesis of sexual selection. First one, and then another, guess
-is made as to the causes of the differences between the sexes. It is not
-shown in a single one of the instances that the postulated cause has
-really had anything to do with the differences in question; and the
-attempt to show that the theory is probable, by pointing out the large
-number of cases which it appears to account for, is weakened to a very
-great degree by the number of exceptional cases, for which an equally
-ready explanation of a different kind is forthcoming. This way of giving
-loose rein to the imagination has been the bane of the method that has
-followed hard on the track of Darwin’s hypothesis, and for which his
-example has been in no small measure responsible. Thus, in the case just
-quoted, there are no less than four distinct conjectures made to account
-for the differences in size between the sexes, and each guess involves
-an entirely different set of processes. Considering the complicated
-relation of the life of organisms, it may be doubted if any of the
-imagined processes could bring about the result, and certainly not a
-single one has been shown to be a real, or a sufficient, cause in the
-evolutionary process. Neither the actuality of the postulated causes,
-nor their application to a particular case, has been shown to exist.
-
-In the Diptera, or flies, Wallace records one interesting case of sexual
-difference in the genus Elaphomyia of New Guinea, in which the males are
-furnished with horns, which the females lack. Darwin writes:—
-
-“The horns spring from beneath the eyes, and curiously resemble those of
-a stag, being either branched or palmated. In one of the species, they
-equal the whole body in length. They might be thought to be adapted for
-fighting, but as in one species they are of a beautiful pink color,
-edged with black, with a pale central stripe, and as these insects have
-altogether a very elegant appearance, it is perhaps more probable that
-they serve as ornaments.”
-
-Presumably, therefore, Darwin means these colored horns have been
-acquired by sexual selection.
-
-In the Hemiptera, or bugs, both sexes of some species are “beautifully
-colored,” and as the members of the group are often unpalatable to other
-animals, the color in this case is supposed to act as a warning signal.
-
-In other cases it is stated, however, that “a small pink and green
-species” could hardly be distinguished from the buds on the trunks of
-the lime trees which this insect frequents. In this case the color
-appears “to be directly protective.” Thus without any means of forming a
-correct judgment, the color of one animal is supposed to be the result
-of natural selection, since it resembles its surroundings, but of sexual
-selection if the color is present or more pronounced in one sex. Where
-neither view can easily be applied, the color is ascribed in a general
-way to the nature of the organism.
-
-In respect to the group of Hymenoptera, or bees, Darwin records the
-following cases:—
-
-“In this order slight differences in color, according to sex, are
-common, but conspicuous differences are rare except in the family of
-bees; yet both sexes of certain groups are so brilliantly colored—for
-instance in Chrysis, in which vermilion and metallic greens prevail—that
-we are tempted to attribute the result to sexual selection. In the
-Ichneumonidæ, according to Mr. Walsh, the males are almost universally
-lighter-colored than the females. On the other hand, in the
-Tenthredinidæ the males are generally darker than the females. In the
-Siricidæ the sexes frequently differ; thus the male of _Sirex juvencus_
-is banded with orange, whilst the female is dark purple; but it is
-difficult to say which sex is the more ornamented.”
-
-In other families of bees, differences in the color of the sexes have
-been recorded, and since the males have been seen fighting for the
-possession(?) of the females, and since bees are known to recognize
-differences in color, Darwin believes that:—
-
-“In some species the more beautiful males appear to have been selected
-by the females; and in others the more beautiful females by the males.
-Consequently in certain genera, the males of the several species differ
-much in appearance, whilst the females are almost indistinguishable; in
-other genera the reverse occurs. H. Müller believes that the colors
-gained by one sex through sexual selection have often been transferred
-in a variable degree to the other sex, just as the pollen-collecting
-apparatus of the female has often been transferred to the male, to whom
-it is absolutely useless.”
-
-Although in beetles the sexes are generally colored alike, yet in some
-of the longicorns there are exceptions to the rule. “Most of these
-insects are large and splendidly colored. The males in the genus
-Pyrodes, which I saw in Mr. Bates’s collection, are generally redder but
-rather duller than the females, the latter being colored of a more or
-less splendid golden-green. On the other hand, in one species the male
-is golden-green, the female being richly tinted with red and purple. In
-the genus Esmeralda the sexes differ so greatly in color that they have
-been ranked as distinct species; in one species both are of a beautiful
-shining green, but the male has a red thorax. On the whole, as far as I
-could judge, the females of those Prionidæ, in which the sexes differ,
-are colored more richly than the males, and this does not accord with
-the common rule in regard to color, when acquired through sexual
-selection.”
-
-The great horns that rise from the heads of many male beetles are very
-striking cases of sexual difference, and Darwin compares them to the
-horns of stags and of the rhinoceros. They “are wonderful from their
-size and shapes.” Darwin offers the following conjecture as to their
-meaning: “The extraordinary size of the horns, and their widely
-different structure in closely allied forms, indicate that they have
-been formed for some purpose; but their excessive variability in the
-males of the same species leads to the inference that this purpose
-cannot be of a definite nature. The horns do not show marks of friction,
-as if used for any ordinary work. Some authors suppose that as the males
-wander about much more than the females, they require horns as a defence
-against their enemies; but as the horns are often blunt, they do not
-seem well adapted for defence. The most obvious conjecture is that they
-are used by the males for fighting together; but the males have never
-been observed to fight; nor could Mr. Bates, after a careful examination
-of numerous species, find any sufficient evidence, in their mutilated or
-broken condition, of their having been thus used. If the males had been
-habitual fighters, the size of their bodies would probably have been
-increased through sexual selection, so as to have exceeded that of the
-females; but Mr. Bates, after comparing the two sexes in above a hundred
-species of the Copridæ, did not find any marked difference in this
-respect amongst well-developed individuals. In Lethrus, moreover, a
-beetle belonging to the same great division of the lamellicorns, the
-males are known to fight, but are not provided with horns, though their
-mandibles are much larger than those of the female.”
-
-“The conclusion that the horns have been acquired as ornaments is that
-which best agrees with the fact of their having been so immensely, yet
-not fixedly, developed,—as shown by their extreme variability in the
-same species, and by their extreme diversity in closely allied species.
-This view will at first appear extremely improbable; but we shall
-hereafter find with many animals standing much higher in the scale,
-namely fishes, amphibians, reptiles and birds, that various kinds of
-crests, knobs, horns and combs have been developed apparently for this
-sole purpose.”
-
-It is asking a great deal to suppose that animals, so dull and sluggish
-as these beetles, are endowed with a sufficient æsthetic discrimination
-to select in each generation those males whose horns are a little longer
-than the average. The resemblance of the horns to those of stags is, as
-Darwin points out, obvious, but in the latter case also it remains to be
-proven that they are the result of sexual selection, as Darwin believes
-to be the case; but the evidence for this belief is not much better, as
-we shall see in the case of the antlers of deer, than it is in these
-beetles.
-
-In regard to butterflies, the males and females are both often equally
-brilliantly colored; in other species the differences in the sexes are
-very striking. Darwin states:—
-
-“Even within the same genus we often find species presenting
-extraordinary differences between the sexes, whilst others have their
-sexes closely alike.” The fine colors of the wings of many moths are
-also supposed by Darwin to have arisen through sexual selection,
-although the colors are usually on the lower wings, which are covered
-during the day by the less ornamented upper wings. It is assumed that,
-since the moths often begin to fly at dusk, their colors might at this
-time be seen and appreciated by the other sex. It should not be
-overlooked, however, that, in the case of some of the most highly
-colored moths, it is known that the males find the females through the
-sense of smell. Moreover, although moths are often finely colored,
-Darwin points out that “it is a singular fact that no British moths
-which are brilliantly colored, and, as far as I can discover, hardly any
-foreign species, differ much in color according to sex; though this is
-the case with many brilliant butterflies.”
-
-Yet Darwin does not hesitate to conclude: “From the several foregoing
-facts it is impossible to admit that the brilliant colors of
-butterflies, and of some few moths, have commonly been acquired for the
-sake of protection. We have seen that their colors and elegant patterns
-are arranged and exhibited as if for display. Hence I am led to believe
-that the females prefer or are most excited by the more brilliant males;
-for on any other supposition the males would, as far as we can see, be
-ornamented to no purpose. We know that ants and certain lamellicorn
-beetles are capable of feeling an attachment for each other, and that
-ants recognize their fellows after an interval of several months. Hence
-there is no abstract improbability in the Lepidoptera, which probably
-stand nearly or quite as high in the scale as these insects, having
-sufficient mental capacity to admire bright colors. They certainly
-discover flowers by color.”
-
-So far as the evidence of ants having an attachment for each other is
-concerned, we may eliminate this part of the argument, since the
-evidence on which the statement is based is now regarded as only showing
-that ants recognize each other by their sense of smell, which resides in
-the antennæ. Hence the so-called fondling means only that the ants are
-trying by smell to determine the odor of the other individual.
-
-Darwin points out a number of cases in which the females are more
-brightly colored than the males, and for such cases he reverses the
-process of selection, supposing that the males have been discriminating,
-and have not “gladly accepted any female.” No explanation is offered to
-account for this reversal of instinct, in fact, no evidence to show that
-such a reversal really exists. Darwin points out that in most cases the
-male insect carries the female during the period of union, while in two
-species of butterflies, _Colias edusa_ and _hyale_, the females carry
-the males, and the females are here the more highly colored. He suggests
-that since in this case “the females take the more active part in the
-final marriage ceremony, so we may suppose that they likewise do so in
-the wooing; and in this case we can understand how it is that they have
-been rendered the more beautiful.”
-
-A most significant fact in connection with the difference in sexual
-coloration of butterflies did not escape Darwin’s attention.
-
-“Whilst reflecting on the beauty of many butterflies, it occurred to me
-that some caterpillars were splendidly colored; and as sexual selection
-could not possibly have here acted, it appeared rash to attribute the
-beauty of the mature insect to this agency, unless the bright colors of
-their larvæ could be somehow explained. In the first place, it may be
-observed that the colors of caterpillars do not stand in any close
-correlation with those of the mature insect. Secondly, their bright
-colors do not serve in any ordinary manner as a protection. Mr. Bates
-informs me, as an instance of this, that the most conspicuous
-caterpillar which he ever beheld (that of a Sphinx) lived on the large
-green leaves of a tree on the open llanos of South America; it was about
-four inches in length, transversely banded with black and yellow, and
-with its head, legs, and tail of a bright red. Hence it caught the eye
-of any one who passed by, even at the distance of many yards, and no
-doubt that of every passing bird.”
-
-Darwin applied to Wallace for a solution of this difficulty, and
-received the reply that he “thought it probable that conspicuously
-colored caterpillars were protected by having a nauseous taste; but as
-their skin is extremely tender, and as their intestines readily protrude
-from a wound, a slight peck from the beak of a bird would be as fatal to
-them as if they had been devoured. Hence, as Mr. Wallace remarks,
-‘distastefulness alone would be insufficient to protect a caterpillar
-unless some outward sign indicated to its would-be destroyer that its
-prey was a disgusting morsel.’ Under these circumstances it would be
-highly advantageous to a caterpillar to be instantaneously and certainly
-recognized as unpalatable by all birds and other animals. Thus the most
-gaudy colors would be serviceable, and might have been gained by
-variation and the survival of the most easily recognized individuals.”
-
-It need scarcely be pointed out that an occasional peck can scarcely be
-supposed to have led to the splendid development of color shown by some
-caterpillars, and Darwin confesses that at first sight this hypothesis
-appears bold, but nevertheless he believes that it will be found to be
-true. He adds, “We cannot, however, at present thus explain the elegant
-diversity in the colors of many caterpillars.”
-
-A most important fact in this connection should not be overlooked,
-namely, that in the caterpillar stage the sexual organs are so little
-developed that it is generally impossible at this time to distinguish
-between the sexes, unless a microscopic examination is made. This gives
-us, perhaps, a clew as to the difference between the mature sexual
-forms. These differences are connected with difference of sex itself.
-This conclusion also fits in well with the fact that during the period
-when the sexual organs are at the height of their development the
-individuals are most brilliantly colored. The primary cause of the
-brilliant color of many animals concerns us here only secondarily, for,
-since it is known that many of the lower forms are no less brilliantly
-and elaborately colored than are the sexes of the higher forms, it is
-not surprising that the sexes themselves sometimes differ in this
-respect.
-
-Organs for producing sounds of different sorts are present in some
-insects, and these organs Darwin includes under the head of secondary
-sexual organs. In the group of Hemiptera, or bugs, the cicadas are the
-most familiar species that produce sounds. The noise is made by the
-males; the females are quite mute.
-
-“With respect to the object of the music, Dr. Hartman, in speaking of
-the _Cicada septemdecim_ of the United States, says, ‘the drums are now
-(June 6th and 7th, 1851) heard in all directions. This I believe to be
-the marital summons from the males. Standing in thick chestnut sprouts
-about as high as my head, where hundreds were around me, I observed the
-females coming around the drumming males.’ He adds, ‘this season
-(August, 1868) a dwarf pear-tree in my garden produced about fifty larvæ
-of _C. pruinosa_; and I several times noticed the females to alight near
-a male while he was uttering his clanging notes.’ Fritz Müller writes to
-me from S. Brazil that he has often listened to a musical contest
-between two or three males of a species with a particularly loud voice,
-seated at a considerable distance from each other: as soon as one had
-finished his song, another immediately began, and then another. As there
-is so much rivalry between the males, it is probable that the females
-not only find them by their sounds, but that, like female birds, they
-are excited or allured by the male with the most attractive voice.”
-
-In the flies the following cases are given by Darwin:—
-
-“That the males of some Diptera fight together is certain; for Professor
-Westwood has several times seen this with the Tipulæ. The males of other
-Diptera apparently try to win the females by their music: H. Müller
-watched for some time two males of an Eristalis courting a female; they
-hovered above her, and flew from side to side, making a high humming
-noise at the same time. Gnats and mosquitoes (Culicidæ) also seem to
-attract each other by humming; and Professor Mayer has recently
-ascertained that the hairs on the antennæ of the male vibrate in unison
-with the notes of a tuning-fork, within the range of the sounds emitted
-by the female.”
-
-In the crickets, grasshoppers, and locusts, the males “are remarkable
-for their musical powers”; and it is generally assumed that the sounds
-serve to call or to excite the female. In these forms the noise is made
-by rubbing the wings over each other or the legs against the
-wing-covers.
-
-In some of these forms both sexes have stridulating organs, and in one
-case they differ to a certain extent from each other. “Hence we cannot
-suppose that they have been transferred from the male to the female, as
-appears to have been the case with the secondary sexual characters of
-many other animals. They must have been independently developed in the
-two sexes, which no doubt mutually call to each other during the season
-of love.”
-
-Some beetles also possess rasping organs in different parts of the body,
-but they cannot produce much noise by this means.
-
-“We thus see that in the different coleopterous families the
-stridulating organs are wonderfully diversified in position, but not
-much in structure. Within the same family some species are provided with
-these organs, and others are destitute of them. This diversity is
-intelligible, if we suppose that originally various beetles made a
-shuffling or hissing noise by the rubbing together of any hard and rough
-parts of their bodies, which happened to be in contact; and that from
-the noise thus produced being in some way useful, the rough surfaces
-were gradually developed into regular stridulating organs. Some beetles
-as they move, now produce, either intentionally or unintentionally, a
-shuffling noise, without possessing any proper organs for the purpose.”
-
-Darwin says that he expected from analogy to find in this group also
-differences in the sexes, but none such were found, although in some
-cases the males alone possess certain characters or have them more
-highly developed.
-
-It is important not to forget, when considering all questions connected
-with sexual selection, that in order for the result to be successful it
-is not only necessary that the female respond to the noises and music of
-the other sex, but that she choose the suitor that makes the greatest,
-or the most pleasing, noise. If the stridulating organs are only used by
-the animals in finding each other, then the case might be considered as
-coming under the head of natural selection. If this be granted, then it
-may be claimed, and apparently Darwin is inclined to adopt this view,
-that those males that make the most noise will be more likely to be
-heard, and possibly approached. They will, therefore, be more likely to
-leave descendants. We have already considered this question when dealing
-with the theory of natural selection in the preceding chapter and need
-not go over the ground again. This much may, however, be said again,
-that even if it is probable that these organs are of use to the animals
-in finding each other, and this seems not improbable, it does not follow
-that the organs have been acquired through selection for this purpose.
-
-Darwin finds his best examples of secondary sexual characters in the
-group of vertebrates, and since in this group the intelligence is of a
-higher order than in the other groups, the argument that the female
-chooses the more pleasing suitor is made to appear more plausible.
-
-The elongation of the lower jaw that occurs in a few fishes at the
-breeding season is regarded as a secondary sexual character. On the
-other hand, Darwin recognizes the following difficulty in regard to the
-size of the males:—
-
-“In regard to size, M. Carbonnier maintains that the female of almost
-all fishes is larger than the male; and Dr. Günther does not know of a
-single instance in which the male is actually larger than the female.
-With some cyprinodonts the male is not even half as large. As in many
-kinds of fishes the males habitually fight together, it is surprising
-that they have not generally become larger and stronger than the females
-through the effects of sexual selection. The males suffer from their
-small size, for, according to M. Carbonnier, they are liable to be
-devoured by the females of their own species when carnivorous, and no
-doubt by other species. Increased size must be in some manner of more
-importance to the females, than strength and size are to the males for
-fighting with other males; and this perhaps is to allow of the
-production of a vast number of ova.”
-
-The last sentence implies that this particular case is to be explained
-by the females becoming larger on account of the number of eggs that
-they are to produce. But why was not the same explanation offered in the
-case of the spiders? It is this uncertain way of applying any
-explanation that suggests itself, that puts the whole method in an
-unfortunate light.
-
-In many species of fish the males are brighter in color than the
-females. In the case of _Callionymus lyra_, Darwin states:—
-
-“When fresh caught from the sea the body is yellow of various shades,
-striped and spotted with vivid blue on the head; the dorsal fins are
-pale brown with dark longitudinal bands, the ventral, caudal, and anal
-fins being bluish black. The female, or sordid dragonet, was considered
-by Linnæus, and by many subsequent naturalists, as a distinct species;
-it is of a dingy reddish brown, with the dorsal fin brown and the other
-fins white. The sexes differ also in the proportional size of the head
-and mouth, and in the position of the eyes; but the most striking
-difference is the extraordinary elongation in the male of the dorsal
-fin. Mr. W. Saville Kent remarks that this ‘singular appendage appears
-from my observations of the species in confinement, to be subservient to
-the same end as the wattles, crests, and other abnormal adjuncts of the
-male in gallinaceous birds, for the purpose of fascinating their
-mates.’”
-
-In the case of another fish, _Cottus scorpius_, there is also a great
-difference between the sexes, and here the males become very brilliant
-only at the breeding season. In other fishes, in which the sexes are
-colored alike, the males may become more brilliant during the breeding
-season. This, too, is explained by Darwin on the assumption that those
-males that have varied at the breeding season, so as to become more
-brightly colored, have been chosen in preference to the other males.
-
-A few cases are cited in which it has been observed that the males
-appear to exhibit themselves before the females, as in the following
-case of the Chinese Macropus:—
-
-“The males are most beautifully colored, more so than the females.
-During the breeding season they contend for the possession of the
-females; and, in the act of courtship, expand their fins, which are
-spotted and ornamented with brightly colored rays, in the same manner,
-according to M. Carbonnier, as the peacock. They then also bound about
-the females with much vivacity, and appear by ‘l’étalage de leurs vives
-couleurs chercher à attirer l’attention des femelles, lesquelles ne
-paraissaient indifférentes à ce manége, elles nageaient avec une molle
-lenteur vers les mâles et semblaient se complaire dans leur voisinage.’”
-
-In this connection Darwin makes the following general statement:—
-
-“The males sedulously court the females, and in one case, as we have
-seen, take pains in displaying their beauty before them. Can it be
-believed that they would thus act to no purpose during their courtship?
-And this would be the case, unless the females exert some choice and
-select those males which please or excite them most. If the female
-exerts such choice, all the above facts on the ornamentation of the
-males become at once intelligible by the aid of sexual selection.”
-
-While it may readily be granted that display of the male may have for
-its purpose the excitement of the female, it is another question as to
-whether she will be more excited by the more beautiful suitor. The
-attentions of the male may be supposed to have a purpose, even if the
-female does not choose the more beautiful of her suitors. It is this
-last proposition, so necessary for the theory of sexual selection, that
-seems improbable. But even if it were probable, there are, as we shall
-see, other difficulties to be overcome before we should be justified in
-accepting Darwin’s statement quoted above, concerning the results of
-sexual selection.
-
-In regard to those species of fish in which both sexes are equally
-ornamented, Darwin returns once more to his hypothesis that the color of
-the male, acquired through sexual selection, may be transmitted to the
-other sex, and then, as if in doubt on this point, he adds, that it may
-be the result of the “nature of the tissues and of the surrounding
-conditions.” He even makes the suggestion, somewhat further on, that the
-colors may be warning, although it is confessedly unknown that these
-fish are distasteful to fish-devouring animals.
-
-In amphibians the crest on the back of the male triton, which becomes
-colored along its edge, is described as a secondary sexual character.
-The vocal sacs, present in some species of frogs, are found sometimes in
-both sexes, but more highly developed in the males. In other species, as
-in the toad, it is the male alone that sings. In the reptiles we find
-that the two sexes of the turtles are colored alike, and this holds also
-for the crocodiles. Some male turtles make sounds at the breeding
-season, and the same is true for the crocodiles, the males of which are
-said to make a “prodigous display.” In snakes the males are smaller, as
-a rule, than the females, and the colors are more strongly pronounced,
-and although some snakes are very brilliantly colored, Darwin puts this
-down either to protective coloration, or to mimicry of other kinds of
-snakes. But surely the extremely brilliant colors of many snakes cannot
-be accounted for in any of these ways. The cause of the color of the
-venomous kinds, that are supposed to be imitated by the others, “remains
-to be explained and this may perhaps be sexual selection.”
-
-“It does not, however, follow because snakes have some reasoning power,
-strong passions and mutual affection, that they should likewise be
-endowed with sufficient taste to admire brilliant colors in their
-partners, so as to lead to the adornment of the species through sexual
-selection. Nevertheless, it is difficult to account in any other manner
-for the extreme beauty of certain species; for instance, of the
-coral-snakes of South America, which are of a rich red with black and
-yellow transverse bands.”
-
-In lizards the erectile crests of the male _Anolis_, the brilliant
-throat patches of _Sitaria minor_, which is colored blue, black, and
-red, the skinny appendages present on the throat of the little lizards
-of the genus Draco, which in the beauty of their colors baffle
-description, are given as cases of sexual adornment. In the last case
-cited the ornaments are present, however, in both sexes. The remarkable
-horns in the males of different species of chameleons are imagined to
-have been acquired through the battle of the males with each other.
-
-In the group of birds we find some of the most striking cases of
-secondary sexual differences. The spurs, combs, wattles, horns,
-air-filled sacs, topknots, feathers with naked shafts, plumes, and
-greatly elongated feathers are all secondary sexual characters. The
-songs of the males, the rattling together of the quills of the peacock,
-the drumming of the grouse, and the booming sounds made by the night
-jars while on the wing, are further examples of secondary sexual
-differences. The odor of the male of the Australian musk duck is also
-put in the same category.
-
-The pugnacity of many male birds is well known, and it is imagined that
-one of the results of the competition of the individuals of the same sex
-with each other has led to the development of the organs of defence and
-offence. The males that have been successful in these battles are then
-supposed to mate with the best females. In this way those secondary
-sexual differences, connected with the encounters of the males, are
-supposed to have been formed. Darwin states in this connection:—
-
-“Even with the most pugnacious species it is probable that the pairing
-does not depend exclusively on the mere strength and courage of the
-male; for such males are generally decorated with various ornaments,
-which often become more brilliant during the breeding season, and which
-are sedulously displayed before the females. The males also endeavor to
-charm or excite their mates by love-notes, songs, and antics; and the
-courtship is, in many instances, a prolonged affair. Hence it is not
-probable that the females are indifferent to the charms of the opposite
-sex, or that they are invariably compelled to yield to the victorious
-males.”
-
-Thus a double process of selection is imagined to take place; one, the
-outcome of a competition of the males with each other, and the other,
-through a choice of the more successful males by the females, the more
-beautiful being supposed to be chosen.
-
-It may be well not to lose sight of the fact that unless the selection
-is severe in each generation, its good effects will be lost, as has been
-stated in connection with the theory of natural selection. Still more
-important is the consideration that unless the same variations appear at
-the same time, in many of the surviving males, the results will be lost
-through crossing. These statements will show that the difficulties of
-the theory are by no means small, and when we are asked to believe
-further that another process still has been superimposed on this one,
-namely, the selection of the more beautiful males by the females, we can
-appreciate how great are the difficulties that must be overcome in order
-that the process may be carried out.
-
-The love-antics and dances of male birds at the breeding season furnish
-many curious data. The phenomena are imagined by Darwin to be connected
-with sexual selection, for in the dances the males are supposed to
-exhibit their ornaments to the females who are imagined to choose the
-suitor that is most to their taste.
-
-Hudson, who has studied the habits of birds in the field, asks some very
-pertinent questions in connection with their performances of different
-kinds. “What relation that we can see or imagine to the passion of love
-and the business of courtship have these dancing and vocal performances
-in nine cases out of ten? In such cases, for instance, as that of the
-scissortail tyrant-bird, and its pyrotechnic displays, when a number of
-couples leave their nests containing eggs and young to join in a wild
-aërial dance; the mad exhibitions of ypecahas and ibises and the
-jacana’s beautiful exhibition of grouped wings; the triplet dances of
-the spur-winged lapwing, to perform which two birds already mated are
-compelled to call in a third bird to complete the set; the harmonious
-duets of the oven-birds and the duets and choruses of nearly all the
-wood-hewers, and the wing-slapping aërial displays of the whistling
-widgeons,—will it be seriously contended that the female of this species
-makes choice of the male able to administer the most vigorous and
-artistic slaps?”
-
-“The believer in the theory would put all these cases lightly aside to
-cite the case of the male cow-bird practising antics before the female,
-and drawing a wide circle of melody around her, etc.... And this was in
-substance what Darwin did.” “How unfair the argument is based on these
-carefully selected cases gathered from all regions of the globe and
-often not properly reported is seen when we turn to the book of nature
-and closely consider the habits and actions of all the species
-inhabiting any _one_ district.” Hudson concludes that he is convinced
-that any one who will note the actions of animals for himself will reach
-the conviction, that “conscious sexual selection on the part of the
-female is not the cause of music and dancing performances in birds, nor
-of the brighter colors and ornaments that distinguish the male.”
-
-The differences in color in the sexes of birds are classified by Darwin
-as follows: (1) when the males are ornamented exclusively or in a much
-higher degree than the females; (2) when both sexes are highly
-ornamented; (3) when the female is more brightly colored. A few examples
-of each sort may be chosen for illustration.
-
-“In regard to color, hardly anything need here be said, for every one
-knows how splendid are the tints of many birds, and how harmoniously
-they are combined. The colors are often metallic and iridescent.
-Circular spots are sometimes surrounded by one or more differently
-shaded zones, and are thus converted into ocelli. Nor need much be said
-on the wonderful difference between the sexes of many birds. The common
-peacock offers a striking instance. Female birds of paradise are
-obscurely colored and destitute of all ornaments, whilst the males are
-probably the most highly decorated of all birds, and in so many
-different ways, that they must be seen to be appreciated. The elongated
-and golden-orange plumes which spring from beneath the wings of the
-_Paradisea apoda_, when vertically erected and made to vibrate, are
-described as forming a sort of halo, in the centre of which the head
-‘looks like a little emerald sun, with its rays formed by the two
-plumes.’”
-
-Male humming-birds are almost as splendidly colored as are the birds of
-paradise, some having the feathers modified in a truly extraordinary
-way. “Almost every part of their plumage has been taken advantage of,
-and modified; and the modifications have been carried, as Mr. Gould
-showed me, to a wonderful extreme in some species belonging to nearly
-every subgroup. Such cases are curiously like those which we see in our
-fancy breeds, reared by man for the sake of ornament: certain
-individuals originally varied in one character, and other individuals of
-the same species in other characters; and these have been seized on by
-man and much augmented—as shown by the tail of the fantail pigeon, the
-hood of the jacobin, the beak and wattle of the carrier, and so forth.
-The sole difference between these cases is that in the one the result is
-due to man’s selection, whilst in the other, as with humming-birds,
-birds of paradise, etc., it is due to the selection by the females of
-the more beautiful males.”
-
-A remarkable bird of South America, the bell-bird, has a peculiar note
-that “can be distinguished at the distance of nearly three miles and
-astonishes every one who hears it.... The male is pure white, whilst the
-female is dusky-green; and white is a very rare color in terrestrial
-species of moderate size and inoffensive habits. The male, also, as
-described by Waterton, has a spiral tube, nearly three inches in length,
-which rises from the base of the beak. It is jet-black, dotted over with
-minute downy feathers. This tube can be inflated with air, through a
-communication with the palate; and when not inflated hangs down on one
-side. The genus consists of four species, the males of which are very
-distinct, whilst the females, as described by Mr. Sclater in a very
-interesting paper, closely resemble each other, thus offering an
-excellent instance of the common rule that within the same group the
-males differ much more from each other than do the females. In a second
-species (_C. nudicollis_) the male is likewise snow-white, with the
-exception of a large space of naked skin on the throat and round the
-eyes, which during the breeding season is of a fine green color. In a
-third species (_C. tricarunculatus_) the head and neck alone of the male
-are white, the rest of the body being chestnut-brown, and the male of
-this species is provided with three filamentous projections half as long
-as the body—one rising from the base of the beak, and the two others
-from the corners of the mouth.”
-
-The most familiar case of sexual difference amongst North American birds
-is that of the scarlet tanager, in which the male is scarlet with
-jet-black wings, while the female is an inconspicuous yellow-green
-color. Amongst domesticated animals the peafowl shows the most beautiful
-case of sexual differences. The magnificent tail of the male can be
-lifted up, so as to be seen to best advantage when the male faces the
-observer. Moreover the wild form, living in the forests of India, has
-the same gorgeous train.
-
-The male Argus pheasant has a remarkable series of spots, or ocelli, on
-the secondary wing-covers. They are concealed until the male displays
-them before the female. Darwin states that, while it may seem incredible
-that such elegant shading and exquisite patterns could have been the
-outcome of the taste of the female, yet the extraordinary attitude
-assumed by the male during courtship appears entirely purposeless,
-unless it be supposed that he is attempting to charm the female by a
-display of his ornamentation.
-
-Let us pass to the second class of cases, in which both sexes are
-similarly and brightly colored, and in which the young have a plumage
-different from the adults. For example, the male and the female of the
-splendid scarlet ibis are alike, whilst the young are brown. The males
-and females of many finely colored herons are ornamented alike, and this
-plumage, Darwin admits, has a nuptial character. He even tries to
-explain this by the curious assumption, that while the color has been
-acquired through the selection of the males by the females, the results
-attained in this way have been transmitted to both sexes. We find here
-another example of the method so often employed by Darwin. When he meets
-with facts that are not in conformity with the theory, he proceeds to
-make a new assumption without establishing its validity. Thus, to assume
-that in all cases where the sexes are colored differently, the
-characters acquired by the males have been transmitted only to the same
-sex, and in those cases where the sexes are colored alike the
-transmission has been to both sexes, is most arbitrary.
-
-In other cases, which are commoner than the last, the male and female
-have the same color, and the young in their first plumage resemble the
-adults. Darwin admits that here the facts are so complex that his
-conclusions are doubtful. The following account of the tree-sparrow
-shows how vague are the principles involved in the entire discussion in
-relation to transmission:—
-
-“Now with the tree-sparrow (_P. montanus_) both sexes and the young
-closely resemble the male of the house-sparrow; so that they have all
-been modified in the same manner, and all depart from the typical
-coloring of their early progenitor. This may have been effected by a
-male ancestor of the tree-sparrow having varied, firstly, when nearly
-mature; or secondly, whilst quite young, and by having in either case
-transmitted his modified plumage to the females and the young; or,
-thirdly, he may have varied when adult and transmitted his plumage to
-both adult sexes, and, owing to the failure of the law of inheritance at
-corresponding ages, at some subsequent period to his young.”
-
-The further admissions made in the following quotation are also
-significant:—
-
-“The plumage of certain birds goes on increasing in beauty during many
-years after they are fully mature; this is the case with the train of
-the peacock, with some of the birds of paradise, and with the crest and
-plumes of certain herons, for instance, the _Ardea ludovicana_. But it
-is doubtful whether the continued development of such feathers is the
-result of the selection of successive beneficial variations (though this
-is the most probable view with birds of paradise) or merely of
-continuous growth. Most fishes continue increasing in size, as long as
-they are in good health and have plenty of food; and a somewhat similar
-law may prevail with the plumes of birds.”
-
-We need not follow Darwin through his discussion of those cases in which
-the adults have a winter and a summer dress and the young resemble the
-one or the other in plumage, or are different from either. The
-discussion of these cases, confessedly very complex, adds nothing to our
-understanding of the theory, and little but conjecture is offered to
-account for the facts.
-
-The extreme to which even conjecture can be carried may be gathered from
-the following quotation, taken from the section dealing with cases in
-which the young in their first plumage differ from each other according
-to sex, the young males resembling more or less closely the adult males,
-and the young females more or less closely the adult females:
-
-“Two humming-birds belonging to the genus Eustephanus, both beautifully
-colored, inhabit the small island of Juan Fernandez, and have always
-been ranked as specifically distinct. But it has lately been ascertained
-that the one which is of a rich chestnut-brown color with a golden-red
-head, is the male, whilst the other, which is elegantly variegated with
-green and white with a metallic-green head, is the female. Now the young
-from the first somewhat resemble the adults of the corresponding sex,
-the resemblance gradually becoming more and more complete.
-
-“In considering this last case, if as before we take the plumage of the
-young as our guide, it would appear that both sexes have been rendered
-beautiful independently; and not that one sex has partially transferred
-its beauty to the other. The male apparently has acquired his bright
-colors through sexual selection in the same manner as, for instance, the
-peacock or pheasant in our first class of cases; and the female in the
-same manner as the female Rhynchæa or Turnix in our second class of
-cases. But there is much difficulty in understanding how this could have
-been effected at the same time with the two sexes of the same species.
-Mr. Salvin states, as we have seen in the eighth chapter, that with
-certain humming-birds the males greatly exceed the females in number,
-whilst with other species inhabiting the same country the females
-greatly exceed the males. If, then, we might assume that during some
-former lengthened period the males of the Juan Fernandez species had
-greatly exceeded the females in number, but that during another
-lengthened period the females had far exceeded the males, we could
-understand how the males at one time, and the females at another, might
-have been rendered beautiful by the selection of the brighter-colored
-individuals of either sex; both sexes transmitting their characters to
-their young at a rather earlier age than usual. Whether this is the true
-explanation I will not pretend to say; but the case is too remarkable to
-be passed over without notice.”
-
-The third group of cases include those in which the females are more
-brightly colored, or more ornamented, than the males. These cases are
-rare, and the differences between the sexes are never so great as when
-the male is the more highly colored. Wallace thinks that since in these
-cases the male incubates the eggs his less conspicuous colors have been
-acquired through natural selection. In the genus Turnix the female is
-larger than the male, and lacks the black on the throat and neck, and
-the plumage as a whole is lighter than that of the male. The natives
-assert that the females after laying their eggs associate in flocks, and
-leave the males to do the incubating; and from other evidence Darwin
-thinks that this is true.
-
-In three species of painted snipe the females “are not only larger but
-much more richly colored than the males,” and the trachea is more
-convoluted in some species. “There is also reason to believe that the
-male undertakes the duty of incubation.” In the dotterel plover the
-female is larger and somewhat more strongly colored. The males take at
-least a share in the incubation. In the common cassowary the female is
-larger and the skin of the head more brightly colored than in the male.
-The female is pugnacious during the breeding season and the male sits on
-the eggs. The female emu is large and has a crest. She is more
-courageous and pugilistic and makes a deep, hollow, guttural boom. The
-male is more docile and can only hiss or croak. He not only incubates
-the eggs, but defends the young against their own mother. “So that with
-this emu we have a complete reversal not only of the parental and
-incubating instincts, but of the usual moral qualities of the two sexes;
-the females being savage, quarrelsome, and noisy, the males gentle and
-good. The case is very different with the African ostrich, for the male
-is somewhat larger than the female and has finer plumes with more
-strongly contrasted colors; nevertheless he undertakes the whole duty of
-incubation.”
-
-Darwin attempts to explain these reversals of instincts on the
-assumption that the males have turned the tables on the females, and
-have themselves done the selecting; and incidentally, it may be pointed
-out in passing, they have had to pay the penalty by incubating the eggs.
-
-In the group of mammals, Darwin thinks that the male wins the female by
-conquering other males rather than by charming her through his display.
-The males, even when unarmed, engage in desperate conflicts with each
-other, and sometimes kill, but more often only wound, their fellows. The
-secondary sexual characters of the males have been acquired, therefore,
-by natural selection applied to one sex, and less frequently through the
-choice of the female. Since we are here more especially concerned with
-the latter class of phenomena, we may examine only a few cases under the
-first head.
-
-The horns of stags are used by them in their conflicts with each other;
-the tusks of the elephant make this animal the most dangerous in the
-world, when in must. The horns of bulls, the canine teeth of many
-mammals, the tusks of the walrus, are further examples of organs which
-have been, according to Darwin, acquired through the competitions of the
-males with each other.
-
-The voices of mammals are used for various purposes, “as a signal of
-danger, as a call from one member of the troup to another, and from the
-mother to her lost offspring, or from the latter for protection.”
-
-“Almost all male animals use their voices much more during the rutting
-season than at any other time; and some, as the giraffe and porcupine,
-are said to be completely mute excepting at this season. As the throats
-(_i.e._ the larynx and thyroid bodies) of stags periodically become
-enlarged at the beginning of the breeding season, it might be thought
-that their powerful voices must be somehow of high importance to them;
-but this is very doubtful. From information given to me by two
-experienced observers, Mr. McNeill and Sir P. Egerton, it seems that
-young stags under three years old do not roar or bellow; and that the
-old ones begin bellowing at the commencement of the breeding season, at
-first only occasionally and moderately, whilst they restlessly wander
-about in search of the females. Their battles are prefaced by loud and
-prolonged bellowing, but during the actual conflict they are silent.
-Animals of all kinds which habitually use their voices utter various
-noises under any strong emotion, as when enraged and preparing to fight;
-but this may merely be the result of nervous excitement, which leads to
-the spasmodic contraction of almost all the muscles of the body, as when
-a man grinds his teeth and clenches his fists in rage or agony. No doubt
-stags challenge each other to mortal combat by bellowing; but those with
-the more powerful voices, unless at the same time the stronger,
-better-armed, and more courageous, would not gain any advantage over
-their rivals.”
-
-“Some writers suggest that the bellowing serves as a call to the female;
-but the experienced observers above quoted inform me that female deer do
-not search for the male, though the males search eagerly for the
-females, as indeed might be expected from what we know of the habits of
-other male quadrupeds. The voice of the female, on the other hand,
-quickly brings to her one or more stags, as is well known to the hunters
-who in wild countries imitate her cry.
-
-“As the case stands, the loud voice of the stag during the breeding
-season does not seem to be of any special service to him, either during
-his courtship or battles, or in any other way. But may we not believe
-that the frequent use of the voice, under the strong excitement of love,
-jealousy, and rage, continued during many generations, may at last have
-produced an inherited effect on the vocal organs of the stag, as well as
-of other male animals? This appears to me, in our present state of
-knowledge, the most probable view.”
-
-Here once more we find that Darwin makes use, as a sort of last resort,
-of the principle of the inheritance of acquired characters. As long as
-the theory of selection, in any of its forms, appears to offer a
-satisfactory solution, we find the facts used in support of this theory,
-but as soon as a difficulty arises the Lamarckian theory is brought to
-the front. It is this shifting, as we have already more than once
-pointed out, that shows how little real basis there is for the theory of
-sexual selection.
-
-The male gorilla has a tremendous voice, and he has, as has also the
-orang, a laryngeal sac. One species of gibbon has the power of producing
-a correct octave of musical notes.
-
-“The vocal organs of the American _Mycetes caraya_ are one-third larger
-in the male than in the female, and are wonderfully powerful. These
-monkeys in warm weather make the forests resound at morning and evening
-with their overwhelming voices. The males begin the dreadful concert,
-and often continue it during many hours, the females sometimes joining
-in with their less powerful voices. An excellent observer, Rengger,
-could not perceive that they were excited to begin by any special cause;
-he thinks that, like many birds, they delight in their own music, and
-try to excel each other. Whether most of the foregoing monkeys have
-acquired their powerful voices in order to beat their rivals and charm
-the females—or whether the vocal organs have been strengthened and
-enlarged through the inherited effects of long-continued use without any
-particular good being thus gained—I will not pretend to say; but the
-former view, at least in the case of the _Hylobates agilis_, seems the
-most probable.”
-
-The odor of some mammals is confined to, or more developed, in the
-males; but in some forms, as in the skunk, it is present in both sexes.
-In the shrew mice, abdominal scent glands are present, but since these
-mice are rejected by birds of prey, their glands probably serve to
-protect them; “nevertheless the glands become enlarged in the males
-during the breeding season.” In many other quadrupeds the scent glands
-are of the same size in both sexes, and their function is unknown.
-
-“In other species the glands are confined to the males, or are more
-developed than in the females; and they almost always become more active
-during the rutting season. At this period the glands on the sides of the
-face of the male elephant enlarge, and emit a secretion having a strong
-musky odor. The males, and rarely the females, of many kinds of bats
-have glands and protrudable sacs situated in various parts; and it is
-believed that these are odoriferous.
-
-“The rank effluvium of the male goat is well known, and that of certain
-male deer is wonderfully strong and persistent. Besides the general
-odor, permeating the whole body of certain ruminants (for instance, _Bos
-moschatus_) in the breeding season, many deer, antelopes, sheep, and
-goats, possess odoriferous glands in various situations, more especially
-on their faces. The so-called tear-sacs, or suborbital pits, come under
-this head. These glands secrete a semifluid fetid matter which is
-sometimes so copious as to stain the whole face, as I have myself seen
-in an antelope. They are ‘usually larger in the male than in the female,
-and their development is checked by castration.’ According to Desmarest
-they are altogether absent in the female of _Antilope subgutturosa_.
-Hence, there can be no doubt that they stand in close relation with the
-reproductive functions. They are also sometimes present, and sometimes
-absent, in nearly allied forms. In the adult male musk-deer (_Moschus
-moschiferus_), a naked space round the tail is bedewed with an
-odoriferous fluid, whilst in the adult female and in the male until two
-years old, this space is covered with hair, and is not odoriferous.”
-Darwin believes in these cases that the odor serves to attract the
-females. He admits that here, “active and long-continued use cannot have
-come into play as in the case of the vocal organs.” He concludes,
-therefore, that “the odor emitted must be of considerable importance to
-the male, inasmuch as large and complex glands, furnished with muscles
-for everting the sac, and for closing or opening the orifice, have in
-some cases been developed. The development of these organs is
-intelligible through sexual selection, if the most odoriferous males are
-the most successful in winning the females, and in leaving offspring to
-inherit their gradually perfected glands and colors.”
-
-There is sometimes a difference in the mammals in the hair of the two
-sexes both in amount and in color. In some species of goats the males
-have a beard, in others it is present in both sexes. The bull, but not
-the cow, has curly hair on the forehead. In some monkeys the beard is
-confined to the male, as in the orang; in other species it is only
-larger in the males.
-
-“The males of various members of the ox family (Bovidæ), and of certain
-antelopes, are furnished with a dewlap, or great fold of skin on the
-neck, which is much less developed in the female.
-
-“Now, what must we conclude with respect to such sexual differences as
-these? No one will pretend that the beards of certain male goats, or the
-dewlap of the bull, or the crests of hair along the backs of certain
-male antelopes, are of any use to them in their ordinary habits.
-
-“Must we attribute all these appendages of hair or skin to mere
-purposeless variability in the male? It cannot be denied that this is
-possible; for in many domesticated quadrupeds, certain characters,
-apparently not derived through reversion from any wild parent form, are
-confined to the males, or are more developed in them than in the
-females—for instance, the hump on the male zebu cattle of India, the
-tail of fat-tailed rams, the arched outline of the forehead in the males
-of several breeds of sheep, and, lastly, the mane, the long hairs on the
-hind-legs, and the dewlap of the male of the Berbura goat.”
-
-In these cases and in others that Darwin cites, which seem clearly to
-indicate that some of these secondary sexual characters are not the
-result of sexual selection, he concludes, “that they must be due to
-simple variability, together with sexually limited inheritance.
-
-“Hence it appears reasonable to extend this same view to all analogous
-cases with animals in a state of nature. Nevertheless I cannot persuade
-myself that it generally holds good, as in the case of the extraordinary
-development of hair on the throat and fore-legs of the male Ammotragus,
-or in that of the immense beard of the male Pithecia. Such study as I
-have been able to give to nature makes me believe that parts or organs
-which are highly developed, were acquired at some period for a special
-purpose. With those antelopes in which the adult male is more strongly
-colored than the female, and with those monkeys in which the hair on the
-face is elegantly arranged and colored in a diversified manner, it seems
-probable that the crests and tufts of hair were gained as ornaments; and
-this I know is the opinion of some naturalists. If this be correct,
-there can be little doubt that they were gained, or at least modified
-through sexual selection; but how far the same view may be extended to
-other mammals is doubtful.”
-
-The astonishing colors in some of the monkeys cannot be passed over
-without comment.
-
-“In the beautiful _Cercopithecus diana_, the head of the adult male is
-of an intense black, whilst that of the female is dark gray; in the
-former the fur between the thighs is of an elegant fawn-color, in the
-latter it is paler.
-
-“In the _Cercopithecus cynosurus_ and _griseoviridis_ one part of the
-body, which is confined to the male sex, is of the most brilliant blue
-or green, and contrasts strikingly with the naked skin on the hinder
-part of the body, which is vivid red.
-
-“Lastly, in the baboon family, the adult male of _Cynocephalus
-hamadryas_ differs from the female not only by his immense mane, but
-slightly in the color of the hair and of the naked callosities. In the
-drill (_C. leucophæus_) the females and young are much paler-colored,
-with less green, than the adult males. No other member in the whole
-class of mammals is colored in so extraordinary a manner as the adult
-male mandrill (_C. mormon_). The face at this age becomes of a fine
-blue, with the ridge and tip of the nose of the most brilliant red.
-According to some authors, the face is also marked with whitish stripes,
-and is shaded in parts with black, but the colors appear to be variable.
-On the forehead there is a crest of hair, and on the chin a yellow
-beard. ‘Toutes les parties supérieures de leurs cuisses et le grand
-espace nu de leurs fesses sont également colorés du rouge le plus vif,
-avec un mélange de bleu qui ne manque réellement pas d’élégance.’ When
-the animal is excited all the naked parts become much more vividly
-tinted.”
-
-Darwin sums up the evidence in regard to the differences in color
-between the male and female in the following statement:—
-
-“I have now given all the cases known to me of a difference in color
-between the sexes of mammals. Some of these may be the result of
-variations confined to one sex and transmitted to the same sex, without
-any good being gained, and therefore without the aid of selection. We
-have instances of this with our domesticated animals, as in the males of
-certain cats being rusty-red, whilst the females are tortoise-shell
-colored. Analogous cases occur in nature: Mr. Bartlett has seen many
-black varieties of the jaguar, leopard, vulpine phalanger, and wombat;
-and he is certain that all or nearly all these animals, were males. On
-the other hand, with wolves, foxes, and apparently American squirrels,
-both sexes are occasionally born black. Hence it is quite possible that
-with some mammals a difference in color between the sexes, especially
-when this is congenital, may simply be the result, without the aid of
-selection, of the occurrence of one or more variations, which from the
-first were sexually limited in their transmission. Nevertheless it is
-improbable that the diversified, vivid, and contrasted colors of certain
-quadrupeds, for instance, of the above monkeys and antelopes, can thus
-be accounted for.”
-
-Finally, the case of man must be considered from the point of view of
-sexual selection, for Darwin claims that man has acquired a number of
-his secondary sexual characters in this way. For instance, the beard is
-an excellent case of a secondary sexual character. Darwin’s
-interpretation is that the beard has been retained, or even developed,
-through the selection by the females of those males that had this
-outgrowth best developed. Conversely, the absence of hair on the face of
-the female is supposed by Darwin to have been brought about by men
-selecting those women having less hair on their faces. The greater
-intellect, energy, courage, pugnacity, and size of man are the outcome
-of the competition of the males with each other, since the individual
-excelling in these qualities will be able to select the most desirable
-wife, or wives, and it is assumed will, therefore, leave more
-descendants. The standard of beauty has been kept up by men selecting
-the most beautiful women in each generation (the fate of the other
-married women is ignored), and this beauty is supposed to have been
-transmitted primarily to their daughters, but also to their sons.
-
-Although all these forms of selection are imagined to be acting in man,
-either alternately or simultaneously, yet Darwin recognizes in man a
-number of checks to the action of sexual selection: amongst savages, the
-so-called communal marriages; second, infanticide, generally of the
-young females, which appears in some races to be practised to an
-astonishing degree; third, early betrothals; fourth, the holding of
-women as slaves.
-
-When we recall that selection to be effective can only be carried out
-under very exacting conditions, we cannot but be appalled at the demands
-made here on our credulity. The choice of the women has produced the
-beard of man, the choice of man the absence of a beard in women; the
-competition of the males with each other is leading at the same time to
-the development of at least half a dozen qualities that are supposed to
-be male specialities, and while all this is going on the results are
-being checked sometimes by one means, sometimes by another. Moreover,
-even this is not all that we are asked to accept, for there are several
-other qualities of the male that are put down as secondary sexual
-characters. For example, let us examine what Darwin has to say in regard
-to the development of the voice, and of singing in man.
-
-In man the vocal cords are about a third longer than in woman and his
-voice deeper. Emasculation arrests the development of the vocal
-apparatus, and the voice remains like that of a woman. This difference
-between the sexes, Darwin thinks, is due probably to long-continued use
-by the male “under the excitement of love, rage, and jealousy.” In other
-words, an appeal is again made to the Lamarckian theory, and in this
-case to explain the origin of an organ that conforms to all the
-requirements of the secondary sexual characters.
-
-“The capacity and love for singing, or music, though not a sexual
-character in man,” in the sense of being confined to one sex, yet is
-supposed to have arisen through sexual selection in the following way:
-“Human song is generally admitted to be the basis or origin of
-instrumental music. As neither the enjoyment nor the capacity of
-producing musical notes are faculties of the least use to man in
-reference to his daily habits of life, they must be ranked amongst the
-most mysterious with which he is endowed.”
-
-Man is supposed to have possessed this faculty of song from a very
-remote time, and even the most savage races make musical sounds,
-although we do not enjoy their music, or they ours.
-
-“We see that the musical faculties, which are not wholly deficient in
-any race, are capable of prompt and high development, for Hottentots and
-Negroes have become excellent musicians, although in their native
-countries they rarely practise anything that we should consider music.
-Hence the capacity for high musical development, which the savage races
-of man possess, may be due either to the practice by our semi-human
-progenitors of some rude form of music, or simply to their having
-acquired the proper vocal organs for a different purpose. But in this
-latter case we must assume, as in the above instance of parrots, and as
-seems to occur with many animals, that they already possessed some sense
-of melody.”
-
-Darwin sums up the evidence in the two following statements, the
-insufficiency of which to explain the phenomena is I think only too
-obvious: “All these facts in respect to music and impassioned speech
-become intelligible to a certain extent, if we assume that musical tones
-and rhythm were used by our half-human ancestors, during the season of
-courtship, when animals of all kinds are excited not only by love, but
-by the strong passions of jealousy, rivalry, and triumph. From the
-deeply laid principle of inherited associations, musical tones in this
-case would be likely to call up vaguely and indefinitely the strong
-emotions of a long past age.” Thus the difficulty is shifted to the
-shoulders of our long-lost savage ancestors; or even, in fact, to our
-simian forefathers, as the following paragraph indicates:—
-
-“As the males of several quadrumanous animals have their vocal organs
-much more developed than in the females, and as a gibbon, one of the
-anthropomorphous apes, pours forth a whole octave of musical notes and
-may be said to sing, it appears probable that the progenitors of man,
-either the males or females or both sexes, before acquiring the power of
-expressing their mutual love in articulate language, endeavored to charm
-each other with musical notes and rhythm. So little is known about the
-use of the voice by the Quadrumana during the season of love, that we
-have no means of judging whether the habit of singing was first acquired
-by our male or female ancestors. Women are generally thought to possess
-sweeter voices than men, and as far as this serves as any guide, we may
-infer that they first acquired musical powers in order to attract the
-other sex. But if so, this must have occurred long ago, before our
-ancestors had become sufficiently human to treat and value their women
-merely as useful slaves. The impassioned orator, bard, or musician, when
-with his varied tones and cadences he excites the strongest emotions in
-his hearers, little suspects that he uses the same means by which his
-half-human ancestors long ago aroused each other’s ardent passions
-during their courtship and rivalry.”
-
-We have now examined in some detail the evidence that Darwin has brought
-forward in support of his hypothesis of sexual selection. A running
-comment has been made while considering the individual cases, but it may
-be well to sum up the matter by briefly indicating the reasons why the
-hypothesis seems incompetent to explain the facts.
-
-
-          General Criticism of the Theory of Sexual Selection
-
-1. Some of the objections that apply to the theory of natural selection
-apply also with equal force to the theory of sexual selection in so far
-as the results in both cases are supposed to be the outcome of the
-selection of individual, or fluctuating, variations. If these variations
-appear in only a few individuals, their perpetuation is not possible,
-since they will soon disappear through crossing. It would be, of course,
-preposterous to suppose that at any one time only those few individuals
-pair and leave descendants that have the secondary sexual characters
-developed to the highest point, but if something of this sort does not
-occur, the extreme of fluctuating variations cannot be maintained. Even
-if half of the individuals are selected in each generation, the
-accumulation of a variation in a given direction could not go very far.
-The assumption, however, that only half of all the individuals that
-reach maturity breed, and that all of these are chosen on account of the
-special development of their secondary sexual characters, seems
-preposterous. Furthermore, if it is assumed that the high development of
-the new character appears in a large number of individuals, then it is
-not improbable that its continued appearance might be accounted for
-without bringing in, at all, the hypothesis of sexual selection.
-
-2. But even supposing that the females select the most beautiful males,
-then, since in the vast majority of higher animals the males and the
-females are in equal numbers, the others will also be able to unite with
-each other in pairs after this first selection has taken place. Nothing
-will therefore be gained in the next generation. It is interesting to
-see how Darwin attempts to meet this argument. He tries to show in the
-case of birds, that there are always unpaired individuals, but since the
-few facts that he has been able to collect show that there are as many
-additional females as males, the argument proves too much. A few species
-are polygamous, one male having a number of female birds; but on this
-basis we can only account, at best, for the development through
-competition of the organs of offence and defence used to keep away the
-weaker males. Yet it is just amongst these birds that we often find the
-ornamental characters well developed. In fact, since all the females in
-such cases are selected, and since they will transmit the characters of
-all the males, it is evident that the secondary sexual characters could
-not be formed in the way imagined.
-
-3. If the female fails to select only the more ornamental males, no
-result will follow. It has not been shown that she is capable of making
-such a choice, and in the lower forms particularly, it does not seem
-probable that this is done. The argument that Darwin often employs,
-namely, that unless she does select, the display of the males before her
-is meaningless, is not to the point. So far as we can detect the “cause”
-of the display of the male, it appears to be due to his own excitement;
-and even if we go so far as to admit that the “purpose” is to attract
-the other sex, it still does not in the least follow that the most
-ornamental male is selected, and unless this occurs the display has no
-bearing on the hypothesis of sexual selection.
-
-4. The two forms of sexual selection, namely, competition of the males
-with one another (really one form of natural selection), and the
-selection of the most ornamental or gifted individuals, are both used by
-Darwin to explain secondary sexual characters, the one for organs of
-offence and defence, and the other for ornamental characters. If we
-fully appreciate the difficulties that any theory of selection meets
-with, we shall realize how extraordinarily complex the action must be,
-when two such processes are carried out at the same time, or even during
-alternating periods.
-
-5. It has been objected to Darwin’s theory of sexual selection, that he
-suddenly reverses its mode of action to explain those cases in which the
-female is the stronger and more ornamented sex; but if, as Darwin shows,
-the instincts of the male have also changed, and have become more like
-those of the female, I can see no inherent difficulty in this way of
-applying the theory. A much more serious objection, it seems to me, is
-that the male is supposed to select the female for one set of
-characteristics, and the female to select the male for another set. It
-sounds a little strange to suppose that women have caused the beard of
-man to develop by selecting the best-bearded individuals, and the
-compliment has been returned by the males selecting the females that
-have the least amount of beard. It is also assumed that the results of
-the selection are transmitted to one sex only. Unless, in fact, the
-character in question were from the beginning peculiar to only one sex
-as to its inheritance, the two sexes might go on forever selecting at
-cross-purposes, and the result would be nothing.
-
-6. The development, or the presence, of the æsthetic feeling in the
-selecting sex is not accounted for on the theory. There is just as much
-need to explain why the females are gifted with an appreciation of the
-beautiful, as that the beautiful colors develop in the males. Shall we
-assume that still another process of selection is going on, as a result
-of which those females are selected by the males that appreciate their
-unusual beauty, or that those females whose taste has soared a little
-higher than that of the average (a variation of this sort having
-appeared) select males to correspond, and thus the two continue heaping
-up the ornaments on one side and the appreciation of these ornaments on
-the other? No doubt an interesting fiction could be built up along these
-lines, but would any one believe it, and, if he did, could he prove it?
-
-Darwin assumes that the appreciation on the part of the female is always
-present, and he thus simplifies, in appearance, the problem, but he
-leaves half of it unexplained.
-
-7. It has been pointed out, that it is important to distinguish between
-the possible excitement of the female by the display or antics of the
-male, and the selection of the more beautiful or agile performer. Darwin
-himself records a few cases, which plainly show that the more beautiful
-is not always the more successful. It has also been suggested that the
-battles of the males are sometimes sham performances, and even when they
-are real, if the less vigorous do not remain to be destroyed but run
-away, they live to find mates of their own. In fact, the conduct of the
-males at the breeding season appears to be much more the outcome of
-their own excitement than an attempt to attract the females.
-
-8. There is another side to the question, the importance of which is so
-great, that it is surprising that Darwin has not taken any notice of it.
-If, in order to bring about, or even maintain, the results of sexual
-selection, such a tremendous elimination of individuals must take place,
-it is surprising that natural selection would not counteract this by
-destroying those species in which a process, so useless for the welfare
-of the species, is going on. It is curious that this has not been
-realized by those who believe in both of these two hypotheses.
-
-9. What has just been said applies also with almost equal force to the
-development of such structures as the horns of deer, bison, antelopes,
-and the brilliant colors of many insects and birds. If in nature,
-competition between species takes place on the scale that the Darwinian
-theory of natural selection postulates, such forms, if they are much
-exposed, would be needlessly reduced in numbers in the process of
-acquiring these structures. So many individuals would have been at such
-a disadvantage in breeding, that if competition is as severe as the
-theory of natural selection postulates, these species could hardly be
-expected to compete successfully with other species in which sexual
-selection was not taking place.
-
-10. Darwin admits that, in certain cases, external conditions may have
-acted directly to produce the colors in certain forms, and if these were
-not injurious he thinks they might have become constant. Such cases are
-left unexplained in the sense that they are not supposed to be
-adaptations to anything in particular. That colors produced in this way
-might afterward be found useful, irrespective of how they arose, is
-admitted as one of the ways in which sexual differences may have arisen.
-
-11. It is baffling to find Darwin resorting to the Lamarckian
-explanation in those cases in which the improbability of the hypothesis
-of sexual selection is manifest. If either principle is true, we should
-expect it to apply to all phenomena of the same sort; yet Darwin makes
-use of the Lamarckian principle, in the hypothesis of sexual selection,
-only when difficulties arise.
-
-12. In attempting to explain the development of the musical sense in
-man, it is clear that the hypothesis of sexual selection fails to give a
-satisfactory explanation. To suppose that the genius of a Beethoven or
-of a Mozart could have been the result of a process of sexual selection
-is too absurd to discuss. Neither the power of appreciation nor of
-expression in music could possibly have been the outcome of such a
-process, and it does not materially help the problem to refer it back to
-a troop of monkeys making the woods hideous with their cries.
-
-We come now to some of the special cases to which Darwin’s hypothesis
-has been applied.
-
-13. In one case at least, it is stated that a bird living on the ground
-might have acquired the color of the upper surface of the body through
-natural selection, while the under surface of the males of the same
-species might have become ornamented through the action of sexual
-selection. Thus in one and the same individual the two processes are
-supposed to have been at work, and it does not lessen the difficulty
-very much by supposing the two processes to have been carried out at
-different times, because it is evident that what had been gained at one
-time by one process might become lost while the color of certain parts
-was being acquired through the other process.
-
-14. Darwin points out that “the plumage of certain birds goes on
-increasing in beauty during many years after they are fully mature,” as
-in the peacock, and in some of the birds of paradise, and with the
-plumes and crests of some herons. This is explained as possibly merely
-the result of “continued growth.” The improbability of selection is
-manifest in these cases, but if “continued growth” can accomplish this
-much, why may not the whole process be also the outcome of such growth?
-At any rate, whatever the explanation is, it is important to find a case
-of a secondary sexual character that the hypothesis obviously is
-insufficient to explain.
-
-15. It is admitted in a number of cases, as in the stag for instance,
-that, although the larynx of the male is enlarged, this is not, in all
-probability, the outcome of sexual selection, but in other forms this
-same enlargement is ascribed to the selection process.
-
-16. It is admitted that in none of the highly colored British moths is
-there much difference according to sex, although when a difference of
-color is found in butterflies this is put down to the action of sexual
-selection. If such wonderful colors as those of moths can arise without
-the action of selection, why make a special explanation for those cases
-in which this difference is associated with sex?
-
-17. It is well known that birds sing at other times of the year than at
-the breeding season, and an attempt is made to account for this in that
-birds take pleasure in practising those instincts that they make use of
-at other times, as the cat plays with the captive mouse. Does not this
-suggest that, if they had certain instincts, they would be more likely
-to employ them at the times when their vitality or excitement is at its
-highest without regard to the way in which they have come by them?
-
-18. The color of the iris of the eyes of many species of hornbills is
-said to be an intense crimson in the males, and white in the females. In
-the male condor the eye is yellowish brown, and in the female a bright
-red. Darwin admits that it is doubtful if this difference is the result
-of sexual selection, since in the latter case the lining of the mouth is
-black in the males, and flesh-colored in the females, which does not
-affect the external beauty. Yet if these colors were more extensive and
-on the exterior, there can be little doubt that they would have been
-explained as due to sexual selection.
-
-19. When the females in certain species of birds differ more from each
-other than they do from their respective males, the case is compared to
-“those inexplicable ones, which occur independently of man’s selection
-in certain sub-breeds of the game-fowl, in which the females are very
-different, whilst the males can hardly be distinguished.” Here then is a
-case of difference in color associated with sex, but not the outcome of
-sexual selection.
-
-20. The long hairs on the throat of the stag are said possibly to be of
-use to him when hunted, since the dogs generally seize him by the
-throat, “but it is not probable that the hairs were specially developed
-for this purpose; otherwise the young and the females would have been
-equally protected.” Here also is a sexual difference that can scarcely
-be ascribed to selection.
-
-Some cases of differences in color between the sexes “may be the result
-of variations confined to one sex, and transmitted to the same sex
-without any good being gained, and, therefore, without the aid of
-selection. We have instances of this with our domesticated animals, as
-in the males of certain cats being rusty-red while the females are
-tortoise-shell colored. Analogous cases occur in nature: Mr. Bartlett
-has seen many black varieties of the jaguar, leopard, vulpine phalanger,
-and wombat; and he is certain that all or nearly all of these animals
-were males.” If changes of this sort occur, associated with one sex, why
-is there any need of a special explanation in other cases of difference?
-
-                  *       *       *       *       *
-
-In the light of the many difficulties that the theory of sexual
-selection meets with, I think we shall be justified in rejecting it as
-an explanation of the secondary sexual differences amongst animals.
-Other attempts to explain these differences have been equally
-unsuccessful. Thus Wallace accounts for them as due to the excessive
-vigor of the male, but Darwin’s reply to Wallace appears to show that
-this is not the cause of the difference. He points out that, while the
-hypothesis might appear plausible in the case of color, it is not so
-evident in the case of other secondary sexual characters, such, for
-instance, as the musical apparatus of the males of certain insects, and
-the difference in the size of the larynx of certain birds and mammals.
-
-Darwin’s theory served to draw attention to a large number of most
-interesting differences between the sexes, and, even if it prove to be a
-fiction, it has done much good in bringing before us an array of
-important facts in regard to differences in secondary sexual characters.
-More than this I do not believe it has done. The theory meets with fatal
-objections at every turn.
-
-In a later chapter the question will be more fully discussed as to the
-sense in which these secondary sexual differences may be looked upon as
-adaptations.
-
-
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-
-
-
-
-                              CHAPTER VII
-
-    THE INHERITANCE OF ACQUIRED CHARACTERS AS A FACTOR IN EVOLUTION
-
-                            Lamarck’s Theory
-
-
-One of the most striking and peculiar characteristics of living things
-is that through use a part is able to carry out a particular function
-better than before, and in some cases the use of the part leads to its
-increase in size. Conversely, disuse leads to the decrease of a part in
-size. We are perfectly familiar with this process in ourselves as
-applied to our nervous system and muscles.
-
-It is not surprising that the idea should have arisen that, if the
-results of the use of a part are inherited by the next generation, the
-adaptation of organisms might be explained in this way. The presence of
-the organs of touch, in those parts of the body that are more likely to
-come into contact with foreign bodies, offers a striking parallel to the
-perfecting of the sensation of touch that can be brought about through
-the use of any part. The development of eyes only on the exposed parts
-of the body, as on the tentacles of the sedentary annelids, or along the
-margin of the mantle of a bivalve mollusk, suggests that there may be
-some direct connection between their presence in these regions and the
-effect of light on the parts. In fact, ever since the time of Lamarck,
-there have been many zoologists who have claimed that many of the
-adaptations of organisms have arisen in this way, that is, through the
-inheritance of the characters acquired through use. In general this
-theory is summed up in the phrase, “the inheritance of acquired
-characters.”
-
-This view is prominently associated with the name of Lamarck, who held,
-however, a different view in regard to the origin of some of the other
-structures of the organism. Moreover, Erasmus Darwin, even before
-Lamarck, had suggested the principle of the inheritance of acquired
-characters.
-
-As has just been said, Lamarck held that the inheritance of acquired
-characters was only one of the ways in which animals have become
-changed, and he clearly stated that in the case of all plants and of
-some of the lower animals the change (evolution) which he supposed them
-to undergo was due to the general influence of the environment. Since
-plants and the lower animals (as he supposed) have no central nervous
-system, or at least no such well-defined nervous system as have the
-higher animals, Lamarck thought that they could not have evolved in the
-same way as have the higher animals. We now know that, so far as the
-lower animals, at least, are concerned, there was no need for such a
-distinction, since many of their responses are like those of the higher
-animals. This distinction that Lamarck made is responsible, no doubt,
-for a misconception that was long held in regard to a part of his views.
-It is often stated that he supposed the desire of the animal for a
-particular part has led to the development of that part; while in
-reality he only maintained the desire to use a particular organ to
-fulfil some want led to its better development through exercise, and the
-result was inherited. Lamarck also supposed that the _decrease_ in use
-of a part which leads to its decrease in size accounts for the
-degeneration of organs.
-
-Lamarck first advanced his theory in 1801, when he cited the following
-examples in its favor. A bird, driven through want to the water to find
-its food, will separate its toes when they strike the water. The skin
-uniting the bases of the toes will be stretched in consequence, and in
-this way the broad membrane between the toes of ducks and geese has been
-acquired. The toes of a bird that is in the habit of perching on a tree
-become elongated in consequence of becoming stretched, hence has arisen
-the foot with the long toes characteristic of arboreal birds.
-
-Shore-birds, “which do not care to swim,” but must approach the water in
-order to obtain food, will be in danger of sinking into the mud, “but,
-wishing to act so that their body shall not fall into the liquid, they
-will contract the habit of extending and lengthening their legs.” Hence
-have arisen the stiltlike legs of shore-birds.
-
-These ideas were more fully elaborated in the following year. He added
-the further examples: Our dray-horses have arisen through the use to
-which they have been put, and the race-horse also, which has been used
-in a different way. Cultivated plants, on the contrary, are the result
-of the new environment to which they have been subjected.
-
-In the “Philosophic Zoologique,” published in 1809, Lamarck has much
-more fully developed his theory. Here he combats strenuously the idea
-that species are fixed. His point of view may be judged by the following
-propositions, which he believes can be established:—
-
-1. That all organized bodies of our globe are veritable productions of
-nature, which she has successively produced in the course of a long
-time.
-
-2. That in her progress nature began, and begins still every day, to
-produce the simplest organisms, and that she still produces directly the
-same primitive kinds of organizations. This process has been called
-spontaneous generation.
-
-3. That the first beginning of animals and of plants takes place in
-favorable localities and under favorable circumstances. An organic
-movement having once established their production, they have of
-necessity gradually developed their organs, and have become diversified
-in the course of time.
-
-4. That the power of growth of each part of the body being inherited as
-a consequence of the first effect of life, different modes of
-multiplication and of regeneration have arisen, and these have been
-conserved.
-
-5. That with the aid of sufficient time and of favorable circumstances
-the changes that have taken place on the surface of the globe have
-called forth new structures and new habits, and in consequence have
-modified the organs of the body, and made animals and plants such as we
-see them at the present day.
-
-6. Finally, as a result of these changes that living bodies have been
-forced to undergo, species have been formed, but these species have only
-a relative constancy, and are not as ancient as is nature herself. If
-the environment remains the same, species also remain the same, as is
-exemplified by the animals living at present in Egypt, which are exactly
-like those living there in ancient times.
-
-Lamarck concludes that the appearance of stability is always mistaken by
-the layman for the reality, because, in general, every one judges things
-relatively to himself. In fact, species are not absolutely constant, but
-are so only temporarily. “The influence of the environment is continuous
-and always active, but its effects may only be recognized after a long
-time.” The irregularity and the complexity of the organization of
-animals is the outcome of the infinitely diversified circumstances to
-which they have been subjected. These changes, Lamarck claims, do not
-directly cause modifications in the form of animals,[17] but bring about
-changes in their needs, and changes in their needs bring about changes
-in their actions. If the needs remain the same, the acquired actions
-become habits. These habitual actions lead to the use of certain parts
-in preference to others, and this in turn to an alteration in form and
-structure. The individuals so changed breed together and leave
-descendants that inherit the acquired modification.
-
-Footnote 17:
-
-  This is clearly meant to be applied only in the case of higher
-  animals.
-
-Curiously enough, Lamarck follows up this argument by citing some cases
-amongst plants that have been changed directly by the action of the
-environment. He says that since plants have no motions they have
-consequently no habits, but they are developed by changes in their
-nutrition, etc., and this brings about the superiority of some of the
-vital movements over others.
-
-Amongst domestic animals Lamarck cites the case of the dog, that has
-come from a wild form like the wolf, but having been carried into
-different countries has acquired different and new habits, and this has
-led to the formation of new races, such as the bulldog, greyhound,
-pug-dog, spaniel, etc.
-
-Lamarck’s argument shifts so often back and forth from animals to
-plants, that it is clear that in his own mind he did not see any
-important difference between the action of the environment on plants,
-and the use of the organs of the animal. He gives in this same
-connection his oft-quoted summary of what he calls the two laws of
-nature “which observation always establishes.”
-
-First Law. In every animal, that has not passed beyond the term of its
-development, the frequent and sustained use of any organ strengthens it,
-develops it, increases its size, and gives it strength proportionate to
-the length of time of its employment. On the other hand, the continued
-lack of use of the same organ sensibly weakens it; it deteriorates, and
-its faculties diminish progressively until at last it disappears.
-
-Second Law. Nature preserves everything that she has caused the
-individual to acquire or to lose by the influence of the circumstances
-to which the race has been for a long time exposed, and consequently by
-the influence of the predominant use of certain organs (or in
-consequence of its continued disuse). She does this by the generation of
-new individuals which are produced with the newly acquired organs. This
-occurs, provided that the acquired changes were common to the two sexes,
-or to the individuals that produced the new forms.
-
-These laws are, Lamarck says, fundamental truths which cannot be
-misunderstood except by those who have never observed or followed nature
-in her operations. He insists that it is a mistake to suppose that the
-parts are responsible for the functions, for it is easy to demonstrate
-that it is the needs and uses of the organs that have caused the parts
-to develop.
-
-If it is supposed, he continues, that these laws are hypothetical, they
-may be demonstrated by the following facts: The adult baleen whale is
-without teeth, although in the fœtus teeth are present, concealed in the
-jaws. The loss of the teeth is the result of the whale swallowing its
-food without first masticating it. The ant-eater is also without teeth,
-and has also the habit of swallowing its food without chewing it. The
-mole has very small eyes, and this is the result of its having made very
-little use of them, since its habits are subterranean. Another animal,
-the aspalax, has only the rudiments of eyes, and has almost completely
-lost the power of sight. This animal also lives underground like the
-mole.
-
-Proteus, an aquatic salamander living in deep caves, has only
-rudimentary eyes. In these latter cases it is the disuse of the eye that
-has led to its degeneration. This is proven, Lamarck adds, by the fact
-that the organs of hearing are never in this condition, because sound
-vibrations penetrate everywhere, even into the densest bodies.
-
-It is a part of the plan of organization of the reptiles that they have
-four legs; but the snakes, although belonging to this group, have no
-legs. This absence of legs is explained by their having acquired the
-habit of gliding over the ground, and of concealing themselves in the
-grass. Owing to their repeated effort to elongate themselves, in order
-to pass through narrow spaces, their bodies have become drawn out. Under
-these circumstances legs would be useless, since long ones would
-interfere with their motion, and short ones could not move their long
-bodies. Since the plan of organization limits the snakes to only four
-legs, and since this number would be useless, they have disappeared.
-
-Many insects are destitute of wings, although wings are a part of the
-plan of organization of this group. They are absent only in those forms
-whose habits render wings useless, consequently they have disappeared
-through disuse.
-
-The preceding cases are those in which the disuse of an organ has led to
-its degeneration. The following cases are cited to show that by use an
-organ increases in size. The formation of the web in the feet of
-water-birds has already been given as a character which Lamarck supposes
-to have been acquired through use; also the case of shore-birds, which,
-by an effort to elongate their legs, have actually made them so in the
-course of time. The necks of water-birds are also long on account of
-their having been stretched in the efforts to catch fish. The long
-tongues of the ant-eater, of the woodpecker, and of humming-birds are
-the result of use, and the long, forked tongue of serpents has come from
-their using their tongue to feel objects in front of them.
-
-Fishes that have acquired the habit of living in shallow water,
-flounders, soles, etc., have been forced to swim on their sides in order
-to approach nearer to the shore. Since more light comes from above than
-from below, the eye on the under side, straining to turn to the light,
-has finally migrated to the upper side.
-
-The habit of eating great quantities of food, which distends the
-digestive organs, has caused the bodies of herbivorous quadrupeds to
-become large, as seen in the elephant, the rhinoceros, oxen, horses, and
-buffaloes. The habit of standing for a long time on their feet has
-caused some animals to develop hard, thick hoofs. Herbivorous animals,
-that inhabit countries where they are constantly subjected to attack, as
-deer and antelopes for example, are forced to escape by rapid flight,
-and in consequence their bodies have become slenderer and their legs
-thinner. The horns, antlers, and protuberances that many of these
-animals possess are the results of their butting each other when
-angered.
-
-“The long neck and the form of the giraffe offer a curious case. We know
-that the giraffe is the tallest of all animals. It inhabits the centre
-of Africa, living in those localities where the earth is nearly always
-dry and without herbage. It is obliged to browse on the foliage of
-trees, and this leads to its stretching continually upwards. As a result
-of this habit, carried on for a long time, in all the individuals of the
-race, the anterior limbs have become longer than the posterior, and its
-neck has also lengthened, so that the giraffe without rising on its
-hind-legs stretches up its neck and can reach to the height of six
-metres.”
-
-The curved claws of the carnivora have arisen from the necessity of
-grasping their prey. The power of retracting the claws has also been
-acquired by the effort to draw them in when running over hard ground.
-The abdominal pouch of the kangaroo, in which the young are carried,
-opens anteriorly, and this has led to the animal standing erect so that
-its young are not injured. In consequence, the fore-legs have become
-shorter through disuse, and the hind-legs have become stronger through
-use. The tail, which is also used as a support, has become enormously
-thick at its base.
-
-The sloth has been compelled to seek refuge in the trees, and has taken
-up its abode permanently there, feeding on leaves. Its movements are
-limited to those involved in crawling along the limbs in order to reach
-the leaves. After feeding it remains inactive and sluggish, these habits
-being provoked by the heat of the climate. The results of its mode of
-life have been to cause the arms to become elongated due to the habit of
-the sloth of grasping the limbs of the tree; the claws of the fingers
-and toes have also become long and hooked in order to retain their hold.
-The digits that do not make any individual movements have lost the power
-to do so, and have become fused, and can only be bent in and
-straightened out. The thighs, being bent out to clasp the larger
-branches, have caused the pelvis to widen, and, in consequence, the
-cotyloid cavities have become directed backward. Many of the bones of
-the skeleton have become fused, as a result of the immobility of the
-animal.
-
-Lamarck says, that “Nature, in producing, successively, all the species
-of animals, beginning with the most imperfect, or the most simple, and
-terminating with the most perfect, has gradually complicated their
-organization. These animals becoming scattered throughout the habitable
-regions of the globe each species has received from the influences of
-its surroundings its present habits, and the modifications of the parts
-the use of which we recognize.”
-
-Such are Lamarck’s views and a fairly complete statement of the facts
-from which he draws his conclusions. His illustrations appear naïve, and
-often not a little ludicrous, but it must be admitted that, despite
-their absurdities, his theory appears in some cases to account
-wonderfully well for the facts. The long legs of wading birds, the long
-neck and disproportionately long fore-legs of the giraffe, the structure
-of the sloth, and particularly the degeneration of the eyes of animals
-living in the dark, seem to find a simple explanation in the principle
-of the inheritance of acquired characters. But the crucial point of the
-entire theory is passed over in silence, or rather is taken for granted
-by Lamarck, namely, the inheritance in the offspring of the characters
-acquired through use or disuse in the parent. He does not even discuss
-this topic, but in several places states unreservedly that the increase
-or decrease of a part reappears in the next generation. It is here that
-Lamarck’s theory has been attacked in more modern times, for as soon as
-experimental proof was demanded to show that the results of use or of
-disuse of an organ is inherited, no such proof was forthcoming. Yet the
-theory is one that has the great merit of being capable of experimental
-test, and it is astonishing to find that, with the immense amount that
-has been written by his followers, so few attempts have been made to
-give the theory a thorough test. The few results that have been obtained
-are not, however, favorable to the theory, but almost the only attempts
-at experiment that have been made in this direction have been those of
-mutilating certain parts; and were it not for popular belief to the
-effect that such mutilations are inherited, one would least expect to
-get evidence for or against the theory in this direction. Lamarck
-himself believed that the changes were slowly acquired, and I think
-modern Lamarckians are justified in claiming that the validity of the
-theory can only be tested by experiments in which the organism is
-subjected to influences extending over a considerable period, although
-Lamarck appears to have believed that the first results may appear quite
-soon. Before expressing any opinion in regard to the probability of the
-theory, let us examine what the followers of Lamarck have contributed in
-the way of evidence to the theory, rather than the applications that
-they have made of the theory. We shall also find it profitable to
-consider some of the modern criticism, to which the theory has been
-subjected.
-
-Despite the contempt with which Darwin referred to Lamarck’s theory, he
-himself, as we have seen, often made use of the principle of the
-inheritance of acquired characters, and even employed the same
-illustrations cited by Lamarck. Darwin seems to have misunderstood
-Lamarck’s view, and to have accepted the current opinion that Lamarck
-supposed an animal acquired a new organ by desiring or needing it.
-Darwin says, “Heaven forefend me from Lamarck’s nonsense of a tendency
-to progressive adaptation from the slow willing of the animals.” Darwin
-speaks of Lamarck as stating that animals will that the egg shall be a
-particular form so as to become attached to particular objects.
-Lamarck’s latest biographer, Packard, says he is unable to find any
-statements of this sort in Lamarck’s writings.
-
-The following cases that Darwin tried to explain through the inheritance
-of acquired characters are exactly like those to which Lamarck applied
-his theory. The bones of the wing of the domestic duck weigh less than
-those of the wild duck, and the bones of the leg more. Darwin believes
-this is due to the effects of the inheritance of acquired characters.
-The drooping ears of many domestic mammals are also explained by him as
-a result of disuse—“the animals being seldom much alarmed.” In speaking
-of the male of the beetle, _Onites apelles_, Darwin quotes Kirby to the
-effect that the tarsi are so habitually lost that the species has been
-described without this part of the foot. In the sacred beetle of Egypt
-the tarsus is totally absent. Hence he concludes that the absence of
-tarsi in the sacred beetle, and the rudimentary condition of the tarsus
-in others, is probably the result of disuse, rather than a case of
-inheritance of a mutilation. Darwin grants that “the evidence that
-accidental mutilations can be inherited is at present not decisive, but
-the remarkable case observed by Brown-Séquard in guinea-pigs of the
-inherited effects of operations should make us cautious in denying this
-tendency.”
-
-The wingless condition of several insects inhabiting oceanic islands has
-come about, Darwin thinks, through disuse. The ostrich also, owing to
-its increase in size, made less use of its wings and more use of its
-legs, with the result that its wings degenerated and its legs got
-stronger. The rudimentary condition of the eyes of the mole is the
-result of disuse, “aided perhaps by natural selection.” Many of the
-animals inhabiting the caves of Kentucky and of Carniola are blind, and
-this is ascribed to disuse. “As it is difficult to imagine that the
-eyes, though useless, could be in any way injurious to animals living in
-darkness, their loss may be attributed to disuse.” The long neck of the
-giraffe Darwin attributes partly to natural selection and partly to use.
-
-These references will suffice to show that Darwin is in full accord with
-the main argument of Lamarck. In fact, the curious hypothesis of
-pangenesis that Darwin advanced was invented partly to account for the
-inheritance of acquired characters. Despite the hesitancy that Darwin
-himself felt in advancing this view, and contrary to Huxley’s advice, he
-at last published his provisional hypothesis of pangenesis in the
-twenty-seventh chapter of his “Animals and Plants under Domestication.”
-
-
-                   Darwin’s Hypothesis of Pangenesis
-
-The study of bud variation, of the various forms of inheritance, and of
-reproduction and of the causes of variation, led him, Darwin says, to
-the belief that these subjects stand in some sort of relation to each
-other. He says: “I have been led, or rather forced, to form a view which
-to a certain extent connects these facts by a tangible method. Every one
-would wish to explain to himself, even in an imperfect manner, how it is
-possible for a character possessed by some remote ancestor suddenly to
-reappear in the offspring; how the effects of increased or decreased use
-of a limb can be transmitted to the child; how the male sexual element
-can act not solely on the ovules, but occasionally on the mother form;
-how a hybrid can be produced by the union of the cellular tissue of two
-plants independently of the organs of generation; how a limb can be
-reproduced on the exact line of amputation, with neither too much nor
-too little added; how the same organism may be produced by such widely
-different processes, as budding and true seminal generation; and,
-lastly, how of two allied forms, one passes in the course of its
-development through the most complex metamorphoses, and the other does
-not do so, though when mature both are alike in every detail of
-structure. I am aware that my view is merely a provisional hypothesis or
-speculation; but, until a better one be advanced, it will serve to bring
-together a multitude of facts which are at present left disconnected by
-any efficient cause.”
-
-In presenting the hypothesis of pangenesis Darwin begins by enumerating
-the different kinds of sexual and asexual processes of reproduction, for
-which he hopes to offer a provisional explanation. Here we find
-mentioned various methods of budding and self-division, regeneration,
-parthenogenesis, sexual reproduction, and the inheritance of acquired
-characters. It is with the last only that we are here chiefly concerned;
-in fact, the need of an hypothesis _of this sort_ to explain the other
-kinds of inheritance is by no means evident. There are, however, two
-other phenomena, besides that of the supposed inheritance of acquired
-characters, to which the hypothesis of pangenesis might appear to apply
-specially, namely, the effect of foreign pollen on the tissues of the
-mother plant, and the supposed influence of the union with the first
-male on the subsequent young (telegony). It is, however, far from being
-shown that any influence of this latter kind really occurs, despite the
-fact that it is generally believed in by breeders.
-
-It is important to observe that Darwin proposes to explain on the
-hypothesis of pangenesis, not only the inheritance of characters
-acquired through use, but also the decrease of structures through
-disuse; and this applies, not only to the structure, but to function as
-well, as when the intelligence of the dog is explained through his
-association with man, and the tameness of the domestic rabbits through
-their long confinement. In the following quotation these points are
-referred to: “How can the use or disuse of a particular limb or of the
-brain affect a small aggregate of reproductive cells, seated in a
-distant part of the body, in such a manner that the being developed from
-these cells inherits the characters of either one or both parents? Even
-an imperfect answer to this question would be satisfactory.”
-
-Coming now to the theory, we find that it consists of one chief
-assumption and several minor ones. “It is universally admitted that the
-cells or units of the body increase by self-division or proliferation,
-retaining the same nature, and that they ultimately become converted
-into the various tissues and substances of the body. But besides this
-means of increase I assume that the units throw off minute granules
-which are dispersed throughout the whole system; that these, when
-supplied with proper nutriment, multiply by self-division, and are
-ultimately developed into units like those from which they were
-originally derived. These granules may be called gemmules. They are
-collected from all parts of the system to constitute the sexual
-elements, and their development in the next generation forms a new
-being; but they are likewise capable of transmission in a dormant state
-to future generations, and may then be developed.... Gemmules are
-supposed to be thrown off by every unit, not only during the adult
-state, but during each stage of development of every organism; but not
-necessarily during the continued existence of the same unit. Lastly, I
-assume that the gemmules in their dormant state have a mutual affinity
-for each other, leading to their aggregation into buds, or into the
-sexual elements. Hence, it is not the reproductive organs, or buds,
-which generate new organisms, but the units of which each individual is
-composed. These assumptions constitute the provisional hypothesis which
-I have called Pangenesis.”
-
-It will be noticed that the first assumption is that the cells throw off
-minute gemmules or granules. The second assumption is that these are
-collected in the reproductive organs, or in buds, or in regenerating
-parts; the third assumption is that the gemmules may lie dormant through
-several generations; the fourth, that the development of the
-reproductive cells is not so much the development of the cell itself,
-but of the gemmules that have collected in it. The fifth assumption is
-that the gemmules are thrown off at all stages of development; the
-sixth, that in their dormant state they have a mutual affinity for each
-other; the seventh, that there may be a sort of continual competition in
-the germ-cells between the original gemmules and the new ones, and,
-according to which win, the old or the new form develops. Thus we see on
-closer analysis that the pangenesis hypothesis is made up of a goodly
-number of different assumptions. At least half a dozen imaginary
-properties are ascribed to the imaginary gemmules, and these attributes
-are all essential to the working of the hypothesis.
-
-Some of the more obvious objections to the hypothesis have been stated
-by Darwin himself. Such, for instance, as our ignorance at what stage in
-their history the body-cells are capable of throwing off gemmules, and
-whether they collect only at certain times in the reproductive organs,
-as the increased flow of blood to these organs at certain seasons might
-seem to indicate. Nor have we any evidence that they are carried by the
-blood at all. The experiment of Galton, of transfusing the blood of one
-animal into another, and finding that this produced no effect on the
-young that were born later, might be interpreted to mean that gemmules
-are not transported by the blood; but this kind of experiment is
-inconclusive, especially in the light of recent results on the effect of
-the blood of one animal on that of another.
-
-A part of the evidence on which Darwin relied to support his theory has
-been shown to be incorrect by later work. Thus the assumption that more
-than a single pollen grain, or more than one spermatozoon, is necessary
-in some cases for fertilization, is certainly wrong. In most cases, in
-fact, the entrance of more than one spermatozoon into the egg is
-disastrous to the development. The cases referred to by Darwin can
-probably be explained by the difficulty that some of the pollen grains,
-or spermatozoa, may have in penetrating the egg, or to the immaturity or
-impotence of some of the male germ-cells, and not to the need of more
-than one to accomplish the true fertilization.
-
-Darwin’s idea that the small number of gemmules in the unfertilized egg
-may account for the lack of power of such eggs to develop until they are
-fertilized, has been shown to be incorrect by recent results in
-experimental embryology. We now know that many different kinds of
-stimuli have the power to start the development of the egg. Moreover, we
-also know that if a single spermatozoon is supplied with a piece of
-egg-protoplasm without a nucleus, it suffices to cause this piece of
-protoplasm to develop.
-
-In the case of regeneration, which Darwin also tries to explain on the
-pangenesis hypothesis, we find that there is no need at all for an
-hypothesis of this sort; and there are a number of facts in connection
-with regeneration that are not in harmony with the hypothesis. For
-instance, when a part is cut off, the same part is regenerated; but
-under these circumstances it cannot be imagined that the part removed
-supplies the gemmules for the new part. Darwin tries to meet this
-objection by the assumption that every part of the body contains
-gemmules from every other part. But it has been shown that if a limb of
-the newt is completely extirpated, a new limb does not regenerate; and
-there is no reason why it should not do so on Darwin’s assumption that
-germs of the limb exist throughout the body.
-
-The best-authenticated cases of the influence of the male on the tissues
-of the female are those in plants, where one species, or variety, is
-fertilized by another. Thus, if the orange is fertilized by the pollen
-of the lemon, the fruit may have the color and flavor of the lemon. Now
-the fruit is a product of the tissues of the ovary of the female, and
-not a part of the seedling that develops in the fruit from the
-cross-fertilized egg-cell. Analogous cases are recorded for the bean,
-whose pods may have their color influenced by fertilizing the flower
-with pollen of another variety having pods of a different color. In
-these cases we do not know whether the color of the fruit is influenced
-directly by the foreign pollen, or whether the influence is through the
-embryo that develops from the egg-cell. The action may appear to be the
-same, however, in either case; but because it seems probable here that
-there is some sort of influence of one tissue on another, let us not too
-readily conclude that this is brought about through any such imaginary
-bodies as gemmules. It may be directly caused, for instance, by some
-chemical substance produced in the young hybrid plant. If this is the
-case, the result would not be different in kind from that of certain
-flowers whose color may be influenced by certain chemical substances in
-the soil.
-
-In the cases amongst animals, where the maternal tissues are believed to
-be influenced by a previous union with the male, as in the oft-cited
-case of Lord Morton’s mare, a reëxamination of the evidence by Ewart has
-shown that the case is not demonstrated, and not even probable. Several
-years ago I tried to test this view in the case of mice. A white mouse
-was first bred to a dark male house-mouse, and the next time to a white
-mouse, but none of the offspring from the second union showed any trace
-of black. If the spermatozoa of the dark mouse are hypodermically
-injected into the body-cavity of the female, the subsequent young from a
-white male show no evidence that the male cells have had any influence
-on the ovary.
-
-The following facts, spoken of by Darwin himself, are not in favor of
-his hypothesis of pangenesis: “But it appears at first sight a fatal
-objection to our hypothesis that a part of an organ may be removed
-during several successive generations, and if the operation be not
-followed by disease, the lost part reappears in the offspring. Dogs and
-horses formerly had their tails docked during many generations without
-any inherited effect; although, as we have seen, there is some reason to
-believe that the tailless conditions of certain sheep-dogs is due to
-such inheritance.” The answer that Darwin gives is that the gemmules
-themselves, that were once derived from the part, are still present in
-other parts of the body, and it is from these that the organs in the
-next generation may be derived. But Darwin fails to point out that, if
-this were the case, it must also be true for those cases in which an
-organ is no longer used. Its decrease in size in successive generations
-cannot be due to its disuse, for the rest of the body would supply the
-necessary gemmules to keep it at its full state of development. Thus, in
-trying to meet an obvious objection to his hypothesis, Darwin brings
-forward a new view that is fatal to another part of his hypothesis.
-
-The following cases, also given by Darwin, are admitted by him to be
-inexplicable on his hypothesis: “With respect to variations due to
-reversion, there is a similar difference between plants propagated from
-buds and seeds. Many varieties can be propagated securely by buds, but
-generally or invariably revert to their parent forms by seed. So, also,
-hybridized plants can be multiplied to any extent by buds, but are
-continually liable to reversion by seed,—that is, to the loss of their
-hybrid or intermediate character. I can offer no satisfactory
-explanation of these facts. Plants with variegated leaves, phloxes with
-striped flowers, barberries with seedless fruit, can all be securely
-propagated by buds taken from the stem or branches; but buds from the
-roots of these plants almost invariably lose their character and revert
-to their former condition. This latter fact is also inexplicable, unless
-buds developed from the roots are as distinct from those on the stem, as
-is one bud on the stem from another, and we know that these latter
-behave like independent organisms.” As Darwin here states, these facts
-appear to be directly contradictory to his hypothesis, and he makes no
-effort to account for them.
-
-The entire question of the possibility of the inheritance of acquired
-characters is itself at present far from being on a satisfactory basis,
-as we shall try to show; and Darwin’s attempt at an explanation, in his
-chapter on pangenesis, does not put the matter in a much more
-satisfactory condition.
-
-
-                       The Neo-Lamarckian School
-
-Let us now turn our attention to a school that has grown up in modern
-times, the members of which call themselves Neo-Lamarckians. Let us see
-if they have supplied the essential evidence that is required to
-establish the Lamarckian view, namely, that characters acquired by the
-individual are transmitted to the offspring.
-
-Lamarck’s views were adopted by Herbert Spencer, and play an important
-rôle in his “Principles of Biology” (1866-1871), and even a more
-conspicuous part in his later writings. In the former he cites, amongst
-other cases, that of “a puppy taken from its mother at six weeks old
-who, although never taught ‘to beg’ (an accomplishment his mother had
-been taught), spontaneously took to begging for everything he wanted
-when about seven or eight months old.” If tricks like this are
-inheritable is it not surprising that more puppies do not stand on their
-hind-legs?
-
-The larger hands of the laboring classes in England are supposed to be
-inherited by their children, and the smaller hands of the leisure
-classes are supposed to be the result of the disuse of the hands by
-their ancestors; but even if these statements in regard to size are
-true, there are many other conceivable causes that may have led to this
-result.
-
-Short-sightedness appears more often, it is said, in those classes of
-society that make most use of their eyes in reading and in writing; but
-if we ask for experimental evidence to show that this is due to
-inheritance, and not due to the children spoiling their eyes at school,
-there is none forthcoming. The problem is by no means so simple as the
-uninitiated may be led to believe.
-
-Spencer thinks that “some of the best illustrations of functional
-heredity are furnished by mental characteristics.” He cites the musical
-faculty as one that could not have been acquired by natural selection,
-and must have arisen through the inheritance of acquired modifications.
-The explanation offered is “that the habitual association of certain
-cadences of speech with certain emotions has clearly established in the
-race an organized and inherited connection between such cadences and
-such emotions, ... and that by the continued hearing and practice of
-melody there has been gained and transmitted an increasing musical
-sensibility.” But a statement that the results have been acquired in
-this way does not supply the proof which the theory is in need of;
-neither does it follow that, because the results cannot be explained by
-the theory of natural selection, therefore, they must be explained by
-the Lamarckian theory.
-
-The clearest proofs that Spencer finds of the inheritance of acquired
-characters are in the well-known experiments of Brown-Séquard. These
-experiments will be more fully discussed below. Amongst the other morbid
-processes that Spencer thinks furnish evidence in favor of this view,
-are cases of a tendency to gout, the occurrence of mental tricks,
-musical prodigies, liability to consumption, in all of which cases the
-fundamental distinction between the inheritance of an acquired character
-and the inherited tendency toward a particular malady is totally
-ignored.
-
-Twenty-seven years later (in 1893) Spencer took up the open challenge of
-the anti-Lamarckian writers, and by bringing forward a number of new
-_arguments_ attempted to reinstate the principle of the inheritance of
-acquired characters. His first illustration is drawn from the
-distribution of the sense of touch in different parts of our bodies.
-Weber’s experiments have shown that if the sharp points of a pair of
-compasses are applied to the tips of the forefingers, the sensation of
-two separate points is given when the points are only one-twelfth of an
-inch apart, and if the points are moved nearer together, they give the
-sensation of only one point. The inner surfaces of the second joints of
-the fingers can only distinguish two points when they are one-sixth of
-an inch apart. The innermost joints are less discriminating, and are
-about equal in the power of discrimination to the tip of the nose. The
-end of the big toe, the palm of the hand, and the cheek discriminate
-only about one-fifth as well as do the tips of the fingers. The back of
-the hand and the top of the head distinguish only about one-fifteenth as
-well as the finger-tips. The front of the thigh, near the knee, is
-somewhat less sensitive than the back of the hand. On the breast the
-points of the compasses must be separated by more than an inch and a
-half in order to give two sensations. In the middle of the back the
-points must be separated by two and a half inches, or more, in order to
-give two separate impressions.
-
-What is the meaning of these differences, Spencer asks. If natural
-selection has brought about the result, then it must be shown that
-“these degrees of endowment have advantaged the possessor to such an
-extent that not infrequently life has been directly or indirectly
-preserved by it.” He asks if this, or anything approaching this, result
-could have occurred.
-
-That the superior perceptiveness of the forefinger-tip might have arisen
-through selection is admitted by Spencer, but how could this have been
-the case, he asks, for the middle of the back, and for the face? The tip
-of the nose has three times more power of discrimination than the lower
-part of the forehead. Why should the front of the thigh near the knee be
-twice as perceptive as in the middle of the thigh; and why should the
-middle of the back and of the neck and the middle of the forearm and of
-the thigh stand at such low levels? Is it possible, Spencer asks again,
-that natural selection has determined these relations, and if not, how
-can they be explained? His reply is that the differences can all be
-accounted for on the theory of the inheritance of use, for it is evident
-that “these gradations in tactile perceptiveness correspond with the
-gradations in the tactual exercise of the parts.” Except from contact
-with the clothing the body receives hardly any touch sensations from
-outside, and this accounts for its small power of discrimination. The
-greater sensitiveness of the chest and abdomen, as compared with the
-back, is due to these regions being more frequently touched by the
-hands, and is also owing to inheritance from more remote ancestors, in
-which the lower surface of the body was more likely to have come in
-contact with foreign objects than was the back. The middle of the
-forearm and of the thigh are also less exposed than the knee and the
-hand, and have correspondingly the power of tactile discrimination less
-well developed.
-
-Weber showed that the tip of the tongue is more sensitive than any other
-part of the body, for it can distinguish between two points only one
-twenty-fourth of an inch apart. Obviously, Spencer says, natural
-selection cannot account for such extreme delicacy of touch, because,
-even if it were useful for the tongue to distinguish objects by touch,
-this power could never be of vital importance to the animal. It cannot
-even be supposed that such delicacy is necessary for the power of
-speech.
-
-The sensitiveness of the tongue can be accounted for, however, Spencer
-claims, as the result of the constant use of the tongue in exploring the
-cavity of the mouth. It is continually moving about, and touching now
-one part, and now another, of the mouth cavity. “No advantage is gained.
-It is simply that the tongue’s position renders perpetual exploration
-almost inevitable.” No other explanation of the facts seemed possible to
-Spencer.
-
-Two questions will at once suggest themselves. First, can it be shown
-that the sensitiveness to touch in various parts of the body is the
-result of individual experience? Have we learned to discriminate in
-those parts of the body that are most often brought into contact with
-surrounding objects? Even the power of discrimination in the tips of the
-fingers can be improved, as Spencer himself has shown, in the case of
-the blind, and of skilled compositors. Can we account in this way for
-the power of discrimination in various parts of the body? In other
-words, if, beginning in infancy, the middle of the back constantly came
-into contact with surrounding objects, would this region become as
-sensitive as the tips of the fingers? The experiment has not, of course,
-been carried out, but it is not probable that it would succeed. I
-venture this opinion on the ground of the relative number of the nerves
-and of the organs of touch on the back, as compared with those of the
-finger-tips. But, it will be asked, will not the number of the
-sense-organs become greater if a part is continually used by the
-individual? It is improbable that much improvement could be brought
-about in this way. The improvement that takes place through experience
-is probably not so much the result of the development of more
-sense-organs, as of better discrimination in the sensation, because the
-increased power can be very quickly acquired.
-
-An examination of the relative abundance of touch-spots in the skin
-shows that they are much more numerous in regions of greater
-sensitiveness. The following table, taken from Sherrington’s account of
-sense-organs in Schaefer’s “Textbook of Physiology,” gives the smallest
-distance that two points, simultaneously applied, can be recognized as
-such (and not simply as one impression) in different regions.
-
-
-                                               Mm.
-
-                      Tip of tongue            1.1
-
-                      Volar surface of         2.3
-                        ungual phalanx of
-                        finger
-
-                      Red surface of lip       4.5
-
-                      Volar face of second     4.5
-                        phalanx
-
-                      Dorsal face of third     6.8
-                        phalanx
-
-                      Side of tongue           9.0
-
-                      Third line of tongue,    9.0
-                        27 mm. from tip
-
-                      Plantar face of ungual  11.3
-                        phalanx of first toe
-
-                      Palm                    11.3
-
-                      Back of second phalanx  11.3
-                        of finger
-
-                      Forehead                22.6
-
-                      Back of ankle           22.6
-
-                      Back of hand            31.6
-
-                      Forearm, leg            40.6
-
-                      Dorsum of foot          40.6
-
-                      Outer sternum           45.1
-
-                      Back of neck            54.1
-
-                      Middle of back          67.1
-
-                      Upper arm, thigh        67.1
-
-
-The great difference in the sensitiveness of the skin in the different
-regions is very striking, and if, as seems probable, about the same
-proportionate difference is found at birth, then the degree of
-sensibility of the different regions is inborn, and is not the result of
-each individual experience. Until it can be shown that more of the
-sense-organs develop in any special part, as the result of the increased
-use of the part, we have no real basis on which to establish, even as
-probable, the Lamarckian view.
-
-But, after all, is the distribution of the sense-organs exactly that
-which we should expect on the Lamarckian theory? Has not Spencer taken
-too much for granted in this direction? The lower part of the forearm
-(represented by 15) we should expect to be more sensitive than the
-protected surface of the eyelid (11.3), but this is not the case. The
-forehead (22.6) is much less sensitive than the forearm, and only half
-as sensitive as the eyelid. The knee (36.1) is still less sensitive than
-any of these other parts, and this does not in the least accord with the
-theory, since in its constant moving forward it must be continually
-coming into contact with foreign bodies. The fact that the back is as
-insensitive as the upper arm (67.7) can hardly be accredited in favor of
-the theory. The great difference between the lower third of the forearm
-on the ulnar surface (15) and the upper arm (67.7) seems out of all
-proportion to what we should expect on the theory. And is it not a
-little odd that the end of the nose should be so highly sensitive?
-
-There is another point that we cannot afford to neglect in this
-connection. It is known that in addition to touch-spots there are warm
-and cold spots in the skin, which produce, when touched, the sensation
-of warmth, or of cold, respectively, and not the sensation of touch. The
-degree of sensitiveness of different regions of the body throws an
-interesting side-light on Spencer’s argument.
-
-The warm spots are much fewer than the cold spots. The spots are
-arranged in short lines radiating from centres which coincide with
-hairs. The number of these spots varies a good deal, even in the same
-region of the skin. If the sensitiveness of the skin is tested, the
-following results will be obtained. The list includes twelve grades of
-sensitiveness, beginning with the places giving the lowest maximum of
-intensity. About one hundred square areas were tested in each region.
-
-
-                              COLD SENSATIONS
-
-   1. Tips of fingers and toes, malleoli, ankle.
-   2. Other parts of digits, tip of nose, olecranon.
-   3. Glabella, chin, palm, gums.
-   4. Occiput, patella, wrist.
-   5. Clavicle, neck, forehead, tongue.
-   6. Buttocks, upper eyelid.
-   7. Lower eyelid, popliteal space, sole, cheek.
-   8. Inner aspect of thigh, arm above elbow.
-   9. The intercostal spaces along axillary line.
-   10. Mammary areola.
-   11. Nipple, flank.
-   12. Certain areas of the loins and abdomen.
-
-
-                           WARMTH SENSATIONS
-
-   0. Lower gum, mucosa of cheek, cornea.
-   1. Tips of fingers and toes, cavity of mouth, conjunctiva, and
-      patella.
-   2. Remaining surface of digits, middle of forehead, olecranon.
-   3. Glabella, chin, clavicle.
-   4. Palm, buttock, popliteal space.
-   5. Neck.
-   6. Back.
-   7. Lower eyelid, cheek.
-   8. Nipple, loin.
-
-
-These two tables show the great differences in the range of
-sensitiveness to cold and to warmth in different parts of the body. I
-doubt if any one will attempt to show that these differences of range of
-sensation can be accounted for either by natural selection or by the
-Lamarckian hypothesis.
-
-Of course, it does not necessarily follow that, because this is true for
-the warm and cold spots, that it must also be true for the tactile
-organs; but I think that the fact of such a great difference in the
-responsiveness to cold and to warmth in different parts of the body
-should put us on our guard against a too ready acceptation of Spencer’s
-argument. More especially is this seen to be necessary, when, as has
-been shown above, the distribution of the touch-organs themselves by no
-means closely corresponds to what we should expect, if they have
-developed in response to contact, as Spencer maintains.
-
-The other main argument advanced by Spencer to fortify the theory of the
-inheritance of acquired characters, and at the same time to show the
-inadequacy of the theory of natural selection, is based on the idea of
-what he calls the “coöperation of the parts” that is required in order
-to carry out any special act. Spencer contends that “the relative powers
-of coöperative parts cannot be adjusted solely by the survival of the
-fittest, and especially where the parts are numerous and the coöperation
-complex.”
-
-Spencer illustrates his point by the case of the extinct Irish elk,
-whose immensely developed horns weighed over a hundredweight. The horns,
-together with the massive skull, could not have been supported by the
-outstretched neck without many and great changes of the muscles and
-bones of the neck and of the fore-part of the body. Unless, for
-instance, the fore-legs had been also strengthened, there would be
-failure in fighting and in locomotion. Since “we cannot assume
-spontaneous increase of all these parts proportionate to the additional
-strains, we cannot suppose them to increase by variations one at once,
-without supposing the creature to be disadvantaged by the weight and
-nutrition of the parts that were for a time useless,—parts, moreover,
-which would revert to their original sizes before the other needful
-variations occurred.”
-
-The answer made to this argument was that coördinating parts vary
-together. In reply to which Spencer points to the following cases, which
-show that this is not so: The blind crayfish in the Kentucky caves have
-lost their eyes, but not the stalks that carry them. Again, the normal
-relation between the length of tongue and of beak in some varieties of
-pigeons is lost. The greater decrease in the jaws in some species of pet
-dogs than of the number of their teeth has caused the teeth to become
-crowded.[18] “I then argued that if coöperative parts, small in number,
-and so closely associated as these are, do not vary together, it is
-unwarrantable to allege that coöperative parts, which are very numerous
-and remote from one another, vary together.” Spencer puts himself here
-into the position of seriously maintaining that, because some
-coöperative parts do not vary together, therefore no coöperative parts
-have ever done so, and he has taken this position in the face of some
-well-known cases in which certain parts have been found to vary
-together.
-
-Footnote 18:
-
-  It is curious that Spencer does not see that this case is as much
-  against his point as in favor of it, since the _unused_ teeth did not
-  also degenerate.
-
-In this same connection Spencer brings up the familiar _pièce de
-résistance_ of the Lamarckian school, the giraffe. He recognizes that
-the chief traits in the structure of this animal are the result of
-natural selection, since its efforts to reach higher branches could not
-be the cause of the lengthening of the legs. But “the coadaptation of
-the parts, required to make the giraffe’s structure useful, is much
-greater than at first appears.” For example, the bones and the muscles
-of the hind-legs have been also altered, and Spencer argues that it is
-“impossible to believe” that all parts of the hind-quarters could have
-been coadapted to one another, and to all parts of the fore-quarters. A
-lack of coadaptation of a single muscle “would cause fatal results when
-high speed had to be maintained while escaping from an enemy.”
-
-Spencer claims that, since 1886, when he first published this argument,
-nothing like an adequate response has been made; and I think he might
-have added that an adequate answer is not likely to be forthcoming,
-since nothing short of a demonstration of how the giraffe really evolved
-is likely to be considered as sufficient. Wallace’s reply, that the
-changes in question could have been brought about by natural selection,
-since similar changes have been brought about by artificial selection,
-is regarded as inadequate by Spencer, since it assumes a parallel which
-does not exist. Nevertheless, Wallace’s reply contains, in my opinion,
-the kernel of the explanation, in so far as it assumes that congenital
-variation[19] may suffice to account for the origin of a form even as
-bizarre as that of the giraffe. The ancon ram and the turnspit dog were
-marked departures from the normal types, and yet their parts were
-sufficiently coördinated for them to carry out the usual modes of
-progression. It would not have been difficult, if we adopted Spencer’s
-mode of arguing, to show that these new forms could not possibly have
-arisen as the result of congenital variations.
-
-Footnote 19:
-
-  Wallace assumes fluctuating variation to suffice, but in this I cannot
-  agree with him.
-
-Again, it might be argued that the large, powerful dray-horse could not
-have arisen through a series of variations from the ordinary horse,
-because, even if variations in the right direction occurred in the
-fore-quarters, it is unlikely that similar variations would occur in the
-hind-quarters, etc. Yet the feat has been accomplished, and while it is
-difficult to prove that the inheritance of acquired characters has not
-had a hand in the process, it is improbable that this has been the case,
-but rather that artificial selection of some kind of variations has been
-the factor at work.
-
-So long as the Lamarckian theory is supported by arguments like these,
-it can never hope to be established with anything more than a certain
-degree of probability. If it is correct, then its demonstration must
-come from experiment. This brings us to a consideration of the
-experimental evidence which has been supposed by some writers to give
-conclusive proof of the validity of the theory.
-
-The best direct evidence in favor of the Lamarckian argument is that
-furnished by the experiments of Brown-Séquard. He found, as the result
-of injury to the nervous system of guinea-pigs, that epilepsy appeared
-in the adult animal, and that young born from these epileptic parents
-became also epileptic. Still more important was his discovery that,
-after an operation on the nerves, as a result of which certain organs,
-the ear or the leg, for instance, are affected, the same affection
-appears in the young born from such parents. These results of
-Brown-Séquard have been vouched for by two of his assistants, and his
-results in regard to the inheritance of epilepsy have been confirmed by
-Obersteiner, and by Luciani on dogs. Equally important is their later
-confirmation, as far as the main facts go, by Romanes.
-
-Brown-Séquard gives the following summary of his results. I follow
-Romanes’ translation in his book on “Darwin and after Darwin,” where
-there is also given a careful analysis of Brown-Séquard’s results, as
-well as the outcome of the experiments of Romanes himself. The summary
-is as follows:—
-
-1. “Appearance of epilepsy in animals born of parents which had been
-rendered epileptic by an injury to the spinal cord.
-
-2. Appearance of epilepsy also in animals born of parents which had been
-rendered epileptic by section of the sciatic nerve.
-
-3. A change in the shape of the ear in animals born of parents in which
-such a change was the effect of a division of the cervical sympathetic
-nerve.
-
-4. Partial closure of the eyelids in animals born of parents in which
-that state of the eyelids had been caused either by section of the
-cervical sympathetic nerve, or the removal of the superior cervical
-ganglion.
-
-5. Exophthalmia in animals born of parents in which an injury to the
-restiform body had produced that protrusion of the eyeball. This
-interesting fact I have witnessed a good many times, and seen the
-transmission of the morbid state of the eye continue through four
-generations. In these animals modified by heredity, the two eyes
-generally protruded, although in the parents usually only one showed
-exophthalmia, the lesion having been made in most cases only on one of
-the corpora restiformia.
-
-6. Hæmatoma and dry gangrene of the ears in animals born of parents in
-which these ear alterations had been caused by an injury to the
-restiform body near the nib of the calamus.
-
-7. Absence of two toes out of the three of the hind-leg, and sometimes
-of the three, in animals whose parents had eaten up their hind-leg toes,
-which had become anæsthetic from a section of the sciatic nerve alone,
-or of that nerve and also of the crural. Sometimes, instead of complete
-absence of the toes, only a part of one or two or three was missing in
-the young, although in the parent not only the toes, but the whole foot
-was absent (partly eaten off, partly destroyed by inflammation,
-ulceration, or gangrene).
-
-8. Appearance of various morbid states of the skin and hair of the neck
-and face in animals born of parents having had similar alterations in
-the same parts as effects of an injury to the sciatic nerve.”
-
-Romanes, who later went over the same ground, in part under the
-immediate direction of Brown-Séquard himself, has made some important
-observations in regard to these results, many of which he was able to
-confirm.
-
-He did not repeat the experiment of cutting the cord, but he found that,
-to produce epilepsy, it was only necessary to cut the sciatic nerve. The
-“epileptiform habit” does not appear in the animal until some time after
-the operation; it lasts for some weeks or months, and then disappears.
-The attacks are not brought on spontaneously, but by “irritating a small
-area of the skin behind the ear on the same side of the body as that on
-which the sciatic nerve had been divided.” The attack lasts for only a
-few minutes, and during it the animal is convulsed and unconscious.
-Romanes thinks that the injury to the sciatic nerve, or to the spinal
-cord, produces some sort of a change in the cerebral centres, “and that
-it is this change—whatever it is, and in whatever part of the brain it
-takes place—which causes the remarkable phenomena in question.”
-
-In regard to Brown-Séquard’s statements, made in the 3d and the 4th
-paragraphs, in respect to the results of the operation of cutting the
-cervical sympathetic, Romanes had not confirmed the results when his
-manuscript went to press; but soon afterward, after Romanes’ death, a
-note was printed in _Nature_ by Dr. Hill, announcing that two
-guinea-pigs from Romanes’ experiment had been born, “both of which
-exhibited a well-marked droop of the upper eyelid. These guinea-pigs
-were the offspring of a male and female in both of which I had produced
-for Dr. Romanes, some months earlier, a droop of the left upper eyelid
-by division of the left cervical sympathetic nerve. This result is a
-corroboration of the series of Brown-Séquard experiments on the
-inheritance of acquired characters.”
-
-Romanes states that he also found that injury to a particular spot of
-the restiform bodies is quickly followed by a protrusion of the eye on
-the same side, and further, that he had “also had many cases in which
-some of the progeny of parents thus affected have shown considerable
-protrusion of the eyeballs of both sides, and this seemingly abnormal
-protrusion has occasionally been transmitted to the next generation.
-Nevertheless, I am far from satisfied that this latter fact is anything
-more than an accidental coincidence.” This reservation is made on the
-ground that the protrusion in the young is never so great as in the
-parents, and also because there is amongst guinea-pigs a considerable
-amount of individual variation in the degree of prominence of the
-eyeballs. Romanes, while unwilling to deny that an “obviously abnormal
-amount of protrusion, due to the operation, may be inherited in lesser
-degree,” is also unwilling to affirm so important a conclusion on the
-basis of these experiments alone.
-
-In regard to Brown-Séquard’s 6th statement, Romanes found after injury
-to the restiform body that hæmatoma and dry gangrene may supervene,
-either several weeks after the operation, or at any subsequent time,
-even many months afterward. The disease usually affects the upper parts
-of both ears, and may then gradually extend downward until nearly the
-whole ear is involved. “As regards the progeny of animals thus affected
-in some cases, but by no means in all, a similarly morbid state of the
-ears may arise apparently at any time in the life history of the
-individual. But I have observed that in cases where two or more
-individuals _of the same litter_ develop this diseased condition, they
-usually do so at about the same time, even though this may be months
-after birth, and therefore after the animals are fully grown.” Moreover,
-the morbid process never extends so far in the young as it does in the
-parents, and “it almost always affects the middle third of the ear.”
-Several of the progeny from this first generation, which had apparently
-inherited the disease, but had not themselves been directly operated
-upon, showed a portion of the ear consumed apparently by the same
-disease. Romanes then gives the following significant analysis of this
-result. Since a different part of the ear of the progeny is affected,
-and also a “very much less quantity thereof,” it might seem that the
-result was due either to a mere coincidence, or to the transmission of
-microbes. But he goes on to say, that he fairly well excluded both of
-these possibilities, for, in the first place, he has never observed “the
-very peculiar process in the ears, or in any other parts of guinea-pigs
-which have neither themselves had the restiform bodies injured, nor been
-born of parents thus mutilated.” In regard to microbes, Romanes tried to
-infect the ears of normal guinea-pigs by first scarifying these parts,
-and then rubbing them with the diseased surfaces of the ears of affected
-guinea-pigs. In not a single case was the disease produced.
-
-Romanes concludes that these “results in large measure corroborate the
-statements of Brown-Séquard; and it is only fair to add that he told me
-they were the results which he had himself obtained most frequently, but
-that he had also met with many cases where the diseased condition of the
-ears in parents affected the same parts in their progeny and also
-occurred in more equal degrees.”
-
-We come now to the remarkable conclusion given in Brown-Séquard’s 7th
-statement, in regard to the absence of toes in animals whose parents had
-eaten off their own hind toes and even parts of their legs. Romanes got
-neuroses in the animals operated upon, and found that the toes might be
-eaten off; but none of the young showed any defect in these parts.
-Furthermore, Romanes repeated the same operation upon the descendants
-through six successive generations, so as to produce, if possible, a
-cumulative effect, but no inheritance of the mutilation was observed.
-“On the other hand, Brown-Séquard informed me that he had observed this
-inherited absence of toes only in about one or two per cent of cases.”
-It is possible, therefore, Romanes adds, that his own experiments were
-not sufficiently numerous to have obtained such cases.
-
-In this connection I may give an account of some observations that I
-made while carrying out some experiments in telegony with mice. I found
-in one litter of mice that when the young came out of the nest they were
-tailless. The same thing happened again when the second litter was
-produced, but this time I made my observations sooner, and examined the
-young mice immediately after birth. I found that the mother had bitten
-off, and presumably eaten, the tails of her offspring at the time of
-birth. Had I been carrying on a series of experiments to see if, when
-the tails of the parents were cut off, the young inherit the defect, I
-might have been led into the error of supposing that I had found such a
-case in these mice. If this idiosyncrasy of the mother had reappeared in
-any of her descendants, the tails might have disappeared in succeeding
-generations. This perversion of the maternal instincts is not difficult
-to understand, when we recall that the female mouse bites off the
-navel-string of each of her young as they are born, and at the same time
-eats the afterbirth. Her instinct was carried further in this case, and
-the projecting tail was also removed.
-
-Is it not possible that something of this sort took place in
-Brown-Séquard’s experiment? The fact that the adults had eaten off their
-own feet might be brought forward to indicate the possibility of a
-perverted instinct in this case also. At least my observation shows a
-possible source of error that must be guarded against in future work on
-this subject.
-
-In regard to the 8th statement of Brown-Séquard, as to various morbid
-states of the skin, Romanes did not test this, because the facts which
-it alleges did not seem of a sufficiently definite character.
-
-These experiments of Brown-Séquard, and of those who have repeated them,
-may appear to give a brilliant experimental confirmation of the
-Lamarckian position; yet I think, if I were a Lamarckian, I should feel
-very uncomfortable to have the best evidence in support of the theory
-come from this source, because there are a number of facts in the
-results that make them appear as though they might, after all, be the
-outcome of a transmitted disease, as Weismann claims, rather than the
-inheritance of an acquired character. Until we know more of the
-pathology of epilepsy, it may be well not to lay too great emphasis on
-these experiments. It should not be overlooked that during the long time
-that the embryo is nourished in the uterus of the mother, there is ample
-opportunity given for the transmission of material, or possibly even of
-bacteria. If it should prove true that epilepsy is due to some substance
-present in the nervous system, such substances could get there during
-the uterine life of the embryo. Even if this were the case, it may be
-claimed that it does not give an explanation of the local reappearance
-of the disease in the offspring. But here also we must be on our guard,
-for it is possible that only certain regions of the body are susceptible
-to a given disease; and it has by no means been shown that the local
-defect itself is inherited, but only the disease. Romanes insists that a
-very special operation is necessary to bring about certain forms of
-transmission.
-
-It is well also to keep in mind the fact, that if this sort of effect is
-inherited, then we must be prepared to accept as a possibility that
-other kinds of injury to the parent may be transmitted to the offspring.
-It would be of great disadvantage to animals if they were to inherit the
-injuries that their parents have suffered in the course of their lives.
-In fact, we might expect to find many plants and animals born in a
-dreadful state of mutilation as a result of inheritances of this sort.
-Thus, while the Lamarckians try to show that, on their principle,
-characters for the good of the species may be acquired, they must also
-be prepared, if they accept this kind of evidence, to grant that immense
-harm may also result from its action. I do not urge this as an argument
-against the theory itself, but point it out simply as one of the
-consequences of the theory.
-
-It has been shown quite recently, by Charrin, Delamare, and Moussu, that
-when, after the operation of laparotomy on a pregnant rabbit or
-guinea-pig, the kidney or the liver has become diseased, the offspring
-sometimes show similar affections in the corresponding organs (kidney or
-liver). The result is due, the authors think, to some substance set free
-from the diseased kidney of the parent that affects the kidney of the
-young in the uterus. By injecting into the blood of a pregnant animal
-fresh extracts from the kidney of another animal, the authors believe
-that the kidney of the young are also affected. It will be observed that
-this transmission of an acquired character appears to be different from
-that of transmission through the egg; for it is the developing, or
-developed organ itself, that is acted upon. The results throw an
-interesting light on the cases of epilepsy described by Brown-Séquard,
-since they show that the diseased condition of the parent may be
-transmitted to the later embryonic stages. May not, therefore,
-Brown-Séquard’s results be also explained as due to direct transmission
-from the organs of the parent to the similar organs of the young in the
-uterus?
-
-There is another series of experiments of a different sort that has been
-used as an argument in favor of the Lamarckian view. These are the
-results that Cunningham has obtained on young flatfish. He put the very
-young fish, while still bilaterally symmetrical (in which stage the
-pigment is equally developed on both sides of the body) into aquaria
-lighted from below. He found that when the young fish begins to undergo
-its metamorphosis, the pigment gradually disappears on one side, as it
-would have done under normal conditions, _i.e._ when they are lighted
-from above. If, however, the fish are kept for some time longer, lighted
-from below, the pigment begins to come back again. “The first fact
-proves that the disappearance of the pigment-cells from the lower side
-in the metamorphosis is an hereditary character, and not a change
-produced in each individual by the withdrawal of the lower side from the
-action of light. On the other hand, the experiments show that the
-absence of pigment-cells from the lower side throughout life is due to
-the fact that light does not act upon that side, for, when it is allowed
-to act, pigment-cells appear. It seems to me that the only reasonable
-conclusion from these facts is, that the disappearance of pigment-cells
-was originally due to the absence of light, and that the change has now
-become hereditary. The pigment-cells produced by the action of light on
-the lower side are in all respects similar to those normally present on
-the upper side of the fish. If the disappearance of the pigment-cells
-were due entirely to a variation of the germ-plasm, no external
-influence could cause them to reappear, and, on the other hand, if there
-were no hereditary tendency, the coloration of the lower side of the
-flatfish when exposed would be rapid and complete.”[20]
-
-Footnote 20:
-
-  _Natural Science_, October, 1893.
-
-This evidence might be convincing were it not weakened by two or three
-assumptions. In the first place, it is not shown that if the loss of
-color on the lower side had been the result of the inheritance of an
-acquired character that the results seen in Cunningham’s experiment
-would follow as a consequence. Thus one of the starting-points of the
-argument really begs the whole question. In the second place, it is
-unproven that, had the loss of color of the lower side been the result
-of a variation of the germ-plasm, no external influence could cause it
-to reappear. In this connection there is another fact that has a bearing
-on the point here raised. In some species of flatfish the right side is
-turned down, and in other species the left. Occasionally an individual
-is found in a right-sided species that is left-sided, and in such cases
-the color is also reversed. Now, to explain this in the way suggested by
-Cunningham, we should be obliged to assume that some of the ancestors
-acquired the loss of pigment on one side of the body, and others on the
-other side according to which side was turned down. This supposition
-might be appealed to to give us an explanation of the occasional
-reversal of the symmetry as a rare occurrence at the present time; but
-the argument is so transparently improbable that, I believe, the
-Lamarckian school would hesitate to make use of it, yet, in principle,
-it is about the same as that Cunningham has followed above.
-
-If, on the other hand, we suppose the difference in color of the two
-sides to have been the result of a germ-variation, we need only suppose
-that this was of such a kind that the color of the under side is only in
-a latent condition, and if an external factor can cause a reaction to
-take place on the light side, it is not surprising that this should call
-forth the latent color patterns. The result can be given at least a
-formal explanation on the theory that the original change was a
-germ-variation.
-
-We come now to the evidence derived from paleontology. A number of
-evolutionists, more especially of the American school, have tried to
-show that the evolution of a number of groups can best be accounted for
-on the theory of the inheritance of acquired characters. A point that we
-must always bear in mind is that evolution in a direct line need not
-necessarily be the outcome of Lamarckian factors. Some of our leading
-paleontologists, Cope, Hyatt, Scott, Osborn, have been strongly
-impressed by the paleontological evidence in favor of the view that
-evolution has often been in direct lines; and some, at least, of these
-investigators have been led to conclude that only the Lamarckian factor
-of the inheritance of acquired characters can give a sufficient
-explanation of the facts. Paleontologists have been much impressed by
-the fact that evolution has been along the lines which we might imagine
-that it would follow if the effects of use and of disuse are inherited.
-There is, however, no proof that this is the case, although there are a
-number of instances to which this mode of explanation appears to give
-the readiest solution. But, as has been said before, it is not this kind
-of evidence that the theory is in need of, since Lamarck himself gave an
-ample supply of illustrations. What we need is clear evidence that this
-sort of inheritance is possible, and, from the very nature of the case,
-it is just this evidence that fossil remains can never supply.
-
-The same criticism may be made of the work of Ryder, Packard, Dali,
-Jackson, Eimer, Cunningham, Semper, De Varigny, and others of the
-Lamarckian school. Despite the large number of cases that they have
-collected, which appear to them to be most easily explained on the
-assumption of the inheritance of acquired characters, the proof that
-such inheritance is possible is not forthcoming. Why not then spend a
-small part of the energy, that has been used to expound the theory, in
-demonstrating that such a thing is really possible? One of the chief
-virtues of the Lamarckian theory is that it is capable of experimental
-verification or contradiction, and who can be expected to furnish such
-proof if not the Neo-Lamarckians?
-
-We may fairly sum up our position in regard to the theory of the
-inheritance of acquired characters in the verdict of “not proven.” I am
-not sure that we should not be justified at present in claiming that the
-theory is unnecessary and even improbable.
-
-
-------------------------------------------------------------------------
-
-
-
-
-                              CHAPTER VIII
-
-          CONTINUOUS AND DISCONTINUOUS VARIATION AND HEREDITY
-
-
-The two terms _continuous_ and _discontinuous variation_ refer to the
-succession or inheritance of the variations rather than to the actual
-conditions amongst a group of individuals living at the same time; but
-this distinction has only a subordinate value. The term _fluctuating_,
-or _individual variation_, expresses more nearly the conditions of the
-individuals of a species at any one time, and the continuation of this
-sort of difference is the continuous variation spoken of above. The
-discontinuous variations are probably of the same nature as those that
-have been called mutations, and what Darwin sometimes called sports, or
-single variations, or definite variations.
-
-
-                          Continuous Variation
-
-If we examine a number of individuals of the same species, we find that
-no two of them are exactly alike in all particulars. If, however, we
-arrange them according to some one character, for example, according to
-the height, we find that there is a gradation more or less perfect from
-one end of the series to the other. Thus, if we were to take at random a
-hundred men, and stand them in line arranged according to their height,
-the tops of their heads, if joined, would form a nearly continuous line;
-the line will, of course, incline downward from the tallest to the
-shortest man. This illustrates individual variation. An arrangement of
-this kind fails to bring out one of the most important facts connected
-with individual differences. If the line is more carefully examined, it
-will be found that somewhere near the middle the men are much more
-nearly of the same height, or rather there are more men having about the
-same height than there are near the ends of the line. Another
-arrangement will bring this out better. If we stand in a line all the
-men from 60 to 61.9 inches, and in another parallel line all those
-between 62 and 63.9, then those between 64 and 65.9, then between 66 and
-67.9 inches in__ height, etc., it will be found that there are more men
-in some of these lines than in others. The longest line will be that
-containing the men of about 65 inches; the two lines formed out of men
-on each side of this one will contain somewhat fewer men, and the next
-ones fewer still, and so on. If we looked at our new group of men from
-above, we should have a figure triangular in outline, the so-called
-frequency polygon, Figure 3 B. With a larger amount of data of this sort
-it is possible to construct a curve, the curve of frequency, Figure 3 A.
-In order to obtain this curve of frequency, it is of course not
-necessary to actually put the individuals in line, but the curve can be
-drawn on paper from the measurements. We sort out the measurements into
-classes as in the case given above. The classes are laid off at regular
-intervals along a base-line by placing points at definite intervals.
-Perpendiculars are then erected at each point, the height of each being
-proportional to the frequency with which each class occurs. If now we
-join the tops of these perpendiculars, the curve of frequency is the
-result.
-
-
-[Illustration:
-
-  Fig. 3.—Curves of frequency, etc.
-  A, normal curve.
-  B, showing the method of arranging individuals in lines containing
-    similar kinds of individuals.
-  C, curve that is skew to the right.
-  D, polygon of frequencies of horns of rhinoceros beetles.
-  (After Davenport.)]
-
-“In arranging the individuals it will be found, as has been said, that
-certain groups contain more individuals. They will form the longest
-line. This value that occurs with the greatest frequency is called the
-mode. The position of this modal class in the polygon is one of the
-points of importance, and the spread of the polygon at its base is
-another. A polygon with a low mode and a broad range means great
-variability. The range may, however, be much affected by a single
-individual standing far removed from the rest, so that a polygon
-containing such an individual might appear to show greater variation
-than really exists. Therefore we need a measure of variability that
-shall take into account the departures of all the individuals from the
-mode. One such measure is the arithmetical average of all the departures
-from the mean in both directions; and this measure has been widely
-employed. At present another method is preferred, namely, the square
-root of the squared departures. This measure is called the standard
-deviation. The standard deviation is of great importance, because it is
-the index of variability.”[21]
-
-Footnote 21:
-
-  Davenport, C. B., “The Statistical Study of Biological Problems,”
-  _Popular Science Monthly_, September, 1900.
-
-Of the different kinds of polygons there are two main sorts, the simple
-and the complex. The former have only a single mode, the latter have
-more than one mode. Some simple polygons lie symmetrically on each side
-of the mode, Figure 3 A; others are unsymmetrical or skew, Figure 3 B.
-The skew polygon generally extends out on one side farther than on the
-other. It has been suggested that when a polygon is symmetrical the
-species is not changing, and when skew that the species is evolving in
-the direction of the longer base. This assumes that the sort of
-variation measured by these curves is of the kind of which evolution is
-made up, but this is a question that we must further consider. How far
-the change indicated by the skew curve may be carried is also another
-point for further examination.
-
-A complex polygon of variation, Figure 3 D, has been sometimes
-interpreted to mean that two subgroups exist in a species, as is well
-shown in the case of the rhinoceros beetle described by Bateson. Two
-kinds of male individuals exist, some with long horns, others with short
-horns; each with a mode of its own, the two polygons overlapping. Other
-complex polygons may be due to changes occurring at different times in
-the life of the individual, as old age, for example.
-
-If, instead of examining the variations of the individuals of the race,
-we study the variations in the different organs of the same individual,
-we find in many cases that certain organs vary together. Thus the right
-and the left leg nearly always vary in the same direction, also the
-first joints of the index and middle fingers, and the stature and the
-forearm. On the other hand, the length of the clavicle and that of the
-humerus do not vary together to the same extent; and the breadth and
-height of the skull even less so.
-
-
- ════════════╤════╤════╤════╤════╤════╤════╤════╤════╤════╤════╤════╤════╤════
- No. of Veins│  10│  11│  12│  13│  14│  15│  16│  17│  18│  19│  20│  21│  22
- ────────────┼────┼────┼────┼────┼────┼────┼────┼────┼────┼────┼────┼────┼────
- First Tree  │   —│   —│   —│   —│   —│   1│   4│   7│   9│   4│   1│   —│   —
- Second Tree │   —│   —│   —│   3│   4│   9│   8│   2│   —│   —│   —│   —│   —
- ════════════╧════╧════╧════╧════╧════╧════╧════╧════╧════╧════╧════╧════╧════
-
-
-We may also study those cases in which a particular organ is repeated a
-number of times in the same individual, as are the leaves of a tree. If
-the leaves of the same tree are examined in respect, for example, to the
-number of veins that each contains, we find that the number varies, and
-that the results give a variation polygon exactly like that when
-different individuals are compared with one another. Let us take the
-illustration given by Pearson. He counted the veins on each side of the
-midrib of the leaves of the beech. If a number of leaves be collected
-from one tree, and the same number from another, and if all those having
-fifteen veins are put in one vertical column, and all those with sixteen
-in another, as shown in the following table, it will be found that each
-tree has a mode of its own. Thus in the first tree the mode is
-represented by nine individuals having eighteen veins, and in the second
-by nine individuals having fifteen veins. So far as this character is
-concerned we might have interchanged certain of the individual leaves,
-but we could not have interchanged the two series. They are _individual_
-to the two trees. Now in what does this individuality consist? Clearly
-there are most leaves in one tree with eighteen ribs, and most in the
-other with fifteen ribs.
-
-If we contrast these results with those obtained by picking at random a
-large number of leaves from different beech trees, we have no longer
-types of individuals, but racial characters. Pearson has given the
-following table to illustrate these points:
-
-
-              Frequency of Different Types of Beech Leaves
-
- ════════════╤════╤════╤════╤════╤════╤════╤════╤════╤════╤════╤════╤════╤════
- No. of Veins│  10│  11│  12│  13│  14│  15│  16│  17│  18│  19│  20│  21│  22
- ────────────┼────┼────┼────┼────┼────┼────┼────┼────┼────┼────┼────┼────┼────
- Frequency   │   1│   7│  34│ 110│ 318│ 479│ 595│ 516│ 307│ 181│  36│  15│   1
- ════════════╧════╧════╧════╧════╧════╧════╧════╧════╧════╧════╧════╧════╧════
-
-
-Thus the mode for beech trees in general is sixteen; but, as shown in
-the other table, this mode does not correspond with either of the two
-individual modes here ascertained. The illustration shows that the
-racial mode may differ from the individual mode. There are also cases
-known in which the mode of a group of individuals living in one locality
-is different from that of another group living in another locality. This
-difference may be a constant one from year to year, although so slight,
-that unless actual measurements are made, the difference cannot be
-detected, because of the overlapping of the individuals from different
-localities. If evolution took place by slow changes of this sort, it
-might be possible to detect its action, even when very slow, by means of
-measurements made on a large number of individuals. At least this has
-been suggested by those who believe new species may result from changes
-of this sort.
-
-There is some evidence showing that by selecting particular individuals
-of a series, and breeding from them, the mode may be changed in the
-direction of selection. Thus it has been stated by Davenport that the
-descendants of twelve- and thirteen-rayed daisies give a polygon with a
-skewness of +1.92; while the descendants of twenty-one-rayed plants give
-a polygon with a skewness of -.13.
-
-Pearson has described very concisely the possibilities involved in the
-selective action of the environment. He states that if we examine the
-frequency distribution of a set of organisms that have just become
-mature, and later make a similar examination on the same number of
-individuals (but not the same individuals) during the period of
-reproduction, we shall probably find that a change has taken place which
-may have been due to selection of some sort. The same thing might be
-found in the next generation, and, if it did, this would indicate that
-“selection does not necessarily mean a permanent or a progressive
-change.” The selection in this imaginary case would be purely periodic
-and suffice only to maintain a given race under given conditions. “Each
-new adolescent generation is not the product of the entire preceding
-generation, but only of selected individuals. This is certainly the case
-for civilized man, in which case twenty-six per cent of the married
-population produce fifty per cent of the next generation.”
-
-Pearson believes that “if a race has been long under the same
-environment it is probable that only periodic selection is at work,
-maintaining its stability. Change the environment and a secular change
-takes place, the deviations from the mode previously destroyed giving
-the requisite material.” “Clearly periods of rapidly changing
-environment, of great climatological and geological change, are likely
-to be associated with most marked secular selection. To show that there
-is little or no change year by year in the types of rabbit and wild
-poppy in our English fields, or of daphnia in our English ponds, is to
-put forward no great argument for the inefficiency of natural selection.
-Take the rabbit to Australia, the wild poppy to the Cape, the daphnia
-into the laboratory, and change their temperature, their food supply,
-and the chemical constituents of water and air, and then the existence
-of no secular selection would indeed be a valid argument against the
-Darwinian theory of evolution.” In regard to the last point, it should
-be noted that, even if under the changed conditions a change in the mode
-took place, as Pearson assumes, it does not follow necessarily that
-selection has had anything to do with it, but the environment may have
-directly changed the forms. Furthermore, and this is the essential
-point, even if selection does act to the extent of changing the mode, we
-should not be justified in concluding that this sort of change could go
-on increasing as long as the selection lasts. All that might happen
-would be to keep the species up to the highest point to which
-fluctuating variation can be held. This need not lead to the formation
-of new species, or direct the course of evolution.
-
-Pearson points out further that, even if we suppose that a secular
-change is produced in a new environment, we cannot explain how species
-may break up into two or more races that are relatively infertile.
-Suppose two groups of individuals, subjected to different environments,
-become isolated geographically. Two local races will be produced.
-“Isolation may account for the origin of local races, but never for the
-origin of species unless it is accompanied by a differential fertility.”
-In other words, Pearson thinks that, unless the reproductive organs are
-correlated with other organs, in such a way that as these organs change
-the interracial fertility of the germ-cells is altered, so that in the
-two changed groups the individuals are no longer interfertile, new
-species cannot be accounted for, since their mutual infertility is one
-of their most characteristic features. “Without a barrier to
-intercrossing during differentiation the origin of species seems
-inexplicable.”
-
-We need not discuss the various suggestions that have been made to
-explain this difficulty, none of which, as Pearson points out, have been
-satisfactory. He himself believes that a process of segregation of like
-individuals must occur, during the incipient stages at least, in the
-formation of species. Afterwards a correlation may exist between the new
-organs and the germ-cells, of such a sort that a relative or an absolute
-sterility between the incipient species is attained. After this
-condition has been reached the two new species may freely intermix
-without a return to the primitive type, since they are no longer fertile
-_inter se_. It seems to me, also, that this would be an essential
-requisite if we assume that species are slowly formed out of races from
-individual differences, as Pearson supposes to be the case. There are,
-however, other possibilities that Pearson does not take into account,
-namely, that from the very beginning the change may be so great that the
-new form is not fertile with the original one; and there is also another
-possibility as well, that, although the new and the old forms are
-fertile, the hybrids may be like one or the other parent, as in several
-cases to be given later. Not that I mean to say that in either of these
-two ways can we really offer a solution of the question of infertility,
-for, from the evidence that we possess, it appears improbable that the
-infertility of species _inter se_ has been the outcome of either of
-these causes.
-
-In support of his main thesis Pearson gives certain data in respect to
-preferential mating in the human race. By this is meant that selection
-of certain types of individuals is more likely to take place, and also
-that the fertility of certain types of individuals is greater than that
-of other types. The calculations are based on stature, color of hair,
-and of eyes. The results appear to show in all cases examined that there
-is a slight tendency to form new races as the result of the more
-frequent selection of certain kinds of individuals. But even if this is
-the case, what more do the results show than that local races may be
-formed,—races having a certain mode for height, for color of eyes or of
-hair? That changes of this kind can be brought about we knew already
-without any elaborate measurements, yet we should not conclude from this
-that new species will be formed by a continuation of the process.
-
-Pearson writes: “As to the problem of evolution itself we are learning
-to see it under a new light. Natural selection, combined with sexual
-selection [by which Pearson means segregation of certain types through
-individual selection] and heredity, is actually at work changing types.
-We have quantitative evidence of its effects in many directions.” Yes!
-but no evidence that selection of this sort can do anything more than
-keep up the type to the upper limit attained in each generation by
-fluctuating variations. Pearson adds, “Variations do not occur
-accidentally, or in isolated instances; autogamic and assortive mating
-are realities, and the problem of the near future is not whether
-Darwinism is a reality, but what is quantitively the rate at which it is
-working and has worked.” This statement expresses no more than Pearson’s
-conviction that the process of evolution has taken place by means of
-selection. He ignores other possibilities, which if established may put
-the whole question in a very different light.
-
-
-                   Heredity and Continuous Variation
-
-It has been to a certain extent assumed in the preceding pages that both
-parents are alike, or, if different, that they have an equal influence
-on the offspring. This may be true in many cases for certain
-characteristics. Thus a son from a tall father and a short mother may be
-intermediate in height, or if the father is white and the mother black,
-the children are mulattoes. But other characters rarely or never blend.
-In such cases the offspring is more like one or the other parent, in
-which case the inheritance is said to be exclusive. Thus if one parent
-has blue eyes and the other black, some of the children may have black
-eyes and others blue. There are also cases of particular inheritance
-where there may be patches of color, some like the color of one parent,
-some like that of the other parent. The latter two kinds of inheritance
-will be more especially considered in the subsequent part of this
-chapter; for the present we are here chiefly concerned with blended
-characters.
-
-How much in such cases does each parent contribute to the offspring?
-This has been expressed by Galton in his law of ancestral heredity. This
-law takes into account not only the two parents, but also the four
-grandparents, and the eight great-grandparents, etc. There will be 1024
-in the tenth generation. These 1024 individuals may be taken as a fair
-sample of the general population, provided there has not been much
-interbreeding. Are we then to look upon the individual as the fused or
-blended product of the population a few generations back? If this were
-true, should we not expect to find all the individuals of a community
-very much alike, except for the fluctuating variations close around the
-mode?
-
-As a result of his studies on the stature of man, and on the coat color
-of the Basset hounds, Galton has shown that the inheritance from the
-parents can be represented by the fraction 1/2; that is one-half of the
-peculiarities of the individual comes from the two parents. The four
-grandparents together count for 1/4 of the total inheritance, the
-great-grandparents 1/8, and so on, giving the series 1/2, 1/4, 1/8.
-Pearson, taking certain other points into consideration, believes the
-following series more fully represents the inheritance from the
-ancestors, .3, .15, .075, .0375, etc. He concludes that, “if Darwinism
-be the true view of evolution, _i.e._ if we are to describe evolution by
-natural selection combined with heredity, then the law which gives us
-definitely and concisely the type of the offspring in terms of the
-ancestral peculiarities is at once the foundation stone of biology and
-the basis upon which heredity becomes an exact branch of science.”
-
-The preceding statements give some idea of what would occur in a
-community in which no selection was taking place. The results will be
-quite different, although the same general law of inheritance will hold,
-if selection takes place in each generation. If, for instance, selection
-takes place, the offspring after four generations will have .93 of the
-selected character, and without further selection will not regress, but
-breed true to this type.[22] “After six generations of selection the
-offspring will, selection being suspended, breed true to under two per
-cent divergence from the previously selected type.”
-
-Footnote 22:
-
-  In this statement the earlier ancestors are assumed to be identical
-  with the general type of the population.
-
-If, however, we do not assume that the ancestors were mediocre, it is
-found that after six generations of selection the offspring will breed
-true to the selected type within one per cent of its value. Thus, if
-selection were to act on a race of men having a mode of 5 feet 9 inches,
-and the 6-foot men were selected in each generation, then in six
-generations this type would be permanently established, and this change
-could be effected in two hundred years.[23]
-
-Footnote 23:
-
-  Quoted from Pearson’s “Grammar of Science.”
-
-Thus we have exact data as to what will happen on the average when
-blended, fluctuating variations are selected. Important as such data
-must always be to give us accurate information as to what will occur if
-things are left to “chance” variations, yet if it should prove true that
-evolution has not been the outcome of chance, then the method is
-entirely useless to determine how evolution has occurred.
-
-More important than a knowledge of what, according to the theory of
-chances, fluctuating variations will do, will be information that would
-tell us what changes will take place in each individual. In this field
-we may hope to obtain data no less quantitative than those of chance
-variations, but of a different kind. A study of some of the results of
-discontinuous variation will show my meaning more clearly.
-
-
-                        Discontinuous Variation
-
-Galton, in his book on “Natural Inheritance,” points out that “the
-theory of natural selection might dispense with a restriction for which
-it is difficult to see either the need or the justification, namely,
-that the course of evolution always proceeds by steps that are severally
-minute and that become effective only through accumulation.” An apparent
-reason, it is suggested, for this common belief “is founded on the fact
-that whenever search is made for intermediate forms between widely
-divergent varieties, whether they are of plants or of animals, of
-weapons or utensils, of customs, religion, or language, or of any other
-product of evolution, a long and orderly series can usually be made out,
-each member of which differs in an almost imperceptible degree from the
-adjacent specimens. But it does not at all follow because these
-intermediate forms have been found to exist, that they were the very
-stages that were passed through in the course of evolution. Counter
-evidence exists in abundance, not only of the appearance of considerable
-sports, but of their remarkable stability in hereditary transmission.”
-Comparing such an apparently continuous series with machines, Galton
-concludes, “If, however, all the variations of any machine that had ever
-been invented were selected and arranged in a museum, each would differ
-so little from its neighbors as to suggest the fallacious inference that
-the successive inventions of that machine had progressed by means of a
-very large number of hardly discernible steps.”
-
-Bateson, also, in his “Materials for the Study of Variation,” speaks of
-the two possible ways in which variations may arise. He points out that
-it has been tacitly assumed that the transitions have been continuous,
-and that this assumption has introduced many gratuitous difficulties.
-Chief of these is the difficulty that in their initial and imperfect
-stages many variations would be useless. “Of the objections that have
-been brought against the Theory of Natural Selection, this is by far the
-most serious.” He continues: “The same objection may be expressed in a
-form which is more correct and comprehensive. We have seen that the
-differences between species on the whole are Specific, and are
-differences of kind forming a discontinuous Series, while the
-diversities of environment to which they are subject are, on the whole,
-differences of degree, and form a continuous Series; it is, therefore,
-hard to see how the environmental differences can thus be made in any
-sense the directing cause of Specific differences, which by the Theory
-of Natural Selection they should be. This objection of course includes
-that of the utility of minimal Variations.”
-
-“Now the strength of this objection lies wholly in the supposed
-continuity of the process of Variation. We see all organized nature
-arranged in a discontinuous series of groups differing from each other
-by differences which are Specific; on the other hand, we see the diverse
-environments to which these forms are subject passing insensibly into
-each other. We must admit, then, that if the steps by which the diverse
-forms of life have varied from each other have been insensible,—if, in
-fact, the forms ever made up a continuous series,—these forms cannot
-have been broken into a discontinuous series of groups by a continuous
-environment, whether acting directly as Lamarck would have, or as
-selective agent as Darwin would have. This supposition has been
-generally made and admitted, but in the absence of evidence as to
-Variation it is nevertheless a gratuitous assumption, and, as a matter
-of fact, when the evidence as to Variation is studied, it will be found
-to be in a great measure unfounded.”
-
-There is a fair number of cases on record in which discontinuous
-variations have been seen to take place. Darwin himself has given a
-number of excellent examples, and Bateson, in the volume referred to
-above, has brought together a large and valuable collection of facts of
-this kind.
-
-Some of the most remarkable of these instances have been already
-referred to and need only be mentioned here. The black-shouldered
-peacock, the ancon ram, the turnspit dog, the merino sheep, tailless and
-hornless animals, are all cases in point. In several of these it has
-been discovered that the young inherit the peculiarities of their
-parents if the new variations are bred together; and what is more
-striking, if the new variation is crossed with the parent form, the
-young are like one or the other parent, and not intermediate in
-character. This latter point raises a question of fundamental importance
-in connection with the origin of species.
-
-Darwin states that he knows of _no cases in which, when different
-species or even strongly marked varieties are crossed, the hybrids are
-like one form or the other_. They show, he believes, always a blending
-of the peculiarities of the two parents. He then makes the following
-significant statement: “All the characters above enumerated which are
-transmitted in a perfect state to some of the offspring and not to
-others—such as distinct colors, nakedness of skin, smoothness of leaves,
-absence of horns or tail, additional toes, pelorism, dwarfed structure,
-etc., have all been known to appear suddenly in individual animals or
-plants. From this fact, and from the several slight, aggregated
-differences which distinguish domestic races and species from each
-other, not being liable to this peculiar form of transmission, we may
-conclude that it is in some way connected with the sudden appearance of
-the characters in question.”
-
-Darwin has, incidentally, raised here a question of the most
-far-reaching import. If it should prove true, as he believes, that
-inheritance of this kind of discontinuous variation is also
-discontinuous, and that we do not get the same result when distinct
-species are intercrossed, or even when well-marked domestic races are
-interbred, then he has, indeed, placed a great obstacle in the path of
-those who have tried to show that new species have arisen through
-discontinuous variation of this sort.
-
-If wild species, when crossed, give almost invariably intermediate
-forms, then it may appear that we are going against the only evidence
-that we can hope to obtain if we claim that discontinuous variation, of
-the kind that sports are made of, has supplied the material for
-evolution. If, furthermore, when distinct races of domesticated animals
-are crossed, we do not get discontinuous inheritance, it might, perhaps,
-with justness be claimed that this instance is paralleled by what takes
-place when wild species are crossed. And if domesticated forms have been
-largely the result of the selection of fluctuating variations, as Darwin
-believes, then a strong case is apparently made out in favor of Darwin’s
-view that continuous variation has given the material for the process of
-evolution in nature. Whether selection or some other factor has directed
-the formation of the new species would not, of course, be shown, nor
-would it make any difference in the present connection.
-
-Before we attempt to reach a conclusion on this point let us analyze the
-facts somewhat more closely.
-
-In the first place, a number of these cases of discontinuous variation
-are of the nature of abnormalities. The appearance of extra fingers or
-toes in man and other mammals is an example of this sort. This
-abnormality is, if inherited at all, inherited completely; that is, if
-present the extra digit is perfect, and never appears in an intermediate
-condition, even when one of the parents was without it. The most obvious
-interpretation of this fact is that when the material out of which the
-fingers are to develop is divided up, or separated into its component
-parts, one more part than usual is laid down. Similarly, when a flower
-belonging to the triradiate type gives rise to a quadriradiate form,—as
-sometimes occurs,—the new variation seems to depend simply on the
-material being subdivided once more than usual; perhaps because a little
-more of it is present, or because it has a somewhat different shape. My
-reasons for making a surmise of this sort are based on certain
-experimental facts in connection with the regeneration of animals. It
-has been shown in several cases that it is possible to produce more than
-the normal number of parts by simply dividing the material so that each
-part becomes more or less a new whole, and the total number of parts
-into which the material becomes subdivided is increased. It seems not
-improbable that phenomena of this sort have occurred in the course of
-evolution, although it is, of course, possible that those characters
-that define species do not belong to this class of variation. To take an
-example. There are nine neck-vertebræ in some birds, but in the swan the
-number is twenty-five. We cannot suppose that the ancestor of the swan
-gradually added enough materially to make up one new vertebra and then
-another, but at least one new whole vertebra was added at a time; and we
-know several cases in which the number of vertebræ in the neck has
-suddenly been increased by the addition of one more than normal, and the
-new vertebra is perfectly formed from the first.
-
-In cases of this sort we can easily understand that the inheritance must
-be either of one kind or the other, since intermediate conditions are
-impossible, when it comes to the question of one or not one; but if one
-individual had one and another six vertebræ, then it would be
-theoretically possible for the hybrid to have three.
-
-This brings us to a question that should have been spoken of before in
-regard to the inheritance of discontinuous variation. It sometimes
-occurs that a variation, which appears in other respects to be
-discontinuous, is inherited in a blended form. Thus the two kinds of
-variation may not always be so sharply separated as one might be led to
-believe. There may be two different kinds of discontinuous variation in
-respect to inheritance, or there may be variations that are only to a
-greater or a less extent inherited discontinuously; and it seems not
-improbable that both kinds occur.
-
-This diversion may not appear to have brought us any nearer to the
-solution of the difficulty that Darwin’s statement has emphasized,
-except in so far as it may show that the lines are not so sharply drawn
-as may have seemed to be the case. The solution of the difficulty is, I
-believe, as follows:—
-
-_The discontinuity referred to by Darwin relates to cases in which only
-a single step (or mutation) has been taken, and it is a question of
-inheritance of one or not one. If, however, six successive steps should
-be taken in the same direction, then when such a form is crossed with
-the original form, the hybrid may inherit only three of the steps and
-stand exactly midway between the parent forms; or it may inherit four,
-or five, or three, or two steps and stand correspondingly nearer to the
-one_ _or to the other parent. Thus while it may not be possible to halve
-a single step (hence one-sided inheritance), yet when more than one step
-has been taken the inheritance may be divided. There is every evidence
-that most of the Linnæan (wild) species that Darwin refers to have
-diverged from the parent form, and from each other, by a number of
-successive steps; hence on crossing, the hybrid often stands somewhere
-between the two parent forms. On this basis not only can we meet
-Darwin’s objection, but the point of view gives an interesting insight
-into the problem of inheritance and the formation of species._
-
-The whole question of inheritance has assumed a new aspect; first on
-account of the work of De Vries in regard to the appearance of
-discontinuous variation in plants; and secondly, on account of the
-remarkable discoveries of Gregor Mendel as to the laws of inheritance of
-discontinuous variations. Mendel’s work, although done in 1865, was long
-neglected, and its importance has only been appreciated in the last few
-years. We shall take up Mendel’s work first, and then that of De Vries.
-
-
-                            Mendel’s Law[24]
-
-Footnote 24:
-
-  Bateson, in his book on “Mendel’s Principles of Heredity,” has given
-  an admirable presentation of Mendel’s results. I have relied largely
-  on this in my account.
-
-The importance of Mendel’s results and their wide application is
-apparent from the results in recent years of De Vries, Correns,
-Tschermak, Bateson, Castle, and others. Mendel carried out his
-experiments on the pea, _Pisum sativum_. Twenty-two varieties were used,
-which had been proven by experiment to be pure breeds. When crossed they
-gave perfectly fertile offspring. Whether they all have the value of
-varieties of a single species, or are different subspecies, or even
-independent species, is of little consequence so far as Mendel’s
-experiments are concerned. The flower of the pea is especially suitable
-for experiments of this kind. It cannot be accidentally fertilized by
-foreign pollen, because the reproductive organs are inclosed in the keel
-of the flower, and, as a rule, the anthers burst and cover the stigma of
-the same flower with its own pollen before the flower opens. In order to
-cross-fertilize the plants it is necessary to open the young buds before
-the anthers are mature and carefully remove all the anthers. Foreign
-pollen may be then, or later, introduced.
-
-The principle involved in Mendel’s law may be first stated in a
-theoretical case, from which a certain complication that appears in the
-actual results may be removed.
-
-If _A_ represent a variety having a certain character, and _B_ another
-variety in which the same character is different, let us say in color,
-and if these two individuals, one of each kind, are crossed, the hybrid
-may be represented by _H_. If a number of these hybrids are bred
-together, their descendants will be of three kinds; some will be like
-the grandparent, _A_, in regard to the special character that we are
-following, some will be like the other grandparent, _B_, and others will
-be like the hybrid parent, _H_. Moreover, there will be twice as many
-with the character _H_, as with _A_, or with _B_.
-
-
-  A   B
-   ↘ ↙
-    H
-   ↙|↘
-  A | B
- ↙  |  ↘
-A   |   B
-    H
-   ↙|↘
-  A | B
- ↙  |  ↘
-A   |   B
-    H
-   ↙|↘
-  A | B
-    H
-
-
-If now we proceed to let these _A_’s breed together, it will be found
-that their descendants are all _A_, forever. If the _B_’s are bred
-together they produce only _B_’s. But when the _H_’s are bred together
-they give rise to _H_’s, _A_’s, and _B_’s, as shown in the accompanying
-diagram. In each generation, the _A_’s will also breed true, the _B_’s
-true, but the _H_’s will give rise to the three kinds again, and always
-in the same proportion.
-
-Thus it is seen that the hybrid individuals continue to give off the
-pure original forms, in regard to the special character under
-consideration. The numerical relation between the numbers is also a
-striking fact. Its explanation is, however, quite simple, and will be
-given later.
-
-In the actual experiment the results appear somewhat more complicated
-because the hybrid cannot be distinguished from one of the original
-parents, but the results really conform exactly to the imaginary case
-given above. The accompanying diagram will make clearer the account that
-follows.
-
-
- A      B
-  ↘    ↙
-   ↘  ↙
-   A(B)
-  ↙ | ↘
- ↙  |  ↘
-A   |   B
-    |
-   A(B)
-  ↙ | ↘
- ↙  |  ↘
-A   |   B
-    |
-   A(B)
-  ↙ | ↘
- ↙  |  ↘
-A   |   B
-    |
-   A(B)
-
-
-The hybrid, _A_(_B_), produced by crossing _A_ and _B_ is like _A_ so
-far as the special character that we will consider is concerned. In
-reality the character that _A_ stands for is only dominant, that is, it
-has been inherited discontinuously, while the other character,
-represented by _B_, is latent, or recessive as Mendel calls it.
-Therefore, in the table, it is included in parentheses. If the hybrids,
-represented by this form _A_(_B_), are bred together, there are produced
-two kinds of individuals, _A_’s and _B_’s, of which there are three
-times as many _A_’s as _B_’s. It has been found, however, that some of
-these _A_’s are pure forms, as indicated by the _A_ on the left in our
-table, while the others, as shown by their subsequent history, are
-hybrids, _A_(_B_). There are also twice as many of these _A_(_B_)’s as
-of the pure _A_’s (or of the _B_’s). Thus the results are really the
-same as in our imaginary case, only obscured by the fact that the _A_’s
-and the _A_(_B_)’s are exactly alike to us in respect to the character
-chosen. We see also why there appear to be three times as many _A_’s as
-_B_’s. In reality the results are 1 _A_, 2 _A_(_B_), 1 _B_.
-
-In subsequent generations the results are the same as in this one, the
-_A_’s giving rise only to _A_, the _B_’s to _B_, and the _A_(_B_)’s
-continuing to split up into the three forms, as shown in our diagram.
-Mendel found the same law to hold for all the characters he examined,
-including such different ones as the form of the seed, color of
-seed-albumen, coloring of seed-coat, form of the ripe pods, position of
-flowers, and length of stem.
-
-Mendel also carried out a series of experiments in which several
-differentiating characters are associated. In the first experiment the
-parental plants (varieties) differed in the form of the seed and in the
-color of the albumen. The two characters of the seed plant are
-designated by the capital letters _A_ and _B_; and of the pollen plant
-by small _a_ and _b_. The hybrids will be, of course, combinations of
-these, although only certain characters may dominate. Thus in the
-experiments, the parents are _AB_ (seed plant) and _ab_ (pollen plant),
-with the following seed characters:—
-
-
-   Seed parent   {A form round           Pollen parent     {a form angular
-      _AB_       {B albumen yellow            _ab_         {b albumen green
-
-
-When these two forms were crossed the seeds appeared round and yellow
-like those of the parent, _AB_, _i.e._ these two characters dominated in
-the hybrid.
-
-The seeds were sown, and in turn yielded plants which when
-self-fertilized gave four kinds of seeds (which frequently all appeared
-in the same pod). Thus 556 seeds were produced by 15 plants, having the
-following characters:—
-
-
-          _AB_ 315 round and yellow
-          _Ab_ 101 angular and yellow
-          _aB_ 108 round and green
-          _ab_ 32 angular and green
-
-
-These figures stand almost in the relation of 9 : 3 : 3 : 1.
-
-These seeds were sown again in the following year and gave:—
-
-From the round yellow seeds:—
-
-          _AB_    38 round and yellow seeds
-          _ABb_   65 round yellow and green seeds
-          _AaB_   60 round yellow and angular yellow seeds
-          _AaBb_ 138 round yellow and green, angular yellow and green
-             seeds
-
-From the angular yellow seeds:—
-
-          _aB_  28 angular yellow seeds
-          _aBb_ 68 angular yellow and green seeds
-
-From the round green seeds:—
-
-          _Ab_  35 round green seeds
-          _Aab_ 67 round angular seeds
-
-From the angular green seeds:—
-
-          _ab_ 30 angular green seeds
-
-Thus there were 9 different kinds of seeds produced. There had been
-separated out at this time 38 individuals like the parent seed plant,
-_AB_, and 30 like the parent pollen plant, _ab_. Since these had come
-from similar seeds of the preceding generation they may be looked upon
-as pure at this time. The forms _Ab_ and _aB_ are also constant forms
-which do not subsequently vary. The remainder are still mixed or hybrid
-in character. By successive self-fertilizations it is possible gradually
-to separate out from these the pure types of which they are compounded.
-
-Without going into further detail it may be stated that the offspring of
-the parent hybrids, having two pairs of differentiating characters, are
-represented by the series:—
-
-        _AB_ _Ab_ _aB_ _ab_ 2_ABb_ 2_aBb_ 2_Aab_ 2_ABa_ 2_AaBb_
-
-This series is really a combination of the two series:—
-
-          _A_ + 2_Aa_ + _a_
-          _B_ + 2_Bb_ + _b_
-
-Mendel even went farther, and used two parent varieties having three
-differentiating characters, as follows:—
-
-                _ABC seed parent_    _abc pollen plant_
-
-               { A form round       { a form angular
-
-               { B albumen yellow   { b albumen green
-
-               { C seed-coat grey   { c seed-coat white
-               brown
-
-The results, as may be imagined, were quite complex, but can be
-expressed by combining these series:—
-
-          _A_ + 2_Aa_ + _a_
-          _B_ + 2_Bb_ + _b_
-          _C_ + 2_Cc_ + _c_
-
-In regard to the two latter experiments, in which two and three
-characters respectively were used, it is interesting to point out that
-the form of the hybrid more nearly approaches “to that one of the
-parental plants which possesses the greatest number of dominant
-characters.” If, for instance, the seed plant has short stem, terminal
-white flowers, and simply inflated pods; the pollen plant, on the other
-hand, a long stem, violet-red flowers distributed along the stem, and
-constricted pods,—then the hybrid resembles the seed parent only in the
-form of the pod; in its other characters it agrees with the pollen
-plant. From this we may conclude that, if two varieties differing in a
-large number of characters are crossed, the hybrid might get some of its
-dominant characters from one parent, and other dominant characters from
-the other parent, so that, unless the individual characters themselves
-were studied, it might appear that the hybrids are intermediate between
-the two parents, while in reality they are only combinations of the
-dominant characters of the two forms. But even this is not the whole
-question.
-
-Mendel points out that, from knowing the characters of the two parent
-forms (or varieties), one could not prophesy what the hybrid would be
-like without making the actual trial. Which of the characters of the two
-parent forms will be the dominant ones, and which recessive, can only be
-determined by experiment. Moreover, the hybrid characters are something
-peculiar to the hybrid itself, and to itself alone, and not simply the
-combination of the characters of the two forms. Thus in one case a
-hybrid from a tall and a short variety of pea was even taller than the
-taller parent variety. Bateson lays much emphasis on this point,
-believing it to be an important consideration in all questions relating
-to hybridization and inheritance.
-
-The theoretical interpretation that Mendel has put upon his results is
-so extremely simple that there can be little doubt that he has hit on
-the real explanation. The results can be accounted for if we suppose
-that the hybrid produces egg-cells and pollen-cells, each of which is
-the bearer of only one of the alternative characters, dominant or
-recessive as the case may be. If this is the case, and if on an average
-there are the same number of egg-cells and pollen-cells, having one or
-the other of these kinds of characters, then on a random assortment
-meeting of egg-cells and pollen-cells, Mendel’s law would follow. For,
-25 per cent of dominant pollen grains would meet with 25 per cent
-dominant egg-cells; 25 per cent recessive pollen grains would meet with
-25 per cent recessive egg-cells; while the remaining 50 per cent of each
-kind would meet each other. Or, as Mendel showed by the following
-scheme:—
-
-      A      A   a      a
-      |        /       |
-      |        ×        |
-      |       /        |
-      A      A   a      a
-
-Or more simply by this scheme:—
-
-    A   a
-    | /|
-    | × |
-    |/
-    A   a
-
-Mendel’s results have received confirmation by a number of more recent
-workers, and while in some cases the results appear to be complicated by
-other factors, yet there can remain little doubt that Mendel has
-discovered one of the fundamental laws of heredity.
-
-It has been found that there are some cases in which the sort of
-inheritance postulated by Mendel’s law does not seem to hold, and, in
-fact, Mendel himself spoke of such cases. He found that some kinds of
-hybrids do not break up in later generations into the parent forms. He
-also points out that in cases of discontinuity the variations in each
-character must be separately regarded. In most experiments in crossing,
-forms are chosen which differ from each other in a multitude of
-characters, some of which are continuous and others discontinuous, some
-capable of blending with their contraries while others are not. The
-observer in attempting to discover any regularity is confused by the
-complications thus introduced. Mendel’s law could only appear in such
-cases by the use of an overwhelming number of examples which are beyond
-the possibilities of experiment.[25]
-
-Footnote 25:
-
-  This statement is largely taken from Bateson’s book.
-
-Let us now examine the bearing of these discoveries on the questions of
-variation which were raised in the preceding pages. It should be pointed
-out, however, that it would be premature to do more than indicate, in
-the most general way, the application of these conclusions. The chief
-value of Mendel’s results lies in their relation to the theory of
-inheritance rather than to that of evolution.
-
-In the first place, Mendel’s results indicate that we cannot make any
-such sharp distinction as Darwin does between the results of inheritance
-of discontinuous and of continuous variations. As Mendel’s results show,
-it is the separate characters that must be considered in each case, and
-not simply the sum total of characters.
-
-The more general objection that Darwin has made may appear to hold,
-nevertheless. He thinks that the evolution of animals and plants cannot
-rest primarily on the appearance of discontinuous variations, because
-they occur rarely and would be swamped by intercrossing. If Mendel’s law
-applies to such cases, that is, if a cross were made between such a
-sport and the original form, the hybrid in this case, if
-self-fertilized, would begin to split up into the two original forms.
-But, on the other hand, it could very rarely happen that the hybrid did
-fertilize its own eggs, and, unless this occurred, the hybrid, by
-crossing with the parent forms in each generation, would soon lose all
-its characters inherited from its “sport” ancestor. Unless, therefore,
-other individuals gave rise to sports at the same time, there would be
-little chance of producing new species in this way. We see then that
-discontinuity in itself, unless it involved infertility with the parent
-species, of which there is no evidence, cannot be made the basis for a
-theory of evolution, any more than can individual differences, for the
-swamping effect of intercrossing would in both cases soon obliterate the
-new form. If, however, a species begins to give rise to a large number
-of individuals of the same kind through a process of discontinuous
-variation, then it may happen that a new form may establish itself,
-either because it is adapted to live under conditions somewhat different
-from the parent form, so that the dangers of intercrossing are lessened,
-or because the new form may absorb the old one. It is also clear, from
-what has gone before, that the new form can only cease to be fertile
-with the parent form, or with its sister forms, after it has undergone
-such a number of changes that it is no longer able to combine the
-differences in a new individual. This result will depend both on the
-kinds of the new characters, as well as the amounts of their difference.
-This brings us to a consideration of the results of De Vries, who has
-studied the first steps in the formation of new species in the
-“mutations” of the evening primrose.
-
-
-                    The Mutation Theory of De Vries
-
-De Vries defines the mutation theory as the conception that “the
-characters of the organism are made up of elements (‘Einheiten’) that
-are sharply separated from each other. These elements can be combined in
-groups, and in related species the same combinations of elements recur.
-Transitional forms like those that are so common in the external
-features of animals and plants do not exist between the elements
-themselves, any more than they do between the elements of the chemist.”
-
-This principle leads, De Vries says, in the domain of the descent theory
-to the conception that species have arisen from each other, not
-continuously, but by steps. Each new step results from a new combination
-as compared with the old one, and the new forms are thereby completely
-and sharply separated from the species from which they have come. The
-new species is all at once there; it has arisen from the parent form
-without visible preparation and without transitional steps.
-
-The mutation theory stands in sharp contrast to the selection theory.
-The latter uses as its starting-point the common form of variability
-known as individual or fluctuating variation; but according to the
-mutation theory there are two kinds of variation that are entirely
-different from each other. “The fluctuating variation can, as I hope to
-show, not overstep the bounds of the species, even after the most
-prolonged selection,—much less can this kind of variation lead to the
-production of new, constant characters.” Each peculiarity of the
-organism has arisen from a preceding one, not through the common form of
-variation, but through a sudden change that may be quite small but is
-perfectly definite. This kind of variability that produces new species,
-De Vries calls mutability; the change itself he calls a mutation. The
-best-known examples of mutations are those which Darwin called “single
-variations” or “sports.”
-
-De Vries recognizes the following kinds of variation:—
-
-First, the polymorphic forms of the systematists. The ordinary groups
-which, following Linnæus, we call species, are according to De Vries
-collective groups, which are the outcome of mutations. Many such Linnæan
-species include small series of related forms, and sometimes even large
-numbers of such forms. These are as distinctly and completely separated
-from each other as are the best species. Generally these small groups
-are called varieties, or subspecies,—varieties when they are separated
-by a single striking character, subspecies when they differ in the
-totality of their characters, in the so-called habitus.
-
-These groups have already been recognized by some investigators as
-elementary species, and have been given corresponding binary names. Thus
-there are recognized two hundred elementary species of the form formerly
-called _Draba verna_.
-
-When brought under cultivation these elementary species are constant in
-character and transmit their peculiarities truly. They are not local
-races in the sense that they are the outcome in each generation of
-special external conditions. Many other Linnæan species are in this
-respect like _Draba verna_, and most varieties, De Vries thinks, are
-really elementary species.
-
-Second, the polymorphism due to intercrossing is the outcome of
-different combinations of hereditary qualities. There are here, De Vries
-says, two important classes of facts to be kept strictly
-apart,—scientific experiment, and the results of the gardener and of the
-cultivator. The experimenter chooses for crossing, species as little
-variable as possible; the gardener and cultivator on the other hand
-prefer to cross forms of which one at least is variable, because the
-variations may be transmitted to the hybrid, and in this way a new form
-be produced.
-
-New elementary characters arise in experiments in crossing only through
-variability, not through crossing itself.
-
-Third, variability in the ordinary sense, that is, individual
-variability, includes those differences between the individual organs
-that follow Quetelet’s theory of chance. This kind of variability is
-characterized by its presence at all times, in all groups of
-individuals.
-
-De Vries recalls Galton’s apt comparison between variability and a
-polyhedron which can roll from one face to another. When it comes to
-rest on any particular face, it is in stable equilibrium. Small
-vibrations or disturbances may make it oscillate, but it returns always
-to the same face. These oscillations are like the fluctuating
-variations. A greater disturbance may cause the polyhedron to roll over
-on to a new face, where it comes to rest again, only showing the ever
-present fluctuations around its new centre. The new position corresponds
-to a mutation. It may appear from our familiarity with the great changes
-that we associate with the idea of discontinuous variability, that a
-mutation must also involve a considerable change. Such, however, De
-Vries says, is not the case. In fact, numerous mutations are smaller
-than the extremes of fluctuating variation. For example, the different
-elementary species of _Draba verna_ are less different from each other
-than the forms of leaves on a tree. The essential differences between
-the two kinds of variation is that the mutation is constant, while the
-continuous variation fluctuates back and forth.
-
-The following example is given by De Vries to illustrate the general
-point of view in regard to varieties and species. The species _Oxalis
-corniculata_ is a “collective” species that lives in New Zealand. It has
-been described as having seven well-characterized varieties which do not
-live together or have intermediate forms. If we knew only this group,
-there would be no question that there are seven good species. But in
-other countries intermediate forms exist, which exactly bridge over the
-differences between the seven New Zealand forms. For this reason all the
-forms have been united in a single species.
-
-Another example is that of the fern, _Lomaria procera_, from New
-Zealand, Australia, South Africa, and South America. If the forms from
-only one country be considered, they appear to be different species; but
-if all the forms from the different parts of the world be taken into
-account, they constitute a connected group, and are united into one
-large species.
-
-It will be seen, therefore, that the limits of a collective species are
-determined solely by the deficiencies in the genealogical tree of the
-elementary species. If all the elementary species in one country were
-destroyed, then the forms living in other countries that had been
-previously held together because of those which have now been destroyed,
-would, after the destruction, become true species. In other words: “The
-Linnæan species are formed by the disappearance of other elementary
-species, which at first connected all forms. This mode of origin is a
-purely historical process, and can never become the subject of
-experimental investigation.” Spencer’s famous expression, the “survival
-of the fittest,” is incomplete, and should read the “survival of the
-fittest species.” It is, therefore, not the study of Linnæan species
-that has a physiological interest, but it is the study of the elementary
-species of which the Linnæan species are made up, that furnishes the
-all-important problem for experimental study.
-
-De Vries gives a critical analysis of a number of cases in which new
-races have been formed under domestication. He shows very convincingly
-that, whenever the result has been the outcome of the selection of
-fluctuating variations, the product that is formed can only be kept to
-its highest point of development by the most rigid and ever watchful
-care. If selection ceases for only a few generations, the new form sinks
-back at once to its original level. Many of our cultivated plants have
-really arisen, not by selection of this sort, but by mutations; and
-there are a number of recorded cases where the first and sudden
-appearance of a new form has been observed. In such cases as these there
-is no need for selection, for if left to themselves there is no return
-to the original form. If, however, after a new mutation has appeared in
-this way, we subject its fluctuating variations to selection, we can
-keep the new form up to its most extreme limit, but can do nothing more.
-
-Another means, frequently employed, by which new varieties have been
-formed is by bringing together different elementary species under
-cultivation. For instance, there are a large number of wild elementary
-species of apples, and De Vries believes that our different races of
-apples owe their origin in part to these different wild forms. Crossing,
-cultivation, and selection have done the rest.
-
-De Vries points out some of the inconsistencies of those who have
-attempted to discriminate between varieties and species. The only rule
-that can be adhered to is that a variety differs from a species to which
-it belongs in only one or in a few characters. Most so-called varieties
-in nature are really elementary species, which differ from their nearest
-relatives, not in one character only, but in nearly all their
-characters. There is no ground, De Vries states, for believing them to
-be varieties. If it is found inconvenient to rank them under the names
-of the old Linnæan species, it will be better, perhaps, to treat them as
-subspecies, but De Vries prefers to call them elementary species.
-
-In regard to the distribution of species in nature, it may be generally
-stated that the larger the geographical domain so much the larger is the
-number of elementary species. They are found to be heaped up in the
-centre of their area of distribution, but are more scattered at the
-periphery.
-
-In any one locality each Linnæan species has as a rule only one or a few
-elementary species. The larger the area the more numerous the forms.
-From France alone Jordan had brought together in his garden 50
-elementary species of _Draba verna_. From England, Italy, and Austria
-there could be added 150 more. This polymorphism is, De Vries thinks, a
-general phenomenon, although the number of forms is seldom so great as
-in this case.
-
-Amongst animals this great variety of forms is not often met with, yet
-amongst the mammalia and birds of North America there are many cases of
-local forms or races, some of which at least are probably mutations.
-This can only be proven, however, by actually transferring the forms to
-new localities in order to find out if they retain their original
-characters, or become changed into another form. It seems not improbable
-that many of the forms are not the outcome of the external conditions
-under which the animal now lives, but would perpetuate themselves in a
-new environment.
-
-From the evidence that his results have given, De Vries believes it is
-probable that mutation has occurred in all directions. In the same way
-that Darwin supposed that individual or fluctuating variations are
-scattering, so also De Vries believes that the new forms that arise
-through mutation are scattering. On this point it seems to me that De
-Vries may be too much prejudiced by his results with the evening
-primrose. If, as he supposes, many forms, generally ranked as varieties,
-are really elementary species, it seems more probable that the mutation
-of a form may often be limited to the production of one or of only a
-very few new forms. The single variations, or sports, point even more
-strongly in favor of this interpretation. Moreover, the general problem
-of evolution from a purely theoretical point of view is very much
-simplified, if we assume that the kinds of mutating forms may often be
-very limited, and that mutations may often continue to occur in a direct
-line. On this last point, De Vries argues that the evidence from
-paleontology cannot be trusted, for all that we can conclude from fossil
-remains is that certain mutations have dominated, and have been
-sufficiently abundant to leave a record. In other words, the conditions
-may have been such that only certain forms could find a foothold.
-
-De Vries asks whether there are for each species periods of mutation
-when many and great changes take place, and periods when relatively
-little change occurs. The evidence upon which to form an opinion is
-scanty, but De Vries is inclined to think that such periods do occur. It
-is at least certain from our experience that there are long periods when
-we do not see new forms arising, while at other times, although we know
-very few of them, epidemics of change may take place. The mutative
-period which De Vries found in the evening primrose is the best-known
-example of such a period of active mutation. Equally important for the
-descent theory is the idea that the same mutation may appear time after
-time. There is good evidence to show that this really occurs, and in
-consequence the chances for the perpetuation of such a form are greatly
-increased. Delbœuf, who advocated this idea of the repeated reappearance
-of a new form, has also attempted to show that if this occurs the new
-form may become established without selection of any kind taking
-place,—the time required depending upon the frequency with which the new
-form appears. This law of Delbœuf, De Vries believes, is correct from
-the point of view of the mutation theory. It explains, in a very simple
-way, the existence of numerous species-characters that are entirely
-useless, such, for instance, as exist between the different elementary
-species of _Draba verna_. “According to the selection theory only useful
-characters can survive; according to the mutation theory, useless
-characters also may survive, and even those that may be hurtful to a
-small degree.”
-
-We may now proceed to examine the evidence from which De Vries has been
-led to the general conclusions given in the preceding pages. De Vries
-found at Hilversam, near Amsterdam, a locality where a number of plants
-of the evening primrose, _Œnothera lamarckiana_, grow in large numbers.
-This plant is an American form that has been imported into Europe. It
-often escapes from cultivation, as is the case at Hilversam, where for
-ten years it had been growing wild. Its rapid increase in numbers in the
-course of a few years may be one of the causes that has led to the
-appearance of a mutation period. The escaped plants showed fluctuating
-variations in nearly all of their organs. They also had produced a
-number of abnormal forms. Some of the plants came to maturity in one
-year, others in two, or in rare cases in three, years.
-
-A year after the first finding of these plants De Vries observed two
-well-characterized forms, which he at once recognized as new elementary
-species. One of these was _O. brevistylis_, which occurred only as
-female plants. The other new species was a smooth-leafed form with a
-more beautiful foliage than _O. lamarckiana_. This is _O. lævifola_. It
-was found that both of these new forms bred true from self-fertilized
-seeds. At first only a few specimens were found, each form in a
-particular part of the field, which looks as though each might have come
-from the seeds of a single plant.
-
-
-                          ŒNOTHERA LAMARCKIANA
-
-                           Elementary Species
-
- ===============+======+======+======+======+========+========+====+========
-   GENERATION   |GIGAS |ALBIDA|OBLON-|RUBRI-|LAMARCK-|NANNELLA|LATA|SCINTIL-
-                |      |      |GATA  |NERVIS| IANA   |        |    | LANS
- ===============+======+======+======+======+========+========+====+========
-      |8 Gener. |
- VIII | 1899    |          5      1       0   1700        21     1
-      |annual   |      ‘———————————v—————————’
-      |         |
-      |7 Gener. |
- VII  | 1898    |                 9       0   3000        11
-      |annual   |                ‘———————v——————’
-      |         |
-      |6 Gener. |
- VI   | 1897    |         11     29       3   1800         9     5      1
-      |annual   |        ‘———————————v—————————————’
-      |         |
-      |5 Gener. |
- V    | 1896    |         25    135      20   8000        49   142      6
-      |annual   |        ‘———————————v—————————————’
-      |         |
-      |4 Gener. |
- IV   | 1895    |     1   15    176       8  14000        60    73      1
-      |annual   |    ‘—————————————v—————————————’
-      |         |
-      |3 Gener. |
- III  | 1890-91 |                         1  10000         3      3
-      |biennial |                        ‘———v——————————’
-      |         |
-      |2 Gener. |
- II   | 1888-89 |                            15000         5      5
-      |biennial |                           ‘—v——————————’
-      |         |
-      |1 Gener. |
- I    | 1886-87 |                                 9
-      |biennial |
- =====+=========+===========================================================
-
-
-These two new forms, as well as the common _O. lamarckiana_, were
-collected, and from these plants there have arisen the three groups or
-families of elementary species that De Vries has studied. In his garden
-other new forms also arose from those that had been brought under
-cultivation. The largest group and the most important one is that from
-the original _O. lamarckiana_ form. The accompanying table shows the
-mutations that arose between 1887 and 1899 from these plants. The seeds
-were selected in each case from self-fertilized plants of the
-_lamarckiana_ form, so that the new plants appearing in each horizontal
-line are the descendants in each generation of _lamarckiana_ parents. It
-will be observed that the species, _O. oblongata_, appeared again and
-again in considerable numbers, and the same is true for several of the
-other forms also. Only the two species, _O. gigas_ and _O. scintillans_,
-appeared very rarely.
-
-Thus De Vries had, in his seven generations, about fifty thousand
-plants, and about eight hundred of these were mutations. When the
-flowers of the new forms were artificially fertilized with pollen from
-the flowers on the same plant, or of the same kind of plant, they gave
-rise to forms like themselves, thus showing that they are true
-elementary species.[26] It is also a point of some interest to observe
-that all these forms differed from each other in a large number of
-particulars.
-
-Footnote 26:
-
-  _O. lata_ is always female, and cannot, therefore, be self-fertilized.
-  When crossed with _O. lamarckiana_ there is produced fifteen to twenty
-  per cent of pure _lata_ individuals.
-
-Only one form, _O. scintillans_, that appeared eight times, is not
-constant as are the other species. When self-fertilized its seeds
-produce always three other forms, _O. scintillans_, _O. oblongata_, and
-_O. lamarckiana_. It differs in this respect from all the other
-elementary species, which mutate not more than once in ten thousand
-individuals.
-
-From the seeds of one of the new forms, _O. lævifolia_, collected in the
-field, plants were reared, some of which were _O. lamarckiana_ and
-others _O. lævifolia_. They were allowed to grow together, and their
-descendants gave rise to the same forms found in the _lamarckiana_
-family, described above, namely, _O. lata_, _elliptica_, _nannella_,
-_rubrinervis_, and also two new species, _O. spatulata_ and
-_leptocarpa_.
-
-In the _lata_ family, only female flowers are produced, and, therefore,
-in order to obtain seeds they were fertilized with pollen from other
-species. Here also appeared some of the new species, already mentioned,
-namely, _albida_, _nannella_, _lata_, _oblongata_, _rubrinervis_, and
-also two new species, _elliptica_ and _subovata_.
-
-De Vries also watched the field from which the original forms were
-obtained, and found there many of the new species that appeared under
-cultivation. These were found, however, only as weak young plants that
-rarely flowered. Five of the new forms were seen either in the Hilversam
-field, or else raised from seeds that had been collected there. These
-facts show that the new species are not due to cultivation, and that
-they arise year after year from the seeds of the parent form, _O.
-lamarckiana_.
-
-
-                              Conclusions
-
-From the evidence given in the preceding pages it appears that the line
-between fluctuating variations and mutations may be sharply drawn. If we
-assume that mutations have furnished the material for the process of
-evolution, the whole problem appears in a different light from that in
-which it was placed by Darwin when he assumed that the fluctuating
-variations are the kind which give the material for evolution.
-
-From the point of view of the mutation theory, species are no longer
-looked upon as having been slowly built up through the selection of
-individual variations, but the elementary species, at least, appear at a
-single advance, and fully formed. This need not necessarily mean that
-great changes have suddenly taken place, and in this respect the
-mutation theory is in accord with Darwin’s view that _extreme_ forms
-that rarely appear, “sports,” have not furnished the material for the
-process of evolution.
-
-As De Vries has pointed out, each mutation may be different from the
-parent form in only a slight degree for each point, although all the
-points may be different. The most unique feature of these mutations is
-the constancy with which the new form is inherited. It is this fact, not
-previously fully appreciated, that De Vries’s work has brought
-prominently into the foreground. There is another point of great
-interest in this connection. Many of the groups that Darwin recognized
-as varieties correspond to the elementary species of De Vries. These
-varieties, Darwin thought, are the first stages in the formations of
-species, and, in fact, cannot be separated from species in most cases.
-The main difference between the selection theory and the mutation theory
-is that the one supposes these varieties to arise through selection of
-individual variations, the other supposes that they have arisen
-spontaneously and at once from the original form. The development of
-these varieties into new species is again supposed, on the Darwinian
-theory, to be the result of further selection, on the mutation theory,
-the result of the appearance of new mutations.
-
-In consequence of this difference in the two theories, it will not be
-difficult to show that the mutation theory escapes some of the gravest
-difficulties that the Darwinian theory has encountered. Some of the
-advantages of the mutation theory may be briefly mentioned here.
-
-1. Since the mutations appear fully formed from the beginning, there is
-no difficulty in accounting for the incipient stages in the development
-of an organ, and since the organ may persist, even when it has no value
-to the race, it may become further developed by later mutations and may
-come to have finally an important relation to the life of the
-individual.
-
-2. The new mutations may appear in large numbers, and of the different
-kinds those will persist that can get a foothold. On account of the
-large number of times that the same mutations appear, the danger of
-becoming swamped through crossing with the original form will be
-lessened in proportion to the number of new individuals that arise.
-
-3. If the time of reaching maturity in the new form is different from
-that in the parent forms, then the new species will be kept from
-crossing with the parent form, and since this new character will be
-present from the beginning, the new form will have much better chances
-of surviving than if a difference in time of reaching maturity had to be
-gradually acquired.
-
-4. The new species that appear may be in some cases already adapted to
-live, in a different environment from that occupied by the parent form;
-and if so, it will be isolated from the beginning, which will be an
-advantage in avoiding the bad effects of intercrossing.
-
-5. It is well known that the differences between related species
-consists largely in differences of unimportant organs, and this is in
-harmony with the mutation theory, but one of the real difficulties of
-the selection theory.
-
-6. Useless or even slightly injurious characters may appear as
-mutations, and if they do not seriously affect the perpetuation of the
-race, they may persist.
-
-In Chapters X and XI, an attempt will be made to point out in detail the
-advantages which the mutation theory has over the Darwinian theory.
-
-
-------------------------------------------------------------------------
-
-
-
-
-                               CHAPTER IX
-
-        EVOLUTION AS THE RESULT OF EXTERNAL AND INTERNAL FACTORS
-
-
-We come now to a consideration of other theories that have been advanced
-to account for the evolution of new forms; and in so far as these new
-forms are adapted to their environment, the theories will bear directly
-on the question of the origin of adaptive variations. One school of
-transformationists has made the external world and the changes taking
-place in it the source of new variations. Another school believes that
-the changes arise within the organism itself. We may examine these two
-points of view in turn.
-
-
-                   The Effect of External Influences
-
-We have already seen that Lamarck held as a part of his doctrine of
-transformation that the changes in the external world, the environment,
-bring about, directly, changes in the organism, and he believed that all
-plants and many of the lower animals have evolved as the result of a
-reaction of this sort. This idea did not originate with Lamarck,
-however, since before him Buffon had advanced the same hypothesis, and
-there cannot be much doubt that Lamarck borrowed from his patron,
-Buffon, this part of his theory of evolution.
-
-This idea of the influence of the external world as a factor inducing
-changes in the organism has come, however, to be associated especially
-with the name of Geoffroy Saint-Hilaire, whose period of activity,
-although overlapping, came after that of Lamarck. The central idea of
-Geoffroy’s view was that species of animals and plants undergo change as
-the environment changes; and it is important to note, in passing, that
-he did not suppose that these changes were always for the benefit of the
-individual, _i.e._ they were not always adaptive. If they were not, the
-forms became extinct. So long as the conditions remain constant, the
-species remains constant; and he found an answer in this to Cuvier’s
-argument, in respect to the similarity between the animals living at
-present in Egypt and those discovered embalmed along with mummies at
-least two thousand years old. Geoffroy Saint-Hilaire said, that since
-the climatic conditions of Egypt had remained exactly the same during
-all these years, the animals of Egypt would also have remained
-unchanged.
-
-Geoffroy’s views were largely influenced by his studies in systematic
-zoology and by his conception of a unity of plan running through the
-entire animal kingdom. His study of embryology and paleontology had led
-him to believe that present forms have descended from other organisms
-living in the past, and in this connection his discovery of teeth in the
-jaws of the embryo of the baleen whale and also his discovery of the
-embryonic dental ridges in the upper and in the lower jaws of birds,
-were used with effect in supporting the theory of change or evolution.
-Lastly, his remarkable work in the study of abnormal forms prepared the
-way for his conception of sudden and great changes, which he believed
-organisms capable of undergoing. He went so far in fact, in one
-instance, as to suppose that it was not impossible that a bird might
-have issued fully equipped from the egg of a crocodile. Such an extreme
-statement, which seems to us nowadays only laughable, need not prejudice
-us against the more moderate parts of his speculation.
-
-His study of the fossil gavials found near Caen led him to believe that
-they are quite distinct from living crocodiles. He asked whether these
-old forms may not represent a link in the chain that connects, without
-interruption, the older inhabitants of the earth with animals living at
-the present time. Without positively affirming that this is the case, he
-did not hesitate to state that a transformation of this sort seemed
-possible to him. He said: “I think that the process of respiration
-constitutes an acquirement so important in the ‘disposition’ of the
-forms of animals, that it is not at all necessary to suppose that the
-surrounding respiratory gases become modified quickly and in large
-amount in order that the animal may become slowly modified. The
-prolonged action of time would ordinarily suffice, but if combined with
-a cataclysm, the result would be so much the better.”
-
-He supposed that in the course of time respiration becomes difficult and
-finally impossible as far as certain systems of organs are concerned.
-The necessity then arises and creates another arrangement, perfecting or
-altering the existing structures. Modifications, fortunate or fatal, are
-created which through propagation are continued, and which, if
-fortunate, influence all the rest of the organization. But if the
-modifications are injurious to the animals in which they have appeared,
-the animals cease to exist, and are replaced by others having a
-different form, and one suited to the new circumstances.
-
-The comparison between the stages of development of the individual and
-the evolution of the species was strongly impressed on the mind of
-Geoffroy. He says: “We see, each year, the spectacle of the
-transformation in organization from one class into another. A batrachian
-is at first a fish under the name of a tadpole, then a reptile
-(amphibian) under that of a frog.” “The development, or the result of
-the transformation, is brought about by the combined action of light and
-of oxygen; and the change in the body of the animal takes place by the
-production of new blood-vessels, whose development follows the law of
-the balancing of organs, in the sense, that if the circulating fluids
-precipitate themselves into new channels there remains less in the old
-vessels.” By preventing tadpoles from leaving the water, Geoffroy claims
-that it has been shown that they can be prevented from changing into
-frogs. The main point that Geoffroy attempts to establish is no doubt
-fairly clear, but the way in which he supposes the change to be effected
-is not so clear, and his ideas as to the way in which new change may be
-perpetuated in the next generation are, from our more modern point of
-view, extremely hazy. It is perhaps not altogether fair to judge his
-view from the standpoint of the origin of adaptive structures, but
-rather as an attempt to explain the causes that have brought about the
-evolution of the organic world.
-
-During the remainder of the nineteenth century there accumulated a large
-number of facts in relation to the action of the external conditions in
-bringing about changes in animals and plants. Much of this evidence is
-of importance in dealing with the question of the origin of organic
-adaptation.
-
-The first class of facts in this connection is that of geographical
-variation in animals and plants. It will be impossible here to do more
-than select some of the most important cases. De Varigny, in his book on
-“Experimental Evolution,” has brought together a large number of facts
-of this kind, and from his account the following illustrations have been
-selected. He says: “When the small brown honey-bee from High Burgundy is
-transported into Bresse—although not very distant—it soon becomes larger
-and assumes a yellow color; this happens even in the second generation.”
-It is also pointed out that the roots of the beet, carrot, and radish
-are colorless in their wild natural state, but when brought under
-cultivation they become red, yellow, etc. Vilmorin has noted that the
-red, yellow, and violet colors of carrots appear only some time after
-the wild forms have been brought under cultivation. Moquin-Tandon has
-seen “gentians which are blue in valleys become white on mountains.”
-Other cases also are on record in which the colors of a plant are
-dependent on external conditions.
-
-The sizes of plants and animals are also often directly traceable to
-certain external conditions; the change is generally connected with the
-amount of food obtainable. “Generally speaking,” De Varigny says,
-“insular animals are smaller than their continental congeners. In the
-Canary Islands the oxen of one of the smallest islands are smaller than
-those on the others, although all belong to the same breed, and the
-horses are also smaller, and the indigenous inhabitants are in the same
-case, although belonging to a tall race. It would seem that in Malta
-elephants were very small,—fossil elephants, of course,—and that during
-the Roman period the island was noted for a dwarf breed of dogs, which
-was named after its birthplace, according to Strabo. In Corsica, also,
-horses and oxen are very small, and _Cervus corsicanus_, the indigenous
-deer, is quite reduced in dimensions; ... and lastly, the small
-dimensions of the Falkland horses—imported from Spain in 1764—are
-familiar to all. The dwarf rabbits of Porto Santo described by Darwin
-may also be cited as a case in point.”
-
-These facts, interesting as they are, will, no doubt, have to be more
-carefully examined before the evidence can have great value, for it is
-not clear what factor or factors have produced the decrease in size of
-these animals.
-
-The following cases show more clearly the immediate effect of the
-environment: “Many animals, when transferred to warm climates, lose
-their wool, or their hairy covering is much reduced. In some parts of
-the warmer regions of the earth, sheep have no wool, but merely hairs
-like those of dogs. Similarly, as Roulin notices, poultry have, in
-Columbia, lost their feathers, and while the young are at first covered
-with a black and delicate down, they lose it in great part as they grow,
-and the adult fowls nearly realize Plato’s realistic description of
-man—a biped without feathers. Conversely, many animals when transferred
-from warm to cold climates acquire a thicker covering; dogs and horses,
-for instance, becoming covered with wool.”
-
-A number of kinds of snails that were supposed to belong to different
-species have been found, on further examination, to be only varieties
-due to the environment. “Locard has discovered through experiments that
-_L. turgida_ and _elophila_ are mere varieties—due to environment—of the
-common _Lymnæa stagnalis_.” He says, “These are not new species, but
-merely common aspects of a common type, which is capable of modification
-and of adaptation according to the nature of the media in which it has
-to live.” It has also been shown by Bateson that similar changes occur
-in _Cardium edule_, and other lamellibranchs are known to vary according
-to the nature of the water in which they live.
-
-In regard to plants, the influence of the environment has long been
-known to produce an effect on the form, color, etc., of the individuals.
-“The common dandelion (_Taraxacum densleonis_) has in dry soil leaves
-which are much more irregular and incised, while they are hardly dentate
-in marshy stations, where it is called _Taraxacum palustre_.
-
-“Individuals growing near the seashore differ markedly from those
-growing far inland. Similarly, species such as some Ranunculi, which can
-live under water as well as in air, exhibit marked differences when
-considered in their different stations, as is well known to all. These
-differences may be important enough to induce botanists to believe in
-the existence of two different species when there is only one.”
-
-An interesting case is that of _Daphnia rectirostris_, a small
-crustacean living sometimes in fresh water, at other times in water
-containing salt and also in salt lakes. There are two forms,
-corresponding to the conditions under which they live, and it is said
-that the differences are of a kind that suffice to separate species from
-each other. In another crustacean, _Branchipus ferox_, the form differs
-in a number of points, according to whether it lives in salt or in fresh
-water. Schmankewitsch says that, had he not found all transitional
-forms, and observed the transformation in cultures, he would have
-regarded the two forms as separate species. The oft-quoted case of
-Artemia furnishes a very striking example of the influence of the
-environment. _Artemia salina_ lives in water whose concentration varies
-between 5 and 12 degrees of saltness. When the amount of salt is
-increased to 12 degrees, the animal shows certain characteristics like
-those of _Artemia milhausenii_, which may live in water having 24 to 25
-degrees of saltness. The form _A. salina_ may be further completely
-changed into that of _A. milhausenii_ by increasing the amount of salt
-to the latter amount.
-
-Among domesticated animals and plants—a few instances of which have been
-already referred to—we find a large number of cases in which a change in
-the environment produces definite changes in the organism. Darwin has
-made a most valuable collection of facts of this kind in his “Animals
-and Plants under Domestication.” He believes that domesticated forms are
-much more variable than wild ones, and that this is due, in part, to
-their being protected from competition, and to their having been removed
-from their natural conditions and even from their native country. “In
-conformity with this, all our domesticated productions without exception
-vary far more than natural species. The hive-bee, which feeds itself,
-and follows in most respects its natural habits of life, is the least
-variable of all domesticated animals.... Hardly a single plant can be
-named, which has long been cultivated and propagated by seed, that is
-not highly variable.” “Bud-variation ... shows us that variability may
-be quite independent of seminal reproduction, and likewise of reversion
-to long-lost ancestral characters. No one will maintain that the sudden
-appearance of a moss-rose on a Provence rose is a return to a former
-state, ... nor can the appearance of nectarines on peach trees be
-accounted for on the principle of reversion.” It is said that
-bud-variations are also much more frequent on cultivated than on wild
-plants.
-
-Darwin adds: “These general considerations alone render it probable that
-variability of every kind is directly or indirectly caused by changed
-conditions of life. Or to put the case under another point of view, if
-it were possible to expose all the individuals of a species during many
-generations to absolutely uniform conditions of life, there would be no
-variability.”
-
-In some cases it has been observed that, in passing from one part of a
-continent to another, many or all of the forms of the same group and
-even of different groups change in the same way. Allen’s account of the
-variations in North American birds and mammals furnishes a number of
-striking examples of this kind of change. He finds that, as a rule, the
-birds and mammals of North America increase in size from the south
-northward. This is true, not only for the individuals of the same
-species, but generally the largest species of each genus are in the
-north. There are some exceptions, however, in which the increase in size
-is in the opposite direction. The explanation of this is that the
-largest individuals are almost invariably found in the region where the
-group to which the species belongs receives its greatest numerical
-development. This Allen interprets as the hypothetical “centre of
-distribution of the species,” which is in most cases doubtless also its
-original centre of dispersal. If the species has arisen in the north,
-then the northern forms are the largest; but if it arose in the south,
-the reverse is the case. Thus, most of the species of North America that
-live north of Mexico are supposed to have had a northern origin, as
-shown by the circumpolar distribution of some of them and by the
-relationship of others to Old World species; and in these the largest
-individuals of the species of a genus are northern. Conversely, in the
-exceptional cases of increase in size toward the south, it can be shown
-that the forms have probably had a southern origin.
-
-The Canidæ (wolves and foxes) have their largest representatives, the
-world over, in the north. “In North America the family is represented by
-six species, the smallest of which (speaking generally) are southern and
-the largest northern.” The three species that have the widest ranges
-(the gray wolf, the common fox, and the gray fox) show the most marked
-differences in size. The skull, for instance, of “the common wolf is
-fully one-fifth larger in the northern parts of British America and
-Alaska than it is in northern Mexico, where it finds the southern limit
-of its habitat. Between the largest northern skull and the largest
-southern skull there is a difference of about thirty-five per cent of
-the mean size. Specimens from the intermediate region show a gradual
-intergradation between the extremes, although many of the examples from
-the upper Missouri country are nearly as large as those from the extreme
-north.” The common fox is about one-tenth larger, on the average, in
-Alaska than it is in New England. The gray fox, whose habitat extends
-from Pennsylvania southward to Yucatan, has an average length of skull
-of about five inches in the north, and less than four in Central
-America—about ten per cent difference.
-
-The Felidæ, or cats, “reach their greatest development as respects both
-the number and the size of the species in the intertropical regions.
-This family has sent a single typical representative, the panther
-(_Felis concolor_), north of Mexico, and this ranges only to about the
-northern boundary of the United States. The other North American
-representatives of the family are the lynxes, which in some of their
-varieties range from Alaska to Mexico.” Although they vary greatly in
-different localities in color and in length and texture of pelage, they
-do not vary as to the size of their skulls. On the other hand the
-panther (and the ocelots) greatly increases in size southward, “or
-toward the metropolis of the family.”
-
-Other carnivora that increase in size northward are the badger, the
-marten, the fisher, the wolverine, and the ermine, which are all
-northern types.
-
-Deer are also larger in the north; in the Virginia deer the annually
-deciduous antlers of immense size reach their greatest development in
-the north. The northern race of flying squirrels is one-half larger than
-the southern, “yet the two extremes are found to pass so gradually one
-into the other, that it is hardly possible to define even a southern and
-a northern geographical race.” The species ranges from the arctic
-regions to Central America.
-
-In birds also similar relations exist, but there is less often an
-increase in size northward. In species whose breeding station covers a
-wide range of latitude, the northern birds are not only smaller, but
-have quite different colors, as is markedly the case in the common
-quail, the meadow-lark, the purple grackle, the red-winged blackbird,
-the flicker, the towhee bunting, the Carolina dove, and in numerous
-other species. The same difference is also quite apparent in the blue
-jay, the crow, in most of the woodpeckers, in the titmice, numerous
-sparrows, and several warblers and thrushes. The variation often amounts
-to from ten to fifteen per cent of the average size of the species.
-
-Allen also states that certain parts of the animal may vary
-proportionately more than the general size, there being an apparent
-tendency for peripheral parts to enlarge toward the warmer regions,
-_i.e._ toward the south. “In mammals which have the external ears
-largely developed—as in the wolves, foxes, some of the deer, and
-especially the hares—the larger size of this organ in southern as
-compared with northern individuals of the same species, is often
-strikingly apparent.” It is even more apparent in species inhabiting
-open plains. The ears of the gray rabbit of the plains of western
-Arizona are twice the size of those of the Eastern states.
-
-In birds the bill especially, but also the claws and tail, is larger in
-the south. In passing from New England southward to Florida the bill in
-slender-billed forms becomes larger, longer, more attenuated, and more
-decurved; while in short-billed forms the southern individuals have
-thicker and larger bills, although the birds themselves are smaller.
-
-The remarkable changes and gradations of color in birds in different
-parts of North America are very instructive, and the important results
-obtained by American ornithologists form an interesting chapter in
-zoology. The evidence would convince the most sceptical of the
-difficulty of distinguishing between Linnæan species. It is not
-surprising to find in this connection a leading ornithologist
-exclaiming, “if there really are such things as species.” The
-differences here noted are mainly from east to west. We may briefly
-review here a few striking cases selected from Coues’s “Key to North
-American Birds.”
-
-The flicker, or golden-winged woodpecker (_Colaptes auratus_), has a
-wide distribution in eastern North America. It is replaced in western
-North America (from the Rocky Mountains to the Pacific) by _C.
-mexicanus_. In the intermediate regions, Missouri and the Rocky Mountain
-region, the characters of the two are blended in every conceivable
-degree in different specimens. “Perhaps it is a hybrid, and perhaps it
-is a transitional form, and doubtless there are no such things as
-species in Nature.... In the west you will find specimens _auratus_ on
-one side of the body, _mexicanus_ on the other.” There is a third form,
-_C. chrysoides_, with the wings and tail as in _auratus_, and the head
-as in _mexicanus_, that lives in the valley of the Colorado River, Lower
-California, and southward.
-
-In regard to the song-sparrow (_Melospiza_), Coues writes: “The type of
-the genus is the familiar and beloved song-sparrow, a bird of constant
-characters in the east, but in the west is split into numerous
-geographical races, some of them looking so different from typical
-_fasciata_ that they have been considered as distinct species, and even
-placed in other genera. This differentiation affects not only their
-color, but the size, relative proportions of parts, and particularly the
-shape of the bill; and it is sometimes so great, as in the case of _M.
-cinerea_, that less dissimilar looking birds are commonly assigned to
-different genera. Nevertheless the gradation is complete, and affected
-by imperceptible degrees.... The several degrees of likeness and
-unlikeness may be thrown into true relief better by some such
-expressions as the following, than by formal antithetical phrases: (1)
-The common eastern bird commonly modified in the interior into the
-duller colored (2) _fallax_. This in the Pacific watershed, more
-decidedly modified by deeper coloration,—broader black streaks in (3)
-_hermanni_, with its diminutive local race (4) _samuelis_, and more
-ruddy shades in (5) _guttata_ northward, increasing in intensity with
-increased size in (6) _rafina_. Then the remarkable (7) _cinerea_,
-insulated much further apart than any of the others. A former American
-school would probably have made four ‘good species,’ (1) _fasciata_, (2)
-_samuelis_, (3) _rafina_, (4) _cinerea_.”
-
-Somewhat similar relations are found in three other genera of finches.
-Thus Passerella is “imperfectly differentiated”; Junco is represented by
-one eastern species, but in the west the stock splits up into numerous
-forms, “all of which intergrade with each other and with the eastern
-bird. Almost all late writers have taken a hand at Junco, shuffling them
-about in the vain attempt to decide which are ‘species’ and which
-‘varieties.’ All are either or both, as we may elect to consider them.”
-In the distribution of the genus Pipilo similar relations are found.
-There is an eastern form much more distinct from the western forms than
-these are from each other.
-
-Finally may be mentioned the curious variations in screech-owls of the
-genus Scops. This owl has two strikingly different plumages—a mottled
-gray and a reddish brown, which, although very distinct when fully
-developed, yet “are entirely independent of age, season, or sex.” There
-is an eastern form, _Scops asio_, that extends west to the Rocky
-Mountains. There is a northwestern form, _S. kennicotti_, which in its
-red phase is quite different from _S. asio_, but in its gray plumage is
-very similar. The California form, _S. benderii_, is not known to have a
-red phase, and the gray phase is quite different from that of _S. asio_,
-but like the last form. The Colorado form, _S. maxwellæ_, has no red
-phase, “but on the contrary the whole plumage is very pale, almost as if
-bleached, the difference evident in the nestlings even.” The Texas form,
-_S. maselli_, has both phases, and is very similar to _S. asio_. The
-Florida form is smaller and colored like _S. asio_. The red phase is the
-frequent, if not the usual, one. The flammulated form, _S. fiammula_, is
-“a very _small species_, with much the general aspect of an ungrown _S.
-asio_.” This is the southwestern form, easily distinguished on account
-of its small size and color from the other forms.
-
-These examples might be greatly increased, but they will suffice, I
-think, to convince one of the difficulty of giving a sharp definition to
-“species.” The facts speak strongly in favor of the transmutation
-theory, and show us how a species may become separated under different
-conditions into a number of new forms, which would be counted as new
-different species, if the intermediate forms were exterminated.
-
-In discussing the nature of the changes that bring about variability,
-Darwin remarks: “From a remote period to the present day, under climates
-and circumstances as different as it is possible to conceive, organic
-beings of all kinds, when domesticated or cultivated, have varied. We
-see this with the many domestic races of quadrupeds and birds belonging
-to different orders, with goldfish and silkworms, with plants of many
-kinds, raised in various quarters of the world. In the deserts of
-northern Africa the date-palm has yielded thirty-eight varieties; in the
-fertile plains of India it is notorious how many varieties of rice and
-of a host of other plants exist; in a single Polynesian island,
-twenty-four varieties of the breadfruit, the same number of the banana,
-and twenty-two varieties of the arum, are cultivated by the natives. The
-mulberry tree of India and Europe has yielded many varieties serving as
-food for the silkworm; and in China sixty-three varieties of the bamboo
-are used for various domestic purposes. These facts, and innumerable
-others which could be added, indicate that a change of almost any kind
-in the conditions of life suffices to cause variability—different
-changes acting on different organisms.”
-
-Darwin thinks that a change in climate alone is not one of the potent
-causes of variability, because the native country of a plant, where it
-has been longest cultivated, is where it has oftenest given rise to the
-greatest number of varieties. He thinks it also doubtful that a change
-in food is an important source of variability, since the domestic pigeon
-has varied more than any other species of fowl, yet the food has been
-always nearly the same. This is also true for cattle and sheep, whose
-food is probably much less varied in kind than in the wild species.
-
-Another point of interest is raised by Darwin. He thinks, as do others
-also, that the influence of a change in the conditions is cumulative, in
-the sense that it may not appear until the species has been subjected to
-it for several generations. Darwin states that universal experience
-shows that when new plants are first introduced into gardens they do not
-vary, but after several generations they will begin to vary to a greater
-or less extent. In a few cases, as in that of the dahlia, the zinnia,
-the Swan River daisy, and the Scotch rose, it is known that the new
-variations only appeared after a time. The following statement by Salter
-is then quoted, “Every one knows that the chief difficulty is in
-breaking through the original form and color of the species, and every
-one will be on the lookout for any natural sport, either from seed or
-branch; that being once obtained, however trifling the change may be,
-the result depends on himself.” Jonghe is also quoted to the effect that
-“there is another principle, namely, that the more a type has entered
-into a state of variation, the greater is the tendency to continue doing
-so, and the more it has varied from the original type, the more is it
-disposed to vary still further.” Darwin also quotes with approval the
-opinion of the most celebrated horticulturist of France, Vilmorin, who
-maintained that “when any particular variation is desired, the first
-step is to get the plant to vary in any manner whatever, and to go on
-selecting the most variable individuals, even though they vary in the
-wrong direction; for the fixed character of the species being once
-broken, the desired variation will sooner or later appear.”
-
-Darwin also cites a few cases where animals have changed quite quickly
-when brought under domestication. Turkeys raised from the eggs of wild
-species lose their metallic tints, and become spotted with white in the
-third generation. Wild ducks lose their true plumage after a few
-generations. “The white collar around the neck of the mallard becomes
-much broader and more irregular, and white feathers appear in the
-duckling’s wings. They increase also in size of body.” In these cases it
-appears that several generations were necessary in order to bring about
-a marked change in the original type, but the Australian dingoes, bred
-in the Zoological Gardens, produced puppies which were in the first
-generation marked with white and other colors.
-
-The following cases from De Varigny are also very striking. The dwarf
-trees from Japan, for the most part conifers, which may be a hundred
-years old and not be more than three feet high, are in part the result
-“of mechanical processes which prevent the spreading of the branches,
-and in part of a starving process which consists in cutting most roots
-and in keeping the plant in poor soil.”
-
-As an example of the sudden appearance of a new variation the following
-case is interesting. A variety of begonia is recorded as having appeared
-quite suddenly at a number of places at the same time. In another case a
-narcissus which had met with adverse circumstances, and had then been
-supplied with a chemical manure in some quantity, began to bear double
-flowers.
-
-Amongst animals the following cases of the appearance of sudden
-variations are pointed out by De Varigny. “In Paraguay, during the last
-century (1770), a bull was born without horns, although his ancestry was
-well provided with these appendages, and his progeny was also hornless,
-although at first he was mated with horned cows. If the horned and the
-hornless were met in fossil state, we would certainly wonder at not
-finding specimens provided with semi-degenerate horns, and representing
-the link between both, and if we were told that the hornless variety may
-have arisen suddenly, we should not believe it and we should be wrong.
-In South America also, between the sixteenth and eighteenth centuries
-the niata breed of oxen sprang into life, and this breed of bulldog oxen
-has thriven and become a new race. So in the San Paulo provinces of
-Brazil, a new breed of oxen suddenly appeared which was provided with
-truly enormous horns, the breed of franqueiros, as they are called. The
-mauchamp breed of sheep owes its origin to a single lamb that was born
-in 1828 from merino parents, but whose wool, instead of being curly like
-that of its parents, remained quite smooth. This sudden variation is
-often met with, and in France has been noticed in different herds.”
-
-The ancon race of sheep originated in 1791 from a ram born in
-Massachusetts having short crooked legs and a long back. From this one
-ram by crossing, at first with common sheep, the ancon race has been
-produced. “When crossed with other breeds the offspring, with rare
-exception, instead of being intermediate in character, perfectly
-resemble either parent; even one of twins has resembled one parent and
-the second the other.”
-
-Two especially remarkable cases remain to be described. These are the
-Porto Santo rabbit and the japanned peacock. Darwin has given a full
-account of both of these cases. “The rabbits which have become feral on
-the island of Porto Santo, near Madeira, deserve a fuller account. In
-1418 or 1419 J. Gonzales Zarco happened to have a female rabbit on board
-which had produced young during the voyage, and he turned them all out
-on the island. These animals soon increased so rapidly that they became
-a nuisance, and actually caused the abandonment of the settlement.
-Thirty-seven years subsequently, Cada Mosto describes them as
-innumerable; nor is this surprising, as the island was not inhabited by
-any beast of prey, or by any terrestrial mammal. We do not know the
-character of the mother rabbit; but it was probably the common domestic
-kind. The Spanish peninsula, whence Zarco sailed, is known to have
-abounded with the common wild species at the most remote historical
-period; and as these rabbits were taken on board for food, it is
-improbable that they should have been of any peculiar breed. That the
-breed was well domesticated is shown by the doe having littered during
-the voyage. Mr. Wollaston, at my request, brought two of these feral
-rabbits in spirits of wine; and, subsequently, Mr. W. Haywood sent home
-three more specimens in brine and two alive. These seven specimens,
-though caught at different periods, closely resemble each other. They
-were full-grown, as shown, by the state of their bones. Although the
-conditions of life in Porto Santo are evidently highly favorable to
-rabbits, as proven by their extraordinarily rapid increase, yet they
-differ conspicuously in their small size from the wild English
-rabbit.... In color the Porto Santo rabbit differs considerably from the
-common rabbit; the upper surface is redder, and is rarely interspersed
-with any black or black-tipped hairs. The throat and certain parts of
-the under surface, instead of being pure white, are generally gray or
-leaden color. But the most remarkable difference is in the ears and
-tail. I have examined many fresh English rabbits, and the large
-collection of skins in the British Museum from various countries, and
-all have the upper surface of the tail and the tips of the ears clothed
-with blackish gray fur; and this is given in most works as one of the
-specific characters of the rabbit. Now in the seven Porto Santo rabbits
-the upper surface of the tail was reddish brown, and the tips of the
-ears had no trace of the black edging. But here we meet with a singular
-circumstance: in June, 1861, I examined two of these rabbits recently
-sent to the Zoological Gardens and their tails and ears were colored as
-just described; but when one of their dead bodies was sent to me in
-February, 1863, the ears were plainly edged, and the upper surface of
-the tail was covered with blackish gray fur, and the whole body was much
-less red; so that under the English climate this individual rabbit had
-recovered the proper color of its fur in rather less than four years.”
-
-Another striking case of sudden variation is found in the peacock. It is
-all the more remarkable because this bird has hardly varied at all under
-domestication, and is almost exactly like the wild species living in
-India to-day. Darwin states: “There is one strange fact with respect to
-the peacock, namely, the occasional appearance in England of the
-‘japanned’ or ‘black-shouldered’ kind. This form has lately been named,
-on the high authority of Mr. Slater, as a distinct species, viz. _Pavo
-nigripennis_, which he believes will hereafter be found wild in some
-country, but not in India, where it is certainly unknown. The males of
-these japanned birds differ conspicuously from the common peacock in the
-color of their secondary wing-feathers, scapulars, wing-coverts, and
-thighs, and are, I think, more beautiful; they are rather smaller than
-the common sort, and are always beaten by them in their battles, as I
-hear from the Hon. A. S. G. Canning. The females are much paler-colored
-than those of the common kind. Both sexes, as Mr. Canning informs me,
-are white when they leave the egg, and they differ from the young of the
-white variety only in having a peculiar pinkish tinge on their wings.
-These japanned birds, though appearing suddenly in flocks of the common
-kind, propagate their kind quite truly.”
-
-In two cases, in which these birds had appeared quite suddenly in flocks
-of the ordinary kind, it is recorded that “though a smaller and weaker
-bird, it increased to the extinction of the previously existing breed.”
-Here we have certainly a remarkable case of a new species suddenly
-appearing and replacing the ordinary form, although the birds are
-smaller, and _are beaten in their battles_.
-
-Darwin has given an admirably clear statement of his opinion as to the
-_causes of variability_ in the opening paragraph of his chapter dealing
-with this topic in his “Animals and Plants.” Some authors, he says,
-“look at variability as a necessary contingent on reproduction, and as
-much an original law as growth or inheritance. Others have of late
-encouraged, perhaps unintentionally, this view by speaking of
-inheritance and variability as equal and antagonistic principles. Pallas
-maintained, and he has had some followers, that variability depends
-exclusively on the crossing of primordially distinct forms. Other
-authors attribute variability to an excess of food, and with animals, to
-an excess relatively to the amount of exercise taken, or again, to the
-effects of a more genial climate. That these causes are all effective is
-highly probable. But we must, I think, take a broader view, and conclude
-that organic beings, when subjected during several generations to any
-change whatever in their condition, tend to vary; the kind of variation
-which ensues depending in most cases in a far higher degree on the
-nature of the constitution of the being, than on the nature of the
-changed conditions.”
-
-Most naturalists will agree, in all probability, with this conclusion of
-Darwin’s. The examples cited in the preceding pages have shown that
-there are several ways in which the organisms may respond to the
-environment. In some cases it appears to affect all the individuals in
-the same way; in other cases it appears to cause them to fluctuate in
-many directions; and in still other cases, without any recognizable
-change in the external conditions, new forms may suddenly appear, often
-of a perfectly definite type, that depart widely from the parent form.
-
-For the theory of evolution it is a point of the first importance to
-determine which of these modes of variation has supplied the basis for
-evolution. Moreover, we are here especially concerned with the question
-of how adaptive variations arise. Without attempting to decide for the
-present between these different kinds of variability, let us examine
-certain cases in which an immediate and adaptive response to the
-environment has been described as taking place.
-
-
-Responsive Changes in the Organism that adapt it to the New Environment
-
-There is some experimental evidence showing that sometimes organisms
-respond directly and adaptively to certain changes in the environment.
-Few as the facts are, they require very careful consideration in our
-present examination. The most striking, perhaps, is the acclimatization
-to different temperatures. It has been found that while few active
-organisms can withstand a temperature over 45 degrees C., and that for
-very many 40 degrees is a fatal point, yet, on the other hand, there are
-organisms that live in certain hot springs where the temperature is very
-high. Thus, to give a few examples, there are some of the lower plants,
-nostocs and protococcus forms, that live in the geysers of California at
-a temperature of 93 degrees C., or nearly that of boiling water.
-Leptothrix is found in the Carlsbad springs, that have a temperature of
-44 to 54 degrees. Oscillaria have been found in the Yellowstone Park in
-water between 54 and 68 degrees, and in the hot springs in the
-Philippines at 71 degrees, and on Ischia at 85 degrees, and in Iceland
-at 98 degrees.
-
-It is probable from recent observations of Setchel that most of the
-temperatures are too high, since he finds that the water at the edge of
-hot springs is many degrees lower than that in the middle parts.
-
-The snail, _Physa acuta_, has been found in France living at a
-temperature of 35 to 36 degrees; another snail, Paludina, at Abano,
-Padua, at 50 degrees. Rotifers have been found at Carlsbad at 45 to 54
-degrees; Anguillidæ at Ischia at 81 degrees; _Cypris balnearia_, a
-crustacean at Hammam-Meckhoutin, at 81 degrees; frogs at the baths of
-“Pise” at 38 degrees.
-
-Now, there can be little doubt that these forms have had ancestors that
-were like the other members of the group, and would have been killed had
-they been put at once into water of these high temperatures, therefore
-it seems highly probable that these forms have become specially adapted
-to live in these warm waters. It is, therefore, interesting to find that
-it has been possible to acclimatize animals experimentally to a
-temperature much above that which would be fatal to them if subjected
-directly to it. Dutrochet (in 1817) found that if the plant, nitella,
-was put into water at 27 degrees, the currents in the protoplasm were
-stopped, but soon began again. If put now into water at 34 degrees they
-again stopped moving, but in a quarter of an hour began once more. If
-then put into water at 40 degrees the currents again slowed down, but
-began again later.
-
-Dallinger (in 1880) made a most remarkable series of experiments on
-flagellate protozoans. He kept them in a warm oven, beginning at first
-at a temperature of 16.6 degrees C. “He employed the first four months
-in raising the temperature 5.5 degrees. This, however, was not
-necessary, since the rise to 21 degrees can be made rapidly, but for
-success in higher temperatures it is best to proceed slowly from the
-beginning. When the temperature had been raised to 23 degrees, the
-organisms began dying, but soon ceased, and after two months the
-temperature was raised half a degree more, and eventually to 25.5
-degrees. Here the organisms began to succumb again, and it was necessary
-repeatedly to lower the temperature slightly, and then to advance it to
-25.5 degrees, until, after several weeks, unfavorable appearances
-ceased. For eight months the temperature could not be raised from this
-_stationary point_ a quarter of a degree without unfavorable
-appearances. During several years, proceeding by slow stages, Dallinger
-succeeded in raising the organisms up to a temperature of 70 degrees C.,
-at which the experiment was ended by an accident.”[27]
-
-Footnote 27:
-
-  Quoted from Davenport’s “Experimental Morphology.”
-
-Davenport and Castle carried out a series of experiments on the egg of
-the toad, in which they tried to acclimatize the eggs to a temperature
-higher than normal. Recently laid eggs were used; one lot kept at a
-temperature of 15 degrees C., the other at 24-25 degrees C. Both lots
-developed normally. At the end of four weeks the temperature point at
-which the tadpoles were killed was determined. Those reared at a
-temperature of 15 degrees C. died at 41 degrees C., or below; those
-reared at 24-25 degrees C. sustained a temperature 10 degrees higher; no
-tadpole dying in this set under 43 degrees C. “This increased capacity
-for resistance was not produced by the dying off of the less resistant
-individuals, for no death occurred in these experiments during the
-gradual elevation of the temperatures in the cultures.” The increased
-resistance was due, therefore, to a change in the protoplasm of the
-individuals. It was also determined that the acquired resistance was
-only very gradually lost (after seventeen days’ sojourn in cooler
-water). The explanation of this result may be due, in part, to the
-protoplasm containing less water at higher temperatures, for it is known
-that while the white of egg (albumen) coagulates at 56 degrees C. in
-aqueous solution; with only 18 per cent of water it coagulates between
-80 degrees and 90 degrees C.; and with 6 per cent, at 145 degrees C.;
-and without water between 100 degrees and 170 degrees C.
-
-It has long been known that organisms in the dry condition resist a much
-higher temperature. The damp uredospore is killed at 58.5 degrees to 60
-degrees C.; but dry spores withstand 128 degrees C. It is also known
-that organisms may become acclimatized to cold through loss of water,
-but we lack exact experimental data to show to what extent this can be
-carried.
-
-There are also some experiments that go to show that animals may become
-attuned to certain amounts of light, but the facts in this connection
-will be described in another chapter.
-
-Some important results have been obtained by accustoming organisms to
-solutions containing various amounts of salts. A number of cases of this
-sort are given by De Varigny. It has been found that littoral marine
-animals that live where the water may become diluted by the rain, or by
-rivers, survive better when put into fresh water than do animals living
-farther from the shore. Thus the oyster, the mussel, and the snail,
-Patella, withstand immersion in fresh water better than other animals
-that live farther out at sea. The reverse is also true; fresh-water
-forms, such as Lymnæa, Physa, Paludina, and others may be slowly
-acclimatized to water containing more salt. The forms mentioned above
-could be brought by degrees into water containing 4 per cent of salt,
-which would have killed the animals if they had been brought suddenly
-into it. Similar results have been obtained for amœba.
-
-It has been shown that certain rotifers and tardigrades, and also some
-unicellular animals, that live in pools and ponds that are liable to
-become dry, withstand desiccation, while other members of the same
-groups, living in the sea, do not possess this power of resistance.
-Cases of this sort are usually explained as cases of adaptation, but it
-has not been shown experimentally that resistance to drying can be
-acquired by a process of acclimatization to this condition. The case is
-also in some respects different from the preceding, since intermediate
-conditions are less likely to be met with, or to be of sufficiently long
-duration for the animal to become acclimatized to them. It seems more
-probable, in such cases, that these forms have been able to live in such
-precarious conditions from the beginning because they could resist the
-effects of drying, not that they have slowly acquired this power.
-Finally, there must be discussed the question of the acclimatization to
-poisons, to which an individual may be rendered partially immune. The
-point of special importance in this connection is that the animal may be
-said to respond adaptively to a large number of substances, which it has
-never met before in its individual history, or to which its ancestors
-have never been subjected. It may become slowly adapted to many
-different kinds of injurious substances. These cases are amongst the
-most important adaptive individual responses with which we are familiar,
-and the point cannot be too much emphasized that organisms have this
-latent capacity without ever having had an opportunity to acquire it
-through experience.
-
-The preceding groups of phenomena, included under the general heading of
-individual acclimatization, have one striking thing in common, namely,
-that a physiological adaptation is brought about without a corresponding
-change in form, although we must suppose that the structure has been
-altered in certain respects at least. The form of the individual remains
-the same as before, but so far as its powers of resistance are concerned
-it is a very different being.
-
-In regard to the perpetuation of the advantages gained by means of this
-power of adaptation, it is clear in those cases in which the young are
-nourished during their embryonic life by the mother, that, in this way,
-the young may be rendered immune to a certain extent, and there are
-instances of this sort recorded, especially in the case of some
-bacterial diseases. Whether this power can also be transmitted through
-the egg, in those instances in which the egg itself is set free and
-development takes place outside the body, has not been shown. In any
-case, the effect appears not to be a permanent one and will wear off
-when the particular poison no longer acts. It is improbable, therefore,
-that any permanent contribution to the race could be gained in this way.
-Adaptations of this sort, while of the highest importance to the
-individual, can have produced little direct effect on the evolution of
-new forms, although it may have been often of paramount importance to
-the individuals to be able to adapt themselves, or rather to become able
-to resist the effect of injurious substances. The important fact in this
-connection is the wonderful latent power possessed by all animals. So
-many, and of such different kinds, are the substances to which they may
-become immune, that it is inconceivable that this property of the
-organism could ever have been acquired through experience, no matter how
-probable it may be made to appear that this might have occurred in
-certain cases of fatal bacterial diseases. And if not, in so many other
-cases, why invent a special explanation for the few cases?
-
-We may defer the general discussion of the rôle that external factors
-have played in the adaptation of organisms, until we have examined some
-of the theories which attribute changes to internal factors. The idea
-that something innate in the living substance itself has served as the
-basis for evolution has given rise to a number of different hypotheses.
-That of the botanist Nägeli is one of the most elaborately worked out
-theories of this sort that has been proposed, and may be examined by way
-of illustration.
-
-
-                     Nägeli’s Perfecting Principle
-
-Nägeli used the term _completing principle_ (“Vervollkommungsprincip”)
-to express a tendency toward perfection and specialization.
-Short-sighted writers, he says, have pretended to see in the use of this
-principle something mystical, but on the contrary it is intended that
-the term shall be employed in a purely physical sense. It represents the
-law of inertia in the organic realm. Once set in motion, the
-developmental process cannot stand still, but must advance in its own
-direction. Perfection, or completion, means nothing else than the
-advance to complicated structure, “but since persons are likely to
-attach more meaning to the word _perfection_ than is intended, it would
-perhaps be better to replace it with the less objectionable word
-_progression_.”
-
-Nägeli says that Darwin, having in view only the condition of
-adaptation, designates that as more complete which gives its possessor
-an advantage in the battle for existence. Nägeli claims that this is not
-the only criterion that applies to organisms, and it leaves out the most
-important part of the phenomenon. There are two kinds of completeness
-which we should keep distinctly apart: (1) the completeness of
-organization characterized by the complication of the structure and the
-most far-reaching specialization of the parts; (2) the completeness of
-the adaptation, present at each stage in the organization, which
-consists in the most advantageous development of the organism (under
-existing conditions) that is possible with a given complication of
-structure and a given division of functions.
-
-The first of these conceptions Nägeli always calls “completeness”
-(Vollkommenheit), for want of a simpler and better expression; the
-second he calls adaptation. By way of illustrating the difference
-between the two, the following examples may be given. The unicellular
-plants and the moulds are excellently adapted each to its conditions of
-life, but they are much less complete in structure than an apple tree,
-or a grape vine. The rotifers and the leeches are well adapted to their
-station, but in completeness of structure they are much simpler than the
-vertebrates.
-
-If we consider only organization and division of labor as the work of
-the completing principle, and leave for the moment adaptation out of
-account, we may form the following picture of the rise of the organic
-world. From the inorganic world there arose the simplest organic being
-thinkable, being little more than a drop of substance. If this underwent
-any change at all, it would have been necessarily in the direction of
-greater complication of structure; and this would constitute the first
-step in the upward direction. In this way Nägeli imagines the process
-once begun would continue. When the movement has reached a certain
-point, it must continue in the same direction. The organic kingdom
-consists, therefore, of many treelike branches, which have had a common
-starting-point. Not only does he suppose that organisms were once
-spontaneously generated, and began their first upward course of
-development, but the process has been repeated over and over again, and
-each time new series have been started on the upward course. The organic
-kingdom is made up, therefore, of all degrees of organization, and all
-these have had their origins in the series of past forms that arose and
-began their upward course at different times in the past. Those that are
-the highest forms at the present time represent the oldest series that
-successfully developed; the lowest forms living at the present time are
-the last that have appeared on the scene of action.
-
-Organisms, as has been said, are distinguished from one another, not
-only in that one is simpler and another more complicated, but also in
-that those standing at the same stage of organization are unequally
-differentiated in their functions and in their structure, which is
-connected primarily with certain external relations which Nägeli calls
-adaptations.
-
-Adaptation appears at each stage of the organization, which stage is,
-for a given environment, the most advantageous expression of the main
-type that was itself produced by internal causes. For this condition of
-adaptation, a sufficient cause is demanded, and this is, as Nägeli tries
-to show later, the result of the inherited response to the environment.
-In many cases this cause will continue to act until complete adaptation
-is gained; in other cases, the external conditions give a direction
-only, and the organism itself continues the movement to its more perfect
-condition.
-
-The difference between the conception of the organic kingdom as the
-outcome of mechanical causes on the one hand, or of competition and
-extermination on the other hand, can be best brought out, Nägeli thinks,
-by the following comparison of the two respective methods of action.
-There might have been no competition, and no consequent extermination in
-the plant kingdom, if from the beginning the surface of the earth had
-continually grown larger in proportion as living things increased in
-numbers, and if animals had not appeared to destroy the plants. Under
-these conditions each germ could then have found room and food, and have
-unfolded itself without hinderance. If now, as is assumed to be the case
-on the Darwinian theory, individual variations had been in all
-directions, the developmental movement could not have gone beyond its
-own beginnings, and the first-formed plants would have remained swinging
-now on one side and now on another of the point first reached. The whole
-plant kingdom would have remained in its entirety at its first stage of
-evolution, that is, it would never have advanced beyond the stage of a
-naked drop of plasma with or without a membrane. But, according to the
-further Darwinian conception, competition, leading to extermination, is
-capable of bringing such a condition to a higher stage of development,
-since it is assumed that those individuals which vary in a beneficial
-direction would have an advantage over those that have not taken such a
-step, or have made a step backward.
-
-If, on the other hand, under the above-mentioned conditions of
-unrestricted development, without competition, variations were
-determined by “_mechanical principles_,” then, according to Nägeli’s
-view, all plant forms that now exist would still have evolved, and would
-be found living at the present time, but along with all those that now
-exist there would be still other forms in countless numbers. These would
-represent those forms which have been suppressed. On Nägeli’s view
-competition and suppression do not produce new forms, but only weed out
-the intermediate forms. He says without competition the plant kingdom
-would be like the Milky Way; in consequence of competition the plant
-kingdom is like the firmament studded with bright stars.
-
-The plant kingdom may also be compared to a branched tree, the ends of
-whose branches represent living species. This tree has an inordinate
-power of growth, and if left to itself it would produce an impenetrable
-tangle of interwoven branches. The gardener prevents this crowding by
-cutting away some of the parts, and thus gives to the tree distinct
-branches and twigs. The tree would be the same without the watchful
-trimming of the gardener, but without definite form.
-
-Nägeli states: “From my earlier researches I believe that the external
-influences are small in comparison to the internal ones. I shall speak
-here only of the influences of climate and of food, which are generally
-described as the causes of change, without however any one’s having
-really determined whether or not a definite result can be brought about
-by these factors. Later I shall speak of a special class of external
-influences which, according to my view, bring forth beyond a doubt
-adaptive changes.”
-
-The external influence of climate and of food act only as transitory
-factors. A rich food supply produces fat, lack of food leads to
-leanness, a warm summer makes a plant more aromatic, and its fruit
-sweeter; a cold year means less odor and sour fruit. Of two similar
-seeds the one sown in rich soil will produce a plant with many branches
-and abundance of flowers; the other, planted in sandy soil, will produce
-a plant without branches, with few flowers, and with small leaves. The
-seeds from these two plants will behave in exactly the same way; they
-have inherited none of the differences of their parents. Influences of
-this sort, even if extending over many generations, have no permanent
-effect. Alpine plants that have lived since the ice age under the same
-conditions, and have the characters of true high-mountain plants, lose
-these characters completely during the first summer, if transplanted to
-the plains. Moreover, it makes no difference whether the seed or the
-whole plant itself be transferred. In place of the dwarfed, unbranched
-growth, and the reduced number of organs, the plant when transferred to
-the plains shoots up in height, branches strongly, and produces numerous
-leaves and flowers. The plants retain their new characters as long as
-they live in the plain without any other new variation being observed in
-them.
-
-Other characteristics also, which arise from different kinds of external
-influences due to different localities, such as dampness and shade, a
-swampy region, or different geological substrata, last only so long as
-the external conditions last.
-
-These transient peculiarities make up the characters of local varieties.
-That they have no permanency is intelligible, since they exhibit no new
-characters, but the change consists mainly in the over- or
-under-development of those peculiarities that are dependent on external
-influences. The effect of these influences may be compared to an elastic
-rod, which, however much it may be distorted by external circumstances,
-returns again to its original form as soon as released.
-
-Besides these temporary changes, due to external influences, there are
-many cases known in which the same plant lives under very diverse
-conditions and yet remains exactly the same. For example, the species of
-_Rhododendron ferragineum_ lives on archæan mountains and especially
-where the soil is poor in calcium. Another species, _Rhododendron
-hirsutum_ is found especially on soil rich in calcium. The difference in
-the two species has been supposed to depend on differences in the soil,
-and if so, we would imagine that, if transplanted for a long time, the
-one should change in the direction of the other. Yet it is known that
-the rusty rhododendron may be found in all sorts of localities, even on
-dry, sunny, calcareous rocks of the Apennines and of the Jura, and
-despite its residence in these localities, since the glacial epoch, no
-change whatever has taken place.
-
-Single varieties of the large and variable genus of _Hieracium_ have
-lived since the glacial period in the high regions of the Alps,
-Carpathians, and in the far north, and also in the plains of different
-geological formations, but these varieties have remained exactly the
-same, although on all sides there are transitional forms leading from
-these to other varieties.
-
-Some parasitic species also furnish excellent illustrations of the same
-principle. Besides the several species of Orobanchia and of the
-parasitic moulds, the mistletoe deserves special mention. It lives on
-both birch and apple trees and on both presents exactly the same
-appearance; and even if it is true that mistletoe growing on conifers
-presents certain small deviations in its character, it is still doubtful
-whether, if transferred to the birch or apple tree, it would not lose
-these differences, thus indicating that they are not permanent.
-
-It is a fact of general observation that, on the one hand, the same
-variety occurs in different localities and under different surroundings,
-and, on the other hand, that slightly different varieties live together
-in the same place and therefore under the same external conditions. It
-is evident, then, that food conditions have neither originated the
-differences nor kept them up. The rarer cases in which in different
-localities different varieties exist show nothing, because competition
-and suppression keep certain varieties from developing where it would be
-possible otherwise for them to exist.
-
-Nägeli says his conclusion may be tested from another point of view. If
-food conditions, as is generally supposed, have a definite, _i.e._ a
-permanent, effect on the organism, then all organisms living under the
-same conditions should show the same characters. Indeed, it has been
-claimed in some instances that this is actually the case. Thus it is
-stated that dry localities cause plants to become hairy, and that
-absence of hairiness is met with in shady localities. This may apply to
-certain species, but in other cases exactly the reverse is true, and
-even the same species behaves differently in different regions, as in
-_Hieracium_. And so it is with all characteristics which are ascribed to
-external influences. As soon as it is supposed a discovery has been made
-in this direction, we may rest assured that in other cases the reverse
-will be found to hold. We have had, in respect to the influence of the
-outer world on organisms, the same experience as with the rules for the
-weather,—when we come to examine the facts critically there are found to
-be as many exceptions as confirmations of the rule.
-
-If climatic influence has a definite effect, the entire flora of a
-special locality ought to have the same peculiarities, but this stands
-in contradiction to all the results of experience. The character of the
-vegetation is not determined by the environment of the plants but by
-their prehistoric origin, and as the result of competition. Nägeli
-concludes his discussion with the statement that all of our experience
-goes to show that the effects of external influences (climate and food)
-appear at once, and their results last only as long as the influences
-themselves last, and are then lost, leaving nothing permanent behind.
-This is true even when the external influences have lasted for a long
-time,—since the glacial epoch, for instance. We find, he claims, nothing
-that supports the view that such influences are inherited.
-
-If we next examine the question of changes from _internal causes_,
-Nägeli claims that here also observation and research fail to show the
-origin of a new species, or even of a new variety from external causes.
-In the organic world little change has taken place, he believes, since
-the glacial epoch. Many varieties have even remained the same throughout
-the whole intervening time; and while it cannot be doubted that new
-varieties have also been formed, yet the cause of their origin cannot be
-empirically demonstrated. The permanent, hereditary characters, of whose
-origin we know something from experience, belong to the individual
-changes which have appeared under cultivation in the formation of
-domestic races. These are for the most part the result of crossing. So
-far as we have any definite information as to the origin of the changes,
-they are the result of inner, and never of external, causes. We
-recognize that this must be the case, since under the same external
-conditions individuals behave differently—in the same flower-bud some
-seeds give rise to plants like the parent, others to altered ones. The
-strawberry with a single leaflet, instead of three, arose in the last
-century in a single individual amongst many other ordinary plants. From
-the ten seeds of a pear Van Mons obtained as many different kinds of
-pears. The most conclusive proof of the action of inner causes is most
-clearly seen when the branches of the same plant differ. In Geneva a
-horse-chestnut bore a branch with “filled” flowers, and from this
-branch, by means of cuttings, this variation has been carried over all
-Europe. In the Botanic Garden at Munich there is a beech with small
-divided leaves; but one of its branches produces the common broad
-undivided leaves. Many such examples have been recorded which can only
-be explained by assuming that a cell, or a group of cells, like those
-from which the other branches arose, have become changed in some unknown
-way as the result of inner causes. The properties that are permanent and
-inherited are contained in the idioplasm, which the parent transmits to
-its offspring. A cause that permanently transforms the organism must
-also transform the idioplasm. How powerless, in comparison to internal
-causes, the external causes are is shown most conclusively in grafting.
-The graft, although it receives its nourishment through the stock, which
-may be another species, remains itself unchanged.
-
-Nägeli makes the following interesting comparison between the
-development of the individual from an egg, and the evolution, or
-development, of the phylum. No one will doubt that the egg during the
-entire time of its process of transformation is guided by internal
-factors. Each successive stage follows with mechanical necessity from
-the preceding. If an animal can develop from inner causes from a drop of
-plasma, why should not the entire evolutionary process have also been
-the outcome of developmental inner causes? He admits that there is a
-difference in the two cases in that the plasma that forms the egg has
-come from another animal, and contains all the properties of the
-individual in a primordial condition. In the other case we must suppose
-that the original drop of plasma did not contain at first the primordium
-of definite structures, but only the ability to form such. Logically the
-difference is unimportant. The main point is that in the primordium of
-the germ a special peculiarity of the substance is present which by
-forming new substances grows, and changes as it grows, and the one
-change of necessity excites the next until finally a highly organized
-being is the result.
-
-Nägeli discusses a question in this connection, which, he says, has been
-unnecessarily confused in the descent theory. Since we are entirely in
-the dark as to how much time has been required for the formation of
-phyla, so also are we ignorant as to how long it may have taken for each
-step in advance. We may err equally in ascribing too much and too little
-time to the process. It is, moreover, not necessary that for every step
-the same amount of time should have been required. On the contrary, the
-probability is that recognizable changes may at times follow each other
-rapidly, and then for a time come to a standstill,—just as in the
-development of the individual there are periods of more rapid and others
-of less rapid change.
-
-A more difficult problem than that relating to the sort of changes the
-external influences bring about in the organism, is the question as to
-how they effect the organism, or how they act on it mechanically. This,
-as is well known, was answered by Darwin, who regards all organization
-as a problem of adaptation: only those chance variations surviving which
-are capable of existence, the others being destroyed. On this theory
-external influences have only a negative or a passive action, namely, in
-setting aside the unadapted individuals. Nägeli, on the other hand,
-looks upon some kinds of external conditions as directly giving rise to
-the adaptive characters of the organism. This is accomplished, he
-supposes, in the following ways: two kinds of influence are recognized;
-_the direct action_, which, as in inorganic nature, comes to an end when
-the external influences come to an end, as when cold diminishes the
-chemical actions in the plant; and _the indirect action_, generally
-known as a stimulus, which starts a series of molecular motions,
-invisible to us, but which we recognize only in their effects. Very
-often the stimulus starts only a reflex action, usually at the place of
-application.
-
-A stimulus acting for but a short time produces no lasting effect on the
-idioplasm. A person stung by a wasp suffers no permanent effect from the
-injury. But if a stimulus acts for a long time, and through a large
-number of generations, then it may, even if of small strength, so change
-the _idioplasm_, that a tendency or disposition capable of being seen
-may be the result. This appears to be the case in regard to the action
-of light, which causes certain parts of the plant to turn toward it and
-others away from it; also for the action of gravity, which determines
-the downward direction of the roots. It may be claimed, perhaps, that
-these are the results of direct influence and not of an internal
-response, but this is not the case; for some plants act in exactly the
-opposite way, and send a stem downward, as in the case of the
-cleistogamous flowers of _Cardamine chenopodifolia_; and other plants
-turn away from the light. This means that the idioplasm behaves
-differently in different plants in response to the same stimulus.
-
-Concerning the more visible effects of adaptation, Nägeli states that in
-regard to some of them there can be no question as to how they must have
-arisen. Protection against cold, by the formation of a thick coat of
-hair, is the direct result of the action of the cold on the skin of the
-animal. The different weapons of offence and of defence, horns, spurs,
-tusks, etc., have arisen, he maintains, through stimulus to those parts
-of the body where these structures arise.
-
-The causes of the other adaptations, especially of those occurring in
-plants, are less obvious. Land plants protect themselves from drying by
-forming a layer of cork over the surface. The most primitive plants were
-water plants, which acclimated themselves little by little to moist, and
-then to dry, air. When they first emerged from the water the drying
-acted as a stimulus on the surface, and caused it to harden in the same
-way as a drop of glue hardens. This hardening in turn acted as a
-stimulus, causing a chemical transformation of the surface into a corky
-substance. This effect was inherited, and in this way the power to form
-cork originated.
-
-Land plants have, in addition to the soft parts, the hard bast and wood
-which serves the mechanical purpose of supporting the soft tissues and
-protecting them from being injured. The arrangement of the hard parts is
-such as to suggest that they are the result of the action of pressures
-and tensions on the plant, for the strongest cells are found where there
-is most need for them. It is easy to imagine, Nägeli adds, that this
-important arrangement of the tissues is the result of external forces
-which brought about the result in these parts.
-
-Nägeli accounts for the origin of twining plants as follows. Being
-overshadowed by other plants, the stem will grow rapidly in the damp
-air. Coming in contact with the stems of other plants, the delicate stem
-is stimulated on one side, and grows around the point of contact. This
-tendency becomes inherited, and the habit to twine is ultimately
-established.
-
-The difference in the two sides of leaves is explained by Nägeli as the
-result of the difference in the illumination of the two sides. This
-influence of light on the leaf has been inherited. The formation of the
-tubular corolla that is seen in many plants visited by insects is
-explained as the result of the stimulus produced by the insects in
-looking for the pollen. The increase in the length of the proboscis of
-the insect is the result of the animal straining to reach the bottom of
-the ever elongating tube of the corolla. “The tubular corolla and the
-proboscis of the insect appear as though made for each other. Both have
-slowly developed to their present condition, the long tube from a short
-tube and the long proboscis from a short one.” Thus, by purely
-Lamarckian principles, Nägeli attempts to account for many of the
-adaptations between the organism and the outer world. But if this takes
-place, where is there left any room for the action for his so-called
-perfecting principle? Nägeli proceeds to show how he supposes that the
-two work together.
-
-As a result of inner causes the organism would pass through a series of
-perfectly definite stages, J, J^1, J^2. But if, at any stage, external
-influences produced an effect on the organism so that the arrangement of
-the idioplasm changes in response, a new adaptation is produced. In this
-way new characters, not inherent in the idioplasm, may be added, and old
-ones be changed or lost. “In order not to be misunderstood in regard to
-the completing or perfecting principle I will add, that I ascribe to it
-no determinate action in the organism, neither in producing the long
-neck of the giraffe, nor the prehensile tail of the ape, neither the
-claws of the crab, nor the decoration of the bird of paradise. These
-structures are the outcome of both factors. I cannot picture to myself
-how external causes alone, and just as little how internal causes alone,
-could have changed a monad into a man.” But Nägeli goes on to say, that
-if at any stage of organization one of the two causes should cease to
-act, the other could only produce certain limited results. Thus, if
-external causes alone acted, the organization would remain at the same
-stage of completeness, but might become adapted to all kinds of external
-conditions—a worm, for instance, would not develop into a fish, but
-would remain a worm forever, although it might change its worm structure
-in many ways in response to external stimuli. If, on the other hand,
-only the completing principle acted, then without changing its
-adaptations the number of the cells and the size of the organs might be
-increased, and functions that were formerly united might become
-separated. Thus, without altering the character of the organism, a more
-highly developed (in the sense of being more specialized) organism would
-appear.
-
-Nägeli, as we have just seen, has attempted to build up a conception of
-nature based on two assumptions, neither of which has been demonstrated
-to be an actual principle of development. His hypothesis appears,
-therefore, entirely arbitrary and speculative to a high degree. Even if
-it were conceivable that two such principles as these control the
-evolution of organisms, it still requires a good deal of imagination to
-conceive how the two go on working together. Moreover, it is highly
-probable that whole groups have evolved in the direction of greater
-simplification, as seen especially in the case of those groups that have
-become degenerate. To what principle can we refer processes of this
-sort?
-
-It is certainly a strange conclusion this, at which Nägeli finally
-arrives, for, after strenuously combating the idea that the external
-factors of climate and of food have influence in producing new species,
-he does not hesitate to ascribe all sorts of imaginary influences to
-other external causes. The apparent contradiction is due, perhaps, to
-the fact that his experience with actual species led him to deny that
-the direct action of the environment produces permanent changes, while
-in theory he saw the necessity of adding to his perfecting principle
-some other factor to explain the adaptations of the new forms produced
-by inner causes. Nägeli seems to have felt strongly the impossibility of
-explaining the process of evolution and of adaptation as the outcome of
-the selection of chance variations, now in this direction, now in that.
-He seems to have felt that there must be something within the organism
-that is driving it ever upward, and he attempts to avoid the
-teleological element, which such a conception is almost certain to
-introduce, by postulating the inheritance of the effects of
-long-continued action of the environment, in so far as certain factors
-in the environment produce a response in the organism. Nevertheless,
-this combination is not one that is likely to commend itself, aside from
-the fact that the assumptions have no evidence to support them. Despite
-Nägeli’s protest that his principles are purely physical, and that there
-is nothing mystical in his point of view, it must be admitted that his
-conception, as a whole, is so vague and difficult in its application
-that it probably deserves the neglect which it generally receives.
-
-Nägeli’s wide experience with living plants convinced him that there is
-something in the organism over and beyond the influence of the external
-world that causes organisms to change; and we cannot afford, I think, to
-despise his judgment on this point, although we need not follow him to
-the length of supposing that this internal influence is a “force”
-driving the organism forward in the direction of ever greater
-complexity. A more moderate estimate would be that the organism often
-changes through influences that appear to us to be internal, and while
-some of the changes are merely fluctuating or chance variations, there
-are others that appear to be more limited in number, but perfectly
-definite and permanent in character. It is the latter, which, I believe,
-we can safely accredit to internal factors, and which may be compared to
-Nägeli’s internal causes, but this is far from assuming that these
-changes are in the direction of greater completeness or perfection, or
-that evolution would take place independently of the action of external
-agencies.
-
-
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-
-
-
-
-                               CHAPTER X
-
-            THE ORIGIN OF THE DIFFERENT KINDS OF ADAPTATIONS
-
-
-In the present chapter we may first consider, from the point of view of
-discontinuous variations as contrasted with the theory of the selection
-of individual variations, the structural adaptations of animals and
-plants, _i.e._ those cases in which the organism has a definite form
-that adapts it to live in a particular environment. In the second place,
-we may consider those adaptations that are the result of the adjustment
-of each individual to its surroundings. In subsequent chapters the
-adaptations connected with the responses of the nervous system and with
-the process of sexual reproduction will be considered.
-
-It should be stated here, at the outset, that the term _mutation_ will
-be used in the following chapters in a very general way, and it is not
-intended that the word shall convey only the idea which De Vries
-attaches to it; it is used rather as synonymous with _discontinuous and
-also definite variation_ of all kinds. The term will be used to include
-“the single variations” of Darwin, “sports,” and even orthogenic
-variation, if this has been definite or discontinuous.
-
-
-                           Form and Symmetry
-
-Almost without exception, animals and plants have definite and
-characteristic forms. In other words, they are not amorphous masses of
-substance. The members of each species conform, more or less, to a sort
-of ideal type. Our first problem is to examine in what sense the form
-itself may be looked upon as an adaptation to the surroundings.
-
-It is a well-recognized fact that the forms of many animals appear to
-stand in a definite relation to the environment. For instance, animals
-that move in definite directions in relation to their structure have the
-anterior and the posterior ends quite different, and it is evident that
-these ends stand in quite different relations to surrounding objects;
-while, on the other hand, the two sides of the body which are, as a
-rule, subjected to the same influences are nearly exactly alike. The
-dorsal and the ventral surfaces of the body are generally exposed to
-very different external conditions, and are quite different in
-structure.
-
-The relation is so obvious in most cases that it might lead one quite
-readily to conclude that the form of the animal had been moulded by its
-surroundings. Yet this first impression probably gives an entirely wrong
-conception of how such a relation has been acquired. Before we attempt
-to discuss this question, let us examine some typical examples.
-
-A radial type of structure is often found in fixed forms, and in some
-floating forms, like the jellyfish. In a fixed form, a sea-anemone, for
-instance, the conditions around the free end and the fixed end of the
-body are entirely different, and we find that these two ends are also
-different. The free end contains the special sense-organs, the mouth,
-tentacles, etc.; while the fixed end contains the organ for attachment.
-It is evident that the free end is exposed to the same conditions in all
-directions, and it may seem probable that this will account for the
-radial symmetry of the anemone. There are also a few free forms, the
-sea-urchin for instance, that have a radial symmetry. Whether their
-ancestors were fixed forms, for which there is some evidence, we do not
-know definitely; but, even if this is true, it does not affect the main
-point, namely, that, although at present free to move, the sea-urchin is
-radially symmetrical. But when we examine its method of locomotion, we
-find that it moves indifferently in any direction over a solid surface;
-that is, it keeps its oral face against a solid object, and moves over
-the surface in any direction. Under these circumstances the same
-external conditions will act equally upon all sides of the body. In
-contrast to these common sea-urchins, there are two other related
-groups, in which, although traces of a well-marked radial symmetry are
-found, the external form has been so changed that a secondary bilateral
-form has been superimposed on it. These are the groups of the
-clypeasters and the spatangoids, and it is generally supposed that their
-forefathers were radially symmetrical forms like the ordinary forms of
-sea-urchins. These bilateral forms move in the direction of their plane
-of symmetry, but we have no means of knowing whether they first became
-bilateral and, in consequence, now move in the direction of the median
-plane, or whether they acquired the habit of moving in one direction,
-and in consequence acquired a bilateral symmetry. It seems more probable
-that the form changed first, for otherwise it is difficult to see why a
-change of movement in one direction should ever have taken place.
-
-The radially symmetrical form is characteristic of many flowers that
-stand on the ends of their stalks. They also will be subjected to
-similar external influences in all directions. Many flowers, on the
-other hand, are bilaterally symmetrical. Some of these forms are of such
-a sort that they are generally interpreted as having been acquired in
-connection with the visits of insects. Be this as it may, it is still
-not clear why, if the flowers are terminal, insects should not approach
-them equally from every direction. If the flowers are not terminal, as,
-in fact, many of them are not, their relation to the surroundings is
-bilateral with respect to internal as well as to external conditions.
-The former, rather than the latter, may have produced the bilateral form
-of the flower. Here also we meet with the problem as to whether the
-flowers, being lateral in position, have assumed a bilateral form
-because their internal relations were bilateral; or whether an external
-relation, for example, the visits of insects, has been the principle
-cause of their becoming bilateral.
-
-
-[Illustration:
-
-  Fig. 4.—A, right and left claws of lobster;
-  B, of the fiddler-crab; and
-  C, of Alpheus.]
-
-In some bilateral forms the right and left sides may be unsymmetrical in
-certain organs. Right and left handedness in man is the most familiar
-example, although the structural difference on which this rests is not
-very obvious. More striking is the difference in the two big claws of
-the lobster (Fig. 4 A). One of the two claws is flat and has a fine
-saw-toothed edge. The other is thicker and has rounded knobs instead of
-teeth. It is said that these two claws are used by the lobster for
-different purposes,—the heavy one for crushing and for holding on, and
-the narrower for cutting up the food. If this is true, then we find a
-symmetrical organism becoming unsymmetrical, and in consequence it takes
-advantage of its asymmetry by using its right and left claws for
-different purposes.
-
-More striking still is the difference in the size of the right and left
-claws in a related form, Alpheus—a crayfish-like form that lives in the
-sea. With the larger claw (Fig. 4 C) it makes a clicking sound that can
-be heard for a long distance. In some of the crabs the difference in the
-size of the two claws is enormous, as in the male fiddler-crab, for
-example (Fig. 4 B). One of the claws is so big and unwieldy that it must
-put the animal at a distinct disadvantage. Its use is unknown, although
-it has been suggested that it is a secondary sexual character.
-
-The asymmetry of the body of the snail is very conspicuous, at least so
-far as certain organs are concerned. The foot on which the animal crawls
-and the head have preserved their bilaterality; but the visceral mass of
-the animal, contained in the spirally wound shell, lying on the middle
-of the upper surface of the foot, is twisted into a spiral form. Many of
-the organs of one side of the body are atrophied. The gill, the kidney,
-the reproductive organ, and one of the auricles of the heart have
-completely, or almost completely, disappeared. The cause of this loss
-seems to be connected with the spiral twist of the visceral mass. One of
-the consequences of the twisting has been to bring the organs of the
-left side of the body around the posterior end until they come to lie on
-the right side, the organs of the original right side being carried
-forward and there atrophying.
-
-There is another remarkable fact connected with the asymmetry of the
-snail. In some species, _Helix pomatia_, for example, the twist has been
-toward the right, _i.e._ in the direction which the hands of a watch
-follow when the face is turned upward toward the observer. Individuals
-twisted in this direction are called dextral. Occasionally there is
-found an individual with the spiral in the opposite direction
-(sinistral), and in this the conditions of the internal organs are
-exactly reversed. It is the left set of organs that is now atrophied,
-and the right set that is functional. Such changes appear suddenly.
-Organs of one side of the body that have not been functional for many
-generations may become fully developed. Moreover, Lang has shown that
-when a sinistral form breeds with a normal dextral form, or even when
-sinistral forms are bred with each other, the young are practically all
-of the ordinary type.
-
-An attempt has been made to connect these facts with the mode of
-development of the mollusks. It is known that the eggs of a number of
-gasteropod mollusks segment in a perfectly definite manner. A sort of
-spiral cleavage is followed by the formation of a large mesodermal cell
-from the left posterior yolk-cell. From this mesodermal cell nearly all
-the mesodermal organs of the body are formed. Thus it may appear that
-the spiral form of the snail is connected with the spiral form of the
-cleavage. In a few species of marine and fresh-water snails the cleavage
-spiral is reversed, and the mesoderm arises from the right posterior
-yolk-cell. It has been shown in several cases that the snail coming from
-such an egg is twisted in the reverse direction from that of ordinary
-snails.
-
-It has been suggested, therefore, that the occasional sinistral
-individual of Helix arises from an egg cleaving in the reverse
-direction, and there is nothing improbable in an assumption of this
-kind. No attempt has been made as yet to explain why, in some cases, the
-cleavage spiral is turned in one direction, and in other cases in the
-reverse direction; but even leaving this unaccounted for, the assumption
-of the unusual form of Helix being the result of a reversal of the
-cleavage throws some light as to how it is possible for the complete
-reversal of the organs of the adult to arise. If it is assumed that in
-the early embryo the cells on each side of the median line are alike,
-and at this time capable of forming adult structures, a simple change of
-the spiral from right to left might determine on which side of the
-middle line the mesodermal cell would lie, and its presence on one side
-rather than on the other might determine which side of the embryo would
-develop, and which would not. This possibility removes much of the
-mystery which may appear to surround a sudden change of this sort.
-
-It seems to me that we shall not go far wrong if we assume that it is
-largely a matter of indifference whether an individual snail is a
-right-handed or a left-handed form, as far as its relation to the
-environment is concerned. One form would have as good a chance for
-existing as the other. If this is granted, we may conclude that, while
-in most species a perfectly definite type is found, a right or a left
-spiral, yet neither the one nor the other has been acquired on account
-of its relation to the environment. This conclusion does not, of course,
-commit us in any way as to whether the spiral form of the visceral mass
-has been acquired in relation to the environment, but only to the view
-that, if a spiral form is to be produced, it is indifferent which way it
-turns. From the evolutionary point of view this conclusion is of some
-importance, since it indicates that one of the alternatives has been
-adopted and has become practically constant in most cases without
-selection having had anything to do with it.
-
-Somewhat similar conditions are found in the flounders and soles. As is
-well known, these fishes lie upon one side of the body on the bottom of
-the ocean. Some species, with the rarest exceptions to be mentioned in a
-moment, lie always on the right side, others on the left side. A few
-species are indifferently right or left. At rare intervals a left-sided
-form is found in a right-sided species, and conversely, a right-sided
-form in a left-sided species. In such cases the reversed type is as
-perfectly developed in all respects as the normal form, but with a
-complete reversal of its right and left sides.
-
-When the young flounders leave the egg, they swim in an upright
-position, as do ordinary fishes, with both sides equally developed.
-There cannot be any doubt that the ancestors of these fish were
-bilaterally symmetrical. Therefore, within the group, both right-handed
-and left-handed forms have appeared. It seems to me highly improbable
-that if a right-handed form had been slowly evolved through the
-selection of favorable variations in this direction, the end result
-could be suddenly reversed, and a perfect left-sided form appear.
-Moreover, as has been pointed out, the intermediate stages would have
-been at a great disadvantage as compared with the parent, and this would
-lead to their extermination on the selection theory. If, however, we
-suppose that a variation of this sort appeared at once, and was fixed,—a
-mutation in other words,—and that whether or not it had an advantage
-over the parent form, it could still continue to exist, and propagate
-its kind, then we avoid the chief difficulty of the selection theory.
-Moreover, we can imagine, at least, that if this variation appeared in
-the germ and was, in its essential nature, something like the relation
-seen in the snail, the occasional reversal of the relations of the parts
-presents no great difficulty.
-
-In this same connection may be mentioned a curious fact first discovered
-by Przibram and later confirmed by others. If the leg carrying the large
-claw of a crustacean be removed, then, at the next moult, the leg of the
-other side that had been the smaller first leg becomes the new big one;
-and the new leg that has regenerated from the place where the big one
-was cut off becomes the smaller one.
-
-Wilson has suggested that both claws in the young crustacean have the
-power to become either sort. We do not know what decides the matter in
-the adult, after the removal of one of the claws. Some slight difference
-may turn the balance one way or the other, so that the smaller claw
-grows into the larger one. At any rate, there is seen a latent power
-like that in the egg of the snail. Zeleny has found a similar relation
-to exist for the big and the little opercula of the marine worm,
-Hydroides.
-
-Let us consider now the more general questions involved in these
-symmetrical and asymmetrical relations between the organism and its
-environment. In what sense, it may be asked, is the symmetry of a form
-an adaptation to its environment? That the kind of symmetry gives to the
-animal in many cases a certain advantage in relation to its environment
-is so evident that I think it will not be questioned. The main question
-is how this relation is supposed to have been attained. Three points of
-view suggest themselves: First, that the form has resulted directly from
-the action of the environment upon the organism. This is the Lamarckian
-point of view, which we rejected as improbable. Second, that the form
-has been slowly acquired by selecting those individual variations that
-best suited it to a given set of surrounding conditions. This is the
-Darwinian view, which we also reject. The third, that the origin of the
-form has had nothing to do with the environment, but appeared
-independently of it. Having, however, appeared, it has been able to
-perpetuate itself under certain conditions.
-
-It should be pointed out that the Darwinian view does not suppose that
-the environment actually produces any of the new variations which it
-selects after they have appeared, but in so far as the environment
-selects individual differences it is supposed to determine the direction
-in which evolution takes place. On the theory that evolution has taken
-place independently of selection, this latter is not supposed to be the
-case; the finished products, so to speak, are offered to the
-environment; and if they pass muster, even ever so badly, they may
-continue to propagate themselves.
-
-The asymmetrical form of certain animals living in a symmetrical
-environment might be used as an argument to show that the relation of
-symmetry between an animal and its environment can easily be overstepped
-without danger. The enormous claw of the fiddler-crab must throw the
-animal out of all symmetrical relation with its environment, and yet the
-species flourishes. The snail carries around a spiral hump that is
-entirely out of symmetrical relation with the surroundings of a snail.
-
-These facts, few though they are, yet suffice to show, I believe, that
-the relation of symmetry between the organism and its environment may
-be, and is no doubt in many cases, more perfect than the requirements of
-the situation demand. The fact that animals made unsymmetrical through
-injuries (as when a crab loses several legs on one side, or a worm its
-head) can still remain in existence in their natural environment, is in
-favor of the view that I have just stated. By this I do not mean to
-maintain that a symmetrical form does not have, on the whole, an
-advantage over the same form rendered asymmetrical, but that this
-relation need not have in all forms a selective value, and if not, then
-it cannot be the outcome of a process of natural selection.
-
-To sum up: it appears probable that the laws determining the symmetry of
-a form are the outcome of internal factors, and are not the result
-either of the direct action of the environment, or of a selective
-process. The finished products and not the different imperfect stages in
-such a process, are what the inner organization offers to the
-environment. While the symmetry or asymmetry may be one of the numerous
-conditions which determine whether a form can persist or not, yet we
-find that the symmetrical relations may be in some cases more perfect
-than the environment actually demands; and in other cases, although the
-form may place the organism at a certain disadvantage, it may still be
-able to exist in certain localities.
-
-
-                  Mutual Adaptation of Colonial Forms
-
-In the white ants, true ants, and bees, we find certain individuals of
-the community specialized in such a way that their modifications stand
-in certain useful relations to other members of the community. Amongst
-the bees, the workers collect the food, make the comb, and look after
-the young. The queen does little more than lay eggs, and the drone’s
-only function is to fertilize the queen. In the true ants there are,
-besides the workers and the queen and the males, the soldier caste.
-These have large thick heads and large strong jaws. On the Darwinian
-theory it is assumed that this caste must have an important rôle to
-play, for otherwise their presence as a distinct group of forms cannot
-be accounted for; but I do not believe it is necessary to find an excuse
-for their existence in their supposed utility. From the point of view of
-the mutation theory, their real value may be very small, but so long as
-their actual presence is not entirely fatal to the community they may be
-endured.
-
-In regard to these forms, Sharp writes:[28] “The soldiers are not alike
-in any two species of Termitidæ, so far as we know, and it seems
-impossible to ascribe the differences that exist between the soldiers of
-different species of Termitidæ to special adaptations for the work they
-have to perform.” “On the whole, it would be more correct to say that
-the soldiers are very dissimilar in spite of their having to perform
-similar work, than to state that they are dissimilar in conformity with
-the different tasks they carry on.” The soldiers have the same instincts
-as the workers, and do the same kinds of things to a certain extent.
-“The soldiers are not such effective combatants as the workers are.”
-Statements such as these indicate very strongly that the origin of this
-caste can have very little to do with its importance as a specialized
-part of the community.
-
-Footnote 28:
-
-  “The Cambridge Natural History,” Vol. V, 1895.
-
-The differences between the castes have gone so far in some of these
-groups that the majority of the members of the community have even lost
-the power to reproduce their kind, and this function has devolved upon
-the queen, whose sole duty is to reproduce the different castes of which
-the community is composed. This specialization carries with it the idea
-of the individuals being adapted to each other, so that, taken all
-together, they form a whole, capable of maintaining and reproducing
-itself. It does not seem that we must necessarily look upon this union
-as the result of competition leading to a death struggle between
-different colonies, so that only those have survived in each generation
-that carried the work of specialization one step farther. All that is
-required is to suppose that such specialization has appeared in a group
-of forms living together, and the group has been able to perpetuate
-itself. We do not find that all other members of the two great groups to
-which the white ants and true ants belong have been crowded out because
-these colonial forms have been evolved. Neither need we suppose that
-during the evolution of these colonial species there has been a death
-struggle accompanying each stage in the evolution. If the members of a
-colonial group began to give rise to different forms through mutations,
-and if it happened that some of the combinations formed in this way were
-capable of living together, and perpetuating the group, this is all that
-is required for such a condition to persist.
-
-The relation of the parents to the offspring presents in some groups a
-somewhat parallel case to that of these colonial forms. Not only are
-some of the fundamental instincts of the parents changed, but structures
-may be present in the parents whose only use is in connection with the
-young. The marsupial pouch of the kangaroo, in which the immature young
-are carried and suckled, is a case in point, and the mammary glands of
-the Mammalia furnish another illustration.
-
-Adaptations of these kinds are clearly connected with the perpetuation
-of the race. In the case of the mammals the young are born so immature
-that they are dependent on the parental organs, just spoken of, for
-their existence. Could we follow this relation through its evolutionary
-stages, it would no doubt furnish us with important data, but
-unfortunately we can do no more than guess how this relation became
-established. The changes in the young and in the parent may have been
-intimately connected at each stage, or more or less independent. If we
-suppose the mammary glands to have appeared first, they might have been
-utilized by the young in order to procure food. Their presence would
-then make it possible for the young to be born in an immature condition,
-as is the case with the young of many of the mammals. But this is pure
-guessing, and until we know more of the actual process of evolution in
-this case, it is unprofitable to speculate.
-
-
-                              Degeneration
-
-In almost every group of the animal kingdom there are forms that are
-recognized as degenerate. This degeneration is usually associated with
-the habitat of the animal. In many cases it can be shown with much
-probability that these degenerate forms have descended from members of
-the group that are not degenerate. We find there is a loss of those
-organs that are not useful to the organism in its new environment. The
-degeneration may involve nearly the whole organization (except as a rule
-the reproductive system), as seen in the tapeworm, or only certain
-organs of the body, as the eyes in cave animals. A few examples will
-bring the main facts before us.
-
-A parasitic existence is nearly always associated with degeneration.
-Under these conditions, food can generally be obtained without
-difficulty, at the expense of the host, and apparently associated with
-this there is a degeneration, and even a complete loss of so important
-an organ as the digestive tract. Thus the tapeworm has lost all traces
-of its digestive tract, absorbing the already digested matter of its
-host through its body wall. Some of the roundworms, that live in the
-alimentary tracts of other animals, may have their digestive organs
-reduced. In Trichina, this degeneration has gone so far that the
-digestive tract is represented, in part, by a single line of endoderm
-cells, pierced by a cavity. The digestive organs are also absent in
-certain male rotifers, which are parasitic on the females, and these
-organs are also very degenerate in the male of _Bonellia_, a gephyrean
-worm. A parasitic snail, _Entoscolax ludwigii_, has its digestive
-apparatus reduced to a sucking tube ending in a blind sac. The rest of
-the tract has completely degenerated. The remarkable parasitic
-crustacean, _Sacculina carcini_, looks like a tumor attached to the
-under surface of the abdomen of a crab. It has neither mouth nor
-digestive tract, and absorbs nourishment from the crab through rootlike
-outgrowths that penetrate the body. From its development alone we know
-that it is a degenerate barnacle.
-
-There seems to be in all these cases an apparent connection between the
-absence of the digestive tract and the presence of an abundant supply of
-food, that has already been partly digested by the host. Put in a
-different way, we may say that the presence of this food has furnished
-the environment in which an animal may live that has a rudimentary
-digestive tract.
-
-An interesting case of degeneration is found in the rudimentary mouth
-parts of the insects known as May-flies, or ephemerids. Some of these
-species live in the adult condition for only a few hours, only long
-enough to unite and deposit their eggs. In the adult stage the insects
-do not take any food. In this case the degeneration is obviously not
-connected with the presence of food, but apparently with the shortness
-of the adult life.
-
-One of the most familiar cases of degeneration is blindness, associated
-with life in the dark. The most striking cases are those of cave
-animals, but this is only an extreme example of what is found everywhere
-amongst animals that live concealed during the day under stones, etc.
-The blind fish and the blind crayfish of the Mammoth Cave, the blind
-proteus of the caves of Carniola, the blind mole that burrows
-underground, the blind larvæ of many insects that live in the dark, are
-examples most often cited. Some nocturnal animals, like the earthworm,
-have no eyes, although they are still able to distinguish light; and
-some of the deep-sea animals, that live below the depth to which light
-penetrates, have degenerate eyes. The workers of some ants, that remain
-in the nests, are blind, but the males and the queens of these forms
-have well-developed eyes, although the eyes may be of use to them at
-only one short period of their life, namely, at the time of the marriage
-flight. This fact is significant and is underestimated by those who
-believe that disuse accounts for the degeneration of organs.
-
-The wings of the ostrich and of the kiwi are rudimentary structures no
-longer used for flight, and many insects, belonging to several different
-orders, have lost their wings, as seen in fleas, some kinds of bugs, and
-moths, and even in some grasshoppers.
-
-A curious case of degeneration is found in the abdomen of the hermit
-crab, which is protected by the appropriated shell of a snail. The
-appendages of one side of the abdomen have nearly disappeared in the
-male, although in the female the abdominal appendages are used to carry
-the eggs as in other decapod crustaceans. The abdomen, instead of being
-covered by a hard cuticle, as in other members of this group, is soft
-and unprotected except by the shell of the snail.
-
-Cases of these kinds could be added to almost indefinitely, and the
-explanation of these degenerate structures has been a source of
-contention amongst zoologists for a long time. The most obvious
-interpretation is that the degeneration has been the result of disuse.
-But as I have already discussed this question, and given my reasons for
-regarding it as improbable that degeneration has arisen in this way, we
-need not further consider this point here.
-
-The selectionists have offered several suggestions to account for
-degeneration. In fact, this has been one of the difficulties that has
-given them most concern. They have suggested, for example, that when an
-organ is no longer of use to its possessor it would become a source of
-danger, and hence would be removed through natural selection. They have
-also suggested that since such organs draw on the general food supply
-they would place their possessor at a disadvantage, and hence would be
-removed. Weismann has attempted to meet the difficulty by his theory of
-“Panmixia,” or universal crossing, by which means the useless structures
-are imagined to be eliminated.
-
-These attempts will suffice to point out the straits to which the
-Darwinians have found themselves reduced, and we have by no means
-exhausted the list of suggestions that have been made. Let us see, if,
-on any other view, we can avoid some of the difficulties that the
-selection theory has encountered.
-
-In the first place we shall be justified, I think, in eliminating
-competition as a factor in the process, since the admission that an
-organ has become useless carries with it the idea that it has no longer
-a selective value. If, in its useless condition, it is no longer greatly
-injurious, as is probably, though not necessarily always, the case, then
-selection cannot enter into the problem. If in parasitism we assume that
-an animal finds a lodgement in another animal, where it is able to
-exist, we may have the first stage of the process introduced at once. If
-under these conditions a mutation appeared, involving some of the organs
-that are no longer essential to the life of the individual in its new
-environment, the new mutation may persist. We need not suppose that the
-original form becomes crowded out, but only that a more degenerate form
-has come into existence. As a matter of fact we find in most groups, in
-which degenerate forms exist, a number of different stages in the
-degeneration in different species. Mutation after mutation might follow
-until many of the original organs have disappeared. The connection that
-appears to exist between the degeneration of a special part and the
-environment in which the animal lives finds its explanation simply in
-the fact that the environment makes possible the existence of that sort
-of mutation in it. We do not know, as yet, whether through mutative
-changes an organ can completely disappear, although this seems probable
-from the fact that in a few cases mutations are known to have arisen in
-which a given part is entirely functionless. If we could assume that, a
-mutation in the direction of degeneration being once established,
-further mutations in the same direction would probably occur, the
-problem would be much simplified; but we lack data, at present, to
-establish this view.
-
-In the case of blind animals it seems probable that the transition has
-taken place in such forms as had already established themselves in
-places more or less removed from the light. Such forms as had the habit
-of hiding away under stones, or in the ground, living partly in and
-partly out of the light, might, if a mutation appeared of such a sort
-that amongst other changes the eyes were less developed, still be
-capable of leading an existence in the dark, while it might be
-impossible for them to exist any longer with weakened vision in the
-light. If such a process took place, the habitat of the new form would
-be limited, or in other words it would be confined to the locality to
-which it finds itself adapted; not that it has become adapted to the
-environment through competition with the original species, or, in fact,
-with any other.
-
-Thus, from the point of view that is here taken, an animal does not
-become degenerate because it becomes parasitic, but the environment
-being given, some forms have found their way there; in fact, we may
-almost say, have been forced there, for these degenerate forms can only
-exist under such conditions.
-
-In conclusion, this much at least can be claimed for the mutation
-theory; that it meets with no serious difficulty in connection with the
-phenomena of degeneration. It meets with no difficulty, because it makes
-no pretence to explain the origin of adaptations, but can account for
-the occurrence of degenerate forms, if it is admitted that these appear
-as mutations, or as definite variations. Let us, however, not close our
-eyes to the fact that there is still much to be explained in respect to
-the degeneration of animals and plants. It is far from my purpose to
-apply the mutation theory to all adaptations; in fact, it will not be
-difficult to show that there are many adaptations whose existence can
-have nothing directly to do with the mutation theory.
-
-
-                         Protective Coloration
-
-That many species of animals are protected by their resemblance to their
-environment no one will probably deny. That we are ignorant in all cases
-as to how far this protection is necessary for the maintenance of the
-species must be admitted. That some of the resemblances that have been
-pointed out have been given fictitious value, I believe very probable.
-
-Resemblance in color between the organism and its environment has given
-to the modern selectionist some of his most valuable arguments, but we
-should be on our guard against supposing that, because an animal may be
-protected by its color, the color has been acquired on this account. On
-the supposition that the animal has become adapted by degrees, and
-through selection, we meet with all the objections that have been urged,
-in general, against the theory of natural selection. But if we assume
-here also that mutations have occurred without relation to the
-environment, and, having once appeared, determined in some cases the
-distribution of the species, we have at least a simple hypothesis that
-appears to explain the facts. If it be claimed that the resemblance is,
-in some cases, too close for us to suppose that it has arisen
-independently of the environment, it may be pointed out that it has not
-been shown that such a close resemblance is at all necessary for the
-continued existence of the species, and hence the argument is likely to
-prove too much. For instance, the most remarkable case of resemblance is
-that of Kallima, but in the light of a recent statement by Dean it may
-be seriously asked whether there is absolute need of such a close
-resemblance to a leaf. Even if it be admitted that to a certain extent
-the butterfly is at times protected by its resemblance to a leaf, it is
-not improbable that it could exist almost equally well without such a
-close resemblance. If this is true, natural selection could never have
-brought about such a close imitation of a leaf. Cases like these of
-over-adaptation are not unaccountable on the theory of mutation, for on
-this view the adaptation may be far ahead of what the actual
-requirements for protection demand. We meet occasionally, I think,
-throughout the living world with resemblances that can have no such
-interpretation, and a number of the kinds of adaptations to be described
-in this chapter show the same relation.
-
-Some of the cases of mimicry appear also to fall under this head;
-although I do not doubt that many so-called cases of mimicry are purely
-imaginary, in the sense that the resemblance has not been acquired on
-account of its relation to the animal imitated. There is no need to
-question that in some cases animals may be protected by their
-resemblance to other animals, but it does not follow, despite the
-vigorous assertions of some modern Darwinians, that this imitation has
-been the result of selection. Until it can be shown that the imitating
-species is dependent on its close imitation for its existence, the
-evidence is unconvincing; and even if, in some cases, this should prove
-to be the case, it does not follow that natural selection has brought
-about the result, or even that it is the most plausible explanation that
-we have to account for the results. The mutation theory gives, in such
-cases, an equally good explanation, and at the same time avoids some of
-the difficulties that appear fatal to the selection theory.
-
-What has been said against the theory of mimicry might be repeated in
-much stronger terms against the hypothesis of warning colors.
-
-It seems to me, in this connection, that the imagination of the
-selectionist has sometimes been allowed to “run wild”; and while it may
-be true that in some cases the colors may serve as a signal to the
-possible enemies of the animal, it seems strange that it has been
-thought necessary to explain the origin of such colors as the result of
-natural selection. Indeed, some of these warning colors appear
-unnecessarily conspicuous for the purpose they have to perform. In other
-words, it does not seem plausible that an animal already protected
-should need to be so conspicuous. If we stop for a moment to consider
-what an enormous amount of destruction must have occurred, according to
-Darwin’s theory, in order to bring this warning coloration to its
-supposed state of perfection, we may well hesitate before committing
-ourselves to such an extreme view.
-
-That gaudy colors have appeared or been present in animals that are
-protected in other ways is not improbable, when we consider the rôle
-that color plays everywhere in nature. That the presence of such colors
-may, to a certain limited extent, protect its possessor may be admitted
-without in any degree supposing that natural selection has directed the
-evolution of such color, or that it has been acquired through a life and
-death struggle of the individuals of the species.
-
-
-                 Sexual Dimorphism[29] and Trimorphism
-
-Footnote 29:
-
-  This term is used here in the sense employed by Darwin. The same term
-  is sometimes used for those cases in which the male departs very
-  greatly from the female in form.
-
-It has been found in a few species of animals and plants that two or
-more forms of one sex may exist, and here we find a condition that
-appears to be far more readily explained on the mutation theory than on
-any other. The most important cases, perhaps, are those in plants, but
-there are also similar cases known amongst animals, and these will be
-given first.
-
-There is a North American butterfly, _Papilio turnus_, that appears
-under at least two forms. In the eastern United States the male has
-yellow wings with black stripes. There are two kinds of females, one of
-which resembles the male except that she has also an orange “eye-spot”;
-the other female is much blacker, and this variety is found particularly
-in the south and west. The species is dimorphic, therefore, mainly in
-the latter regions.
-
-The cases of seasonal dimorphism offer somewhat similar illustrations.
-The European butterfly, _Vanessa levana-prorsa_, has a spring generation
-(_levana_) with a yellow and black pattern on the upper surface of the
-wings. The summer generation (_prorsa_) has black wings “with a broad
-white transverse band, and delicate yellow lines running parallel to the
-margins.” These two types are sharply separated, and their differences
-in color do not appear to be associated with any special protection that
-it confers on the bearer. These facts in regard to Vanessa seem to
-indicate that differences may arise that are perfectly well marked and
-sharply defined, which yet appear to be without any useful significance.
-
-We meet with cases in which the same animal has at different times of
-year different colors, as seen in the summer and winter plumage of the
-ptarmigan. There is no direct evidence to show how this seasonable
-change has been brought about; but from the facts in regard to Vanessa
-we can see that it might have been at least possible for the white
-winter plumage, for instance, to have appeared without respect to any
-advantage it conferred on the animal, but after it had appeared it may
-have been to a certain degree useful to its possessor.
-
-
-[Illustration:
-
-  Fig. 5.—A, long-styled, and
-  B, short-styled, forms of _Primula veris_.
-  C, D, E, the three forms of the trimorphic flower of _Lythrum
-    salicaria_, with petals and calyx removed on near side. (After
-    Darwin.)]
-
-Amongst plants there are some very interesting cases of dimorphism and
-trimorphism in the structure of the flowers. Darwin has studied some of
-these cases with great care, and has made out some important points in
-regard to their powers of cross-fertilization.[30] The common European
-cowslip, _Primula veris_, var. _officinalis_, is found under two forms,
-Figure 5 A and B, which are about equally abundant. In one the style is
-long so that the stigma borne on its end comes to the top of the tube of
-the corolla. The stamens in this form stand about halfway up the tube.
-This is called the long-styled form. The other kind, known as the
-short-styled form, has a style only half as long as the tube of the
-corolla, and the stamens are attached around the upper end of the tube
-near its opening. In other words, the position of the end of the style
-(the stigma) and that of the stamens is exactly reversed in the two
-forms. The corolla is also somewhat differently shaped in the two forms,
-and the expanded part of the tube above the stamens is larger in the
-long-styled than in the short-styled form. Another difference is found
-in the stigma, which is globular in the long-styled, and depressed on
-its top in the short-styled, form. The papillæ on the former are twice
-as long as those on the short-styled form. The most important difference
-is found in the size of the pollen grains. These are larger in the
-long-styled form, being in the two cases in the proportion of 100 to 67.
-The shape of the grains is also different. Furthermore, the long-styled
-form tends to flower before the other kind, but the short-styled form
-produces more seeds. The ovules in the long-styled form, even when
-unfertilized, are considerably larger than those of the short-styled,
-and this, Darwin suggests, may be connected with the fact that fewer
-seeds are produced, since there is less room for them. The important
-point for our present consideration is that intermediate forms do not
-exist, although there are fluctuating variations about the two types.
-Moreover, the two kinds of flowers never appear on the same plant.
-
-Darwin tried the effect of fertilizing the long-styled flowers with the
-pollen from the same flower or from other long-styled flowers. Unions of
-this sort he calls illegitimate, for reasons that will appear later. He
-also fertilized the long-styled flowers with pollen from short-styled
-forms. A union of this sort is called legitimate. Conversely, the
-short-styled forms were fertilized with their own pollen or with that
-from another short-styled form. This is also an illegitimate union.
-Short-styled forms fertilized with pollen from long-styled forms give
-again legitimate unions.
-
-Footnote 30:
-
-  Many of the facts as to the occurrence of these cases were known
-  before Darwin worked on them; but very little had been ascertained in
-  regard to the sexual relation between the dimorphic and trimorphic
-  forms, and it was here that Darwin obtained his most interesting
-  results.
-
-The outcome of these different crossings are most curious. In the table,
-page 364, the results of the four combinations are given. It will be
-seen at once that the legitimate unions give more capsules, and the
-seeds weigh more, than in the illegitimate unions.
-
-The behavior of the offspring from seeds of legitimate and
-illegitimate origin is even more astonishing. Darwin found in _Primula
-veris_ (the form just described) that the seeds from the short-styled
-form fertilized with pollen from the same form germinated so badly
-that he obtained only 14 plants, of which 9 were short-styled and 5
-long-styled. The long-styled form fertilized with its own-styled
-pollen produced “in the first generation 3 long-styled plants. From
-their seed 53 long-styled grandchildren were produced; from their seed
-4 long-styled great-grandchildren; from their seed 20 long-styled
-great-great-grandchildren; and lastly, from their seed 8 long-styled
-and 2 short-styled great-great-great-grandchildren.”
-
-
-    ══════════════╤═════════╤═════════╤═════════╤═════════╤═════════
-                  │Number of│         │ Maximum │ Minimum │ Average
-      Nature of   │ Flowers │Number of│of Seeds │of Seeds │ No. of
-        Union     │Fertilized│  Seed   │ in any  │ in any  │Seeds per
-                  │         │Capsules │   one   │   one   │ Capsule
-                  │         │         │ Capsule │ Capsule │
-    ──────────────┼─────────┼─────────┼─────────┼─────────┼─────────
-    Long-styled   │   10    │    6    │   62    │   34    │  46.5
-      form by     │         │         │         │         │
-      pollen of   │         │         │         │         │
-      short-styled│         │         │         │         │
-      form:       │         │         │         │         │
-      Legitimate  │         │         │         │         │
-      union.      │         │         │         │         │
-    ──────────────┼─────────┼─────────┼─────────┼─────────┼─────────
-    Long-styled   │   20    │    4    │   49    │    2    │  27.7
-      form by     │         │         │         │         │
-      own-form    │         │         │         │         │
-      pollen:     │         │         │         │         │
-      Illegitimate│         │         │         │         │
-      union.      │         │         │         │         │
-    ──────────────┼─────────┼─────────┼─────────┼─────────┼─────────
-    Short-styled  │   10    │    8    │   61    │   37    │  47.7
-      form by     │         │         │         │         │
-      pollen of   │         │         │         │         │
-      long-styled │         │         │         │         │
-      form:       │         │         │         │         │
-      Legitimate  │         │         │         │         │
-      union.      │         │         │         │         │
-    ──────────────┼─────────┼─────────┼─────────┼─────────┼─────────
-    Short-styled  │   17    │    3    │   19    │    6    │  12.1
-      form by     │         │         │         │         │
-      own-form    │         │         │         │         │
-      pollen:     │         │         │         │         │
-      Illegitimate│         │         │         │         │
-      union.      │         │         │         │         │
-    ──────────────┼─────────┼─────────┼─────────┼─────────┼─────────
-    The two       │   20    │   14    │   62    │   37    │  47.1
-      legitimate  │         │         │         │         │
-      unions      │         │         │         │         │
-      together.   │         │         │         │         │
-    ──────────────┼─────────┼─────────┼─────────┼─────────┼─────────
-    The two       │   30    │    7    │   49    │    2    │  35.5
-      illegitimate│         │         │         │         │
-      unions      │         │         │         │         │
-      together.   │         │         │         │         │
-    ══════════════╧═════════╧═════════╧═════════╧═════════╧═════════
-
-
-From other long-styled plants, fertilized with their own-form pollen, 72
-plants were raised, which were made up of 68 long-styled and 4
-short-styled. In all, 162 illegitimate unions of this sort produced 156
-long-styled and 6 short-styled plants. It is evident from these results
-that the long-form pistils, fertilized with pollen from flowers of the
-same pistil-form (from other individuals as a rule), tend to produce the
-same form as their parents, although occasionally the other form. The
-fertility of these plants from an illegitimate union is found to be very
-low. Darwin observed that sometimes the male and female organs of these
-plants were in a very deteriorated condition. It is interesting to
-notice, in this connection, that in another species, _Primula sinensis_,
-illegitimate plants from long-styled parents were vigorous, but the
-flowers were small and more like the wild form. They were, however,
-perfectly fertile.
-
-Illegitimate plants from short-styled parents were dwarfed in stature,
-and often had a weakly constitution. They were not very fertile _inter
-se_, and remarkably infertile when legitimately fertilized. This kind of
-result, where a difference in the power of mutual intercrossing exists
-between two forms, recalls in many ways the difference in the results of
-crossing of different species of animals and plants, especially those
-cases in which a cross can be made in one way more successfully than in
-the other.
-
-The heterostyled trimorphic plants, of which _Lythrum salicaria_, Figure
-5 C, D, E, may be taken as an example, are even more remarkable. There
-are three different kinds of flowers: in one the pistil is long and
-there is a medium and a short set of stamens; in another the pistil is
-of intermediate length and there is a long set and a short set of
-stamens; in the third kind the pistil is short, and there is a medium
-and a long set of stamens. There are possible only six sorts of
-legitimate unions between these three sets of flowers. No less than
-twelve kinds of illegitimate unions may occur. In regard to the
-difference in the sizes of the pollen grains, those from the long-styled
-form are the largest, from the mid-styled form next, and from the
-short-styled form the smallest. The extreme difference is as 100 to 60.
-“Nothing shows more clearly the extraordinary complexity of the
-reproductive system of this plant than the necessity of making eighteen
-distinct unions in order to ascertain the relative fertilizing power of
-the three forms.” Darwin tried the effect of each of these combinations,
-making 223 unions in all. The results are surprising. Comparing the
-outcome of the six legitimate unions with the twelve illegitimate ones,
-the following results were obtained:—
-
-
-      ═══════════════╤══════════╤══════════╤══════════╤══════════
-                     │Number of │          │          │ Average
-                     │ Flowers  │Number of │ Average  │  No. of
-      Nature of Union│Fertilized│ Capsules │  No. of  │Seeds per
-                     │          │ Produced │Seeds per │  Flower
-                     │          │          │ Capsule  │Fertilized
-      ───────────────┼──────────┼──────────┼──────────┼──────────
-      The 6          │    75    │    56    │  96.29   │  71.89
-      legitimate     │          │          │          │
-      unions         │          │          │          │
-      ───────────────┼──────────┼──────────┼──────────┼──────────
-      The 12         │   146    │    36    │  44.72   │  11.03
-      illegitimate   │          │          │          │
-      unions         │          │          │          │
-      ═══════════════╧══════════╧══════════╧══════════╧══════════
-
-
-This table shows that the fertility of the legitimate to that of the
-illegitimate is as 100 to 33, as judged by the flowers that produced
-capsules; and as 100 to 46 as judged by the average number of seeds per
-capsule. It is evident, therefore, that “it is only the pollen from the
-longest stamens that can fully fertilize the longest pistil; only that
-from the mid-length stamens, the mid-length pistil; and only that from
-the shortest stamens, the shortest pistil.”
-
-Darwin tries to connect this fact with the visits of insects to the
-flowers. He says: “And now we can comprehend the meaning of the almost
-exact correspondence in length between the pistil in each form and of a
-set of six stamens in two of the other forms; for the stigma of each
-form is thus rubbed against that part of the insect’s body which becomes
-charged with the proper pollen.” A further conclusion that Darwin draws
-is “that the greater the inequality in length between the pistil and the
-set of stamens, the pollen of which is employed for its fertilization,
-by so much is the sterility the more increased.” Darwin also makes the
-following significant comment on the problem here involved: “The
-correspondence in length between the pistil in each form, and a set of
-stamens in the other two forms, is probably the direct result of
-adaptation, as it is of the highest service to the species by leading to
-full and legitimate fertilization.” He points out, on the other hand,
-that the increased sterility of the illegitimate unions, in proportion
-to the inequality in length between the pistil and the stamens employed,
-can be of no service at all. Neither can this relation have any
-connection with the facility for self-fertilization. “We are led,
-therefore, to conclude that the rule of increased sterility in
-accordance with increased inequality in length between the pistils and
-stamens is a purposeless result, incidental on those changes through
-which the species has passed in acquiring certain characters fitted to
-insure the legitimate fertilization of the three flowers.”
-
-In regard to the plants that were raised from the seeds from legitimate
-and illegitimate unions, Darwin found in Lythrum that of twelve
-illegitimate unions two were completely barren, and nearly all showed
-lessened fertility; only one approached complete fertility. Darwin lays
-much emphasis on the close resemblance in the sterility of the
-illegitimate unions, and the sterility of different species when
-crossed. In both cases every degree of sterility is met with, “from very
-slightly lessened fertility to absolute barrenness.” The importance of
-this comparison cannot, I think, be overestimated, for, if admitted, it
-indicates clearly that the infertility between species cannot be used as
-a criterion of their distinctness, because here, in individuals
-belonging to the same species, we find sterility between pistils and
-stamens of different lengths. If, as I shall urge below, we must
-consider these different forms of Primula the results of a mutation, and
-not the outcome of selection as Darwin supposed, then this relation in
-regard to infertility becomes a point of great interest.
-
-This brings us to the central point of our examination of these cases of
-dimorphism and trimorphism. How have these forms arisen? Darwin tries to
-account for them as follows: Since heterostyled plants occur in fourteen
-different families of plants, it is probable that this condition has
-been acquired independently in each family, and “that it can be acquired
-without any great difficulty.” The first step in the process he imagines
-to have been due to great variability in the length of the pistil and
-stamens, or of the pistil alone. Flowers in which there is a great deal
-of variation of this sort are known. “As most plants are occasionally
-cross-fertilized by the aid of insects, we may assume that this was the
-case with our supposed varying plant; but that it would have been
-beneficial to it to have been more regularly cross-fertilized.” “This
-would have been better accomplished if the stigma and the stamens stood
-at the same level; but as the stamens and pistil are supposed to have
-varied much in length, and to be still varying, it might well happen
-that they could be reduced much more easily through natural selection
-into two sets of different lengths in different individuals than all to
-the same length and level in all individuals.” By means of these
-assumptions, improbable as they may appear, Darwin tries to explain
-these cases of dimorphism. But when we attempt to apply the same
-argument to the trimorphic forms, it is manifestly absurd to pretend
-that three such sharply defined types could ever have been formed as the
-result of natural selection. But we have not even yet touched the chief
-difficulty, as Darwin himself points out. “The essential character of a
-heterostyled plant is that an individual of one form cannot fully
-fertilize, or be fertilized by, an individual of the same form, but only
-by one belonging to another form.” This result Darwin admits cannot be
-explained by the selection theory, for, as he says, “How can it be any
-advantage to a plant to be sterile with half of its brethren, that is,
-with the individuals belonging to the same form?” He concludes that this
-sterility between the individuals of the same form is an incidental and
-purposeless result. “Inner constitutional differences” between the
-individuals is the only suggestion that is offered to account for the
-phenomenon. In other words, it is clearly apparent that the attempt to
-apply the theory of selection has here broken down, and it is a
-fortunate circumstance that the Lamarckian theory cannot here be brought
-to the rescue, as it so often is in Darwin’s writings, when the theory
-of natural selection fails to give a sufficient explanation.
-
-On the other hand, this is one of the cases that seem to fit in
-excellently with the mutation theory, for if these two forms of the
-primrose should appear, as mutations, and if, as is the case, they do
-not blend when crossed, but are equally inherited, they would both
-continue to exist as we find them to-day. Whether the similar forms were
-infertile with each other would be determined at the outset by the
-nature of the individual variation, and if, despite this obvious
-disadvantage, the forms could still continue to propagate themselves,
-the new dimorphic form would remain in existence. Darwin cannot explain
-the origin of dimorphic forms and trimorphic forms unless he can show
-that there is some advantage in having two forms, and as we have seen,
-he fails completely to show that there is an advantage. On the other
-hand, the result might have been reached on the mutation theory, even if
-the dimorphic and trimorphic forms were placed at a greater disadvantage
-than were the parent forms. In such a case fewer individuals might
-appear, or find a foothold; but as long as the race could be kept up the
-new forms would remain in existence. Thus, while no attempt is made to
-explain what has always been, and may possibly long remain, inexplicable
-to us, namely, the origin of the new form itself, yet granting that such
-new forms may sometimes appear spontaneously, they may be able to
-establish themselves, regardless of whether they are a little more or a
-little less well adapted to the environment than were their parent
-forms. If it should appear that the question is begged by the assumption
-that mutations such as these may appear (at one step or by a series of
-steps is immaterial), it should not be forgotten that the whole
-Darwinian theory itself also rests on the spontaneous appearance of
-fluctuating variations, whose origin it does not pretend to explain. In
-this respect both theories are on the same footing, but where the
-Darwinian theory meets with difficulties at every turn by assuming that
-new forms are built up through the action of selection, the mutation
-theory escapes most of these difficulties, because it applies no such
-rigid test as that of selection to account for the presence of new
-forms.
-
-
-                    Length of Life as an Adaptation
-
-It has been pointed out in the first chapter that the length of life of
-the individual has been supposed by some of the most enthusiastic
-followers of Darwin to be determined by the relation of the individual
-to the species as a whole. In other words, the doctrine of utility has
-been applied here also, on the ground that it would be detrimental to
-the species to have part of the individuals live on to a time when they
-can no longer propagate the race or protect the young. It is assumed
-that those varieties or groups of individuals (unfortunately not sharply
-defined) would have the best chance to survive in which the parent forms
-died as soon as they had lost the power to produce new individuals.
-Sometimes interwoven with this idea there is another, namely, that
-_death itself_ has been acquired because it was more profitable to
-supplant the old and the injured individuals by new ones, than to have
-the old forms survive, and thus deprive the reproducing individuals of
-some of the common food supply.
-
-This insidious form that the selection theory has taken in the hands of
-its would-be advocates only serves to show to what extremes its
-disciples are willing to push it. On the whole it would be folly to
-pursue such a will-o’-the-wisp, when the theory can be examined in much
-more tangible examples. If in these cases it can be shown to be
-improbable, the remaining superstructure of quasi-mystical hypothesis
-will fall without more ado.
-
-That the problem of the length of life may be a real one for
-physiological investigation will be granted, no doubt, without
-discussion, and that in some cases the length of life and the coming to
-maturity of the germ-cell may be, in some way, physiologically connected
-seems not improbable; but that this relation has been regulated by the
-competition of species with each other can scarcely be seriously
-maintained. I will not pretend to say whether the mutation theory can or
-cannot be made to appear to give the semblance of an explanation of the
-length of life in each species, but it seems to me fairly certain that
-this is one of the questions which we are not yet in a position to
-attempt to consider on any theory of evolution.
-
-
-                      Organs of Extreme Perfection
-
-It has often been pointed out that certain organs may be more perfectly
-developed than the requirements of the surroundings strictly demand. At
-least we have no good reasons to suppose in some cases that constant
-selection is keeping certain organs at the highest possible point of
-development, yet, on the Darwinian theory, as soon as selection ceases
-to be operative the level of perfection must sink to that which the
-exigencies of the situation demand. The problem may be expressed in a
-different way. Does the animal or plant ever possess organs that are
-more perfectly adapted than the absolute requirements demand? If such
-organs are the result of fluctuating variations, they will be unable to
-maintain themselves in subsequent generations without a constant process
-of selection going on. If, on the other hand, the organs have arisen as
-mutations, they may become permanently established without respect to
-the degree of perfection of their adaptation. We can see, therefore,
-that cases of extreme perfection meet with no difficulty on the mutation
-theory, while they have proven one of the stumbling-blocks to the
-selection theory.
-
-There are, in fact, many structures in the animal and plant kingdoms
-that appear to be more perfect than the requirements seem to demand. The
-exact symmetry of many forms appears in some cases to be unnecessarily
-perfect. The perfection of the hand of man, the development of his vocal
-organs, and certain qualities of his brain, as his musical and
-mathematical powers, seem to go beyond the required limits. It is not,
-of course, that these things may not be of some use, but that their
-development appears to have gone beyond what selection requires of these
-parts.
-
-Closely related to this group of phenomena are those cases in which
-certain organs are well developed, but which can scarcely be of use to
-the animal in proportion to their elaboration. The electric organs of
-several fishes and skates are excellent examples of this sort of
-structures. The phosphorescent organs do not appear, in some forms at
-least, to be useful in proportion to their development. The selection
-theory fails completely to explain the building up of organs of this
-kind, but on the mutation theory there is no difficulty at all in
-accounting for the presence of even highly developed organs that are of
-little or of no use to the individual. If the organs appeared in the
-first place as mutations, and their presence was not injurious to the
-extent of interfering seriously with the existence and propagation of
-the new form, this new form may remain in existence, and if the
-mutations continued in the same direction, the organs might become more
-perfect, and highly developed. The whole class of secondary sexual
-organs may belong to this category, but a discussion of these organs
-will be deferred to the following section.
-
-
-                 Secondary Sexual Organs as Adaptations
-
-In the sixth chapter we have examined at some length Darwin’s
-interpretation of the secondary sexual characters. His explanation has
-been found insufficient in many cases to account for the conditions.
-That these organs do play in some cases a role in the relation of the
-sexes to each other may be freely admitted. In other words, in some
-animals the organs in one sex appear in the light of adaptations to
-certain instincts in the other sex. It would, perhaps, appear to
-simplify the problem to deny outright that any such relation exists; but
-I think, in the light of the evidence that we have, this procedure would
-be like that of the proverbial ostrich, which is supposed to stick its
-head in the sand in order to escape an anticipated danger. If we assumed
-this agnostic position, we might attempt to account for the appearance
-of secondary sexual organs as mutations that had appeared in one sex,
-and had no immediate connection with the other sex; and, so long as
-these organs were not directly and seriously injurious, we might assume
-that the animals in which such structures had appeared might be able to
-exist. But, on the other hand, I think that an examination of the
-evidence will show that this way out of the difficulty is not very
-satisfactory, for the organs in question appear, in some cases at least,
-to be closely connected with certain definite responses in the other
-sex. Moreover, as Darwin has so insistently pointed out, the action of
-the males is of such a sort that it is evidently associated with the
-presence of the secondary sexual organs which they often display before
-the other sex. Furthermore, the greater and often exclusive development
-of these organs during the sexual period distinctly points to them as in
-some way connected with the relation of the sexes to each other. And
-finally, there is a small, although not entirely convincing, body of
-evidence, indicating that the female is influenced by the action of the
-male; but I do not think that this evidence shows that she selects one
-individual at the expense of all other rivals. We meet here with a
-problem that is as profoundly interesting as it is obscure. In fact, if
-we admit that this relation exists we have a double set of conditions to
-deal with: first, the development in the males of certain secondary
-sexual organs; and secondly, the instinct to display these organs. The
-supposed influence of the display on the female may also have to be
-taken into account, although, for all we know to the contrary, the same
-results might follow were there no secondary sexual character at all, as
-is, in fact, the case in most animals.
-
-I have a strong suspicion that much that has been written on this
-subject is imaginative, and in large part fictitious; so that it may,
-after all, be the wisest course not to attempt to explain how this
-relation has arisen until we have a more definite conception of what we
-are really called upon to explain. For example, when we see a gorgeously
-bedecked male displaying himself before a female, we feel that his
-finery must have been acquired for this very purpose. On the other hand,
-when we see an unornamented male also making definite movements before
-the female, we do not feel called upon to explain the origin of his
-colors. Now, it is not improbable that the ornaments of the first
-individual have not been acquired in order to display them before the
-female, and this view seems to me the more probable. From this
-standpoint our problem is at least much simplified. What we need to
-account for is only that the male is excited to undergo certain
-movements in the presence of the female, and possibly that the female
-may be influenced by the result. That this view is the more profitable
-is indicated by the occurrence of secondary sexual characters in the
-lower forms, as in the insects and crustaceans, in which it appears
-almost inconceivable that the ornamentation could have been acquired in
-connection with the æsthetic taste of the other sex. It does not seem to
-me that the conditions in the higher animals call for any other
-explanation than that which applies to these lower forms.
-
-My position may be summed up in the statement, that, while in some cases
-there appears to be a connection between the presence in one sex of
-secondary sexual organs and their effect on the other sex, yet their
-origin cannot be explained on account of this connection.
-
-
-                 Individual Adjustments as Adaptations
-
-As pointed out in the first chapter, there is a group of adaptations,
-obviously including several quite different kinds of phenomena, that can
-at least be conveniently brought together under the general rubric of
-individual adjustments or regulations. A few examples of these will
-serve to show in what sense they may be looked upon as adaptations, and
-how they may be regarded from the evolutionary point of view.
-
-
-                Color Changes as Individual Adaptations
-
-The change in color of certain fish in response to the color of the
-background, the change in color of some chrysalides also in response to
-their surroundings, appears to be of some use to the animals in
-protecting them from their enemies. The change in color from green to
-brown and from brown back to green in several lizards and in some tree
-frogs is popularly supposed to be in response to the color of the
-surroundings, but a more searching examination has shown that, in some
-cases at least, the response has nothing to do with the color of the
-background.
-
-In the first cases mentioned above, in which the response appears to be
-of some advantage to the animal, the question may be asked, how have
-such responses arisen? The selection theory assumes that those animals
-that responded at first to a slight degree in a favorable direction have
-escaped, and this process being repeated, the power to change has been
-gradually built up. The mutation theory will also account for the result
-by assuming the response to have appeared as a new quality, but it has
-been preserved, not because it has been of vital importance to its
-possessor, but simply because the species possessing it has been able to
-survive, perhaps in some cases even more easily, although this is not
-essential. Even if the change were of no direct benefit, or even
-injurious to a slight degree, it might have been retained, as appears in
-fact to be the case in the change of color of the green lizards.
-
-
-       Increase of Organs through Use and Decrease through Disuse
-
-We meet here with one of the most characteristic and unique features of
-living things as contrasted with non-living things. We shall have to
-dismiss at once the idea that we can explain this attribute of organisms
-by either the selection or the mutation theory; for we find animals
-possessing this power that could never be supposed to have acquired it
-by any experience to which they have been subjected; and since it
-appears to be so universally present, we cannot account for it as a
-chance mutation that may have appeared in each species. No doubt Wolff
-had responses of this kind in view when he made the rather sweeping
-statement that purposeful adaptation is the most characteristic feature
-of living things. The statement appears to contain a large amount of
-truth, if confined to the present group of phenomena.
-
-This power of self-regulation may confer a great benefit on its
-possessor. The increase in the size and strength of the muscles through
-use may give the animal just those qualities that make its existence
-easier. The increase in the power of vision, or at least of visual
-discrimination through use, of the power of smell and of taste, of
-hearing and of touch, are familiar examples of this phenomenon.
-
-However much we may be tempted to speculate as to how this property of
-the animal may have been acquired, we lack the evidence which would
-justify us in formulating even a working hypothesis. It may be that when
-we come to know more of what the process of contraction of the muscle
-involves, the possibility of its development as a consequence of its use
-may be found to be a very simple phenomenon that requires no special
-explanation at all to account for its existence in the individual,
-further than that the muscles are of such a kind that this is a
-necessary physical result of their action. But until we know more of the
-physiology involved in the process, it is idle to speculate about the
-origin of the phenomenon.
-
-
-               Reactions of the Organism to Poisons, etc.
-
-In this case also we meet with a number of responses for whose origin we
-can give not the shadow of an explanation. On the other hand, the cases
-are significant in so far as a number of them show quite clearly that
-the response cannot have been acquired through the experience of the
-organism, or the selection of those individuals that have best resisted
-the particular poison. This is true, because in a number of cases the
-poison is a substance that the animal cannot possibly have met with
-during the ordinary course of its life, or of that of its ancestors. It
-may be argued, it is true, that in the case of the poisons produced by
-certain bacteria the power of resistance has been acquired through the
-survival of the less susceptible, or more resistant, individuals.
-Improbable as this may be in some cases, it does not, even if it were
-true, alter the real issue, for it can be shown, as has just been said,
-that the same power of responding adaptively is sometimes shown in cases
-of poisons that are new to the animal.
-
-There is no question that different individuals respond in very
-different degrees to these poisonous substances, and it is easy to
-imagine in the case of contagious diseases that a sort of selective
-process might go on that would bring the race up to the highest point to
-which fluctuating variations could be carried, even to complete
-immunity; but even if this were the case, it seems to be true that the
-moment the selection stopped the race would sink back to the former
-condition.
-
-All this touches only indirectly the main point that we have under
-consideration, namely, the existence of this power of resistance in
-cases where it cannot have been the result of any educative process.
-Since the responses to new poisons do not appear to be in principle
-different from the responses to those to which the organism may have
-possibly been subjected at times in the past, we shall probably not go
-far wrong if we treat all cases on the same general footing. Whether the
-power of adaptation to certain substances, such as nicotine, morphine,
-cocaine, arsenic, alcohol, etc., is brought about by the formation of a
-counter-substance is as yet unproven. And while it seems not improbable
-that in some of these instances it may turn out that this is the case,
-especially for poisons of plant origin, it is better to suspend judgment
-on this point until each case has been established.
-
-In recent years it has been shown that the animal body has the power of
-making counter-substances when a very large number of different kinds of
-things are introduced into the blood. We seem to be here on the
-threshold of a field for discovery which may, if opened up, give us an
-insight into some of the most remarkable phenomena of adaptation shown
-by living things.
-
-It has already been pointed out that it appears to be almost a _reductio
-ad absurdum_ to speak of animals adapting themselves to poisonous
-substances. It is curious, too, that in man at least the use of these
-substances may arouse a craving for the poison, or at any rate the
-individual may become so dependent on the poison that the depression
-following its disuse may lead to a desire for a repetition of the dose.
-The two questions that are raised here must be kept apart, for the
-adaptation of the individual to the poison and the so-called craving for
-it may depend on quite different factors. Nevertheless, it seems to be
-true in the case of morphine and of arsenic, and probably for some other
-substances as well, that if their use is suddenly stopped the individual
-may die in consequence. In this respect the organism behaves exactly as
-it does to an environment to which it has become adapted.
-
-
-                              Regeneration
-
-Many animals are able to replace lost parts, and all of them can heal
-wounds and mend injuries. This power is obviously of great advantage to
-them, and it has been supposed by Darwin, and more especially by his
-followers, that the power has been acquired through natural selection.
-It is not difficult to show that regeneration could not, in many cases,
-and presumably in none, have been acquired in this way. Since I have
-treated this subject at some length recently in my book on
-“Regeneration,” I shall attempt to do no more here than indicate the
-outline of the argument.
-
-The Darwinians believe that, if some individuals of a species have the
-power to replace a part that is lost better than have other individuals,
-it would follow that those would survive that regenerate best, and in
-this way after a time the power to regenerate perfectly would be
-acquired.
-
-But the matter is by no means so simple as may appear from this
-statement. In the first place, it is a matter of common observation that
-all the individuals of a species are never injured in the same part of
-the body at the same time. In those cases in which it is known that a
-special part is often injured, an examination has shown that there are
-not more than ten per cent of individuals that are injured at any one
-time, and in the case of the vast majority of animals this estimate is
-much too great. Thus there will be very little chance for competition of
-the injured individuals in each generation with each other, and the
-effects that are imagined to be gained as a result would be entirely
-lost by crossing with the uninjured individuals. But it is not necessary
-to consider this possibility, since there is another fact that shows at
-once that the power to regenerate could not have been gained through
-selection. The number of uninjured individuals in each generation will
-be much greater than the injured ones, and these will have so great an
-advantage over the injured individuals that, if competition approached
-the degree assumed by the selectionists, the injured individuals should
-be exterminated. A slight advantage gained through better powers of
-regeneration would be of little avail in competition, as compared with
-the competition with the uninjured individuals. Since selection is
-powerless to accomplish its end without competition, and since with
-competition all the injured individuals would be eliminated, it is clear
-that an appeal cannot be made to selection to explain the power of
-regeneration.
-
-In many cases the power of regeneration could not have been slowly
-acquired through selection, since the intermediate steps would be of no
-use. Unless, for example, a limb regenerated from the beginning almost
-completely, the result would be of no use to the animal. If the limb did
-regenerate completely the first time it was injured, then the selection
-hypothesis becomes superfluous.
-
-There are also a few cases known in which a process of regeneration
-takes place that is of no use to the animal. If, for instance, the
-earthworm (_Allolobophora fœtida_) be cut in two in the middle, the
-posterior piece regenerates at its anterior cut end, not a head, but a
-tail. Not by the widest stretch of the imagination can such a result be
-accounted for on the selection theory. Again, we find the reverse case,
-as it were, in certain planarians. If the head of _Planaria lugubris_ is
-cut off just behind the eyes, there develops at the cut surface of this
-head-piece another head turned in the opposite direction. Here again we
-have the regeneration of a perfect structure, but one that is entirely
-useless to the individual. The development of an antenna in place of an
-eye in the shrimp, when the eye stalk is cut off near its base, is
-another instance of the occurrence of a perfectly constant process, but
-one that is of no use to the organism.
-
-When we recall that in some organisms regeneration takes place in almost
-every part of the body, it does not seem possible that this power could
-have been acquired by selection. And when we find that many internal
-organs regenerate, that can rarely or never be injured without the
-animal perishing, it seems impossible that this can be ascribed to the
-principle of natural selection.
-
-It has also been found that if the first two cells of the egg of a
-number of animals, jellyfish, sea-urchins, salamanders, etc., be
-separated, each will produce an entire animal. In some of these cases it
-is inconceivable that the process could ever have been acquired through
-selection, because the cells themselves can be separated only by very
-special and artificial means.
-
-These, and other reasons, indicate with certainty that regeneration
-cannot be explained by the theory of natural selection.
-
-
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-
-
-
-
-                               CHAPTER XI
-
-                 TROPISMS AND INSTINCTS AS ADAPTATIONS
-
-
-Of the different kinds of adaptation none are more remarkable than those
-connected with the immediate responses of organisms to external agents.
-These responses are usually thought of as associated with the nervous
-system; and while in the higher forms the nervous system plays an
-important role in the reaction, yet in many cases it is little more than
-the shortest path between the point stimulated and the muscles that
-contract; and in the lower animals, where we find just as definite
-responses, there may be no distinct nervous system, as in the protozoa,
-for instance.
-
-Many of the so-called instincts of animals have been shown in recent
-years to be little more than direct responses to external agents. Many
-of these instincts are for the good of the individual, and must be
-looked upon as adaptations. For example: if a frog is placed in a jar of
-water, and the temperature of the water lowered, the frog will remain at
-the top until the water reaches 8 degrees C., when it will dive down to
-the bottom of the jar; and, if the temperature is further lowered, it
-will remain there until the water becomes warmer again, when it will
-come to the surface again. It is clear that, under the ordinary
-conditions of life of the frog, this reaction is useful to it, since it
-leads the animal to go to the bottom of the pond on the approach of cold
-weather, and thus to avoid being frozen at the surface.
-
-Another illustration of an instinct that is a simple response to light
-is shown by the earthworm. During the day the worm remains in its
-burrow, but on dark nights it comes out of its hole, and lies stretched
-out on the surface of the ground. It procures its food at this time, and
-the union of the individuals takes place. In the early morning the worm
-retires into its burrow.
-
-This habit of the earthworm is the direct result of its reaction to
-light. It crawls away from ordinary light as bright as that of diffuse
-daylight, and, indeed, from light very much fainter than that of
-daylight. If, however, the light be decreased to a certain point, the
-worm will then turn and crawl toward the source of light. This lower
-limit has been found by Adams to be about that of .001 candle-metre.
-This corresponds to the amount of light of a dark night, and gives an
-explanation of why the worm leaves its burrow only at night, and also
-why it crawls back on the approach of dawn. It is also obvious that this
-response is useful to the animal, for if it left the burrow during the
-day, it would quickly fall a prey to birds.
-
-The blow-fly lays its eggs on decaying meat, on which the larvæ feed.
-The fly is drawn to the meat by its sense of smell, a simple and direct
-response to a chemical compound given off by the meat. The maggot that
-lives in the decaying meat is also attracted by the same odor, as Loeb
-has shown, and will not leave the meat, or even a spot on a piece of
-glass that has been smeared with the juice of the meat, so long as the
-odor remains. Here again the life of the race depends on the proper
-response to an external agent, and the case is all the more interesting,
-since the response of the fly to the meat is of no immediate use to the
-fly itself, but to the maggot that hatches from the egg of the fly.
-
-The movement toward or from a stimulating agent is, in some cases,
-brought about in the following way. Suppose an earthworm is lying in
-complete darkness, and light be thrown upon it from one side. The worm
-turns its head, as it thrusts it forward, to the side away from the
-light; and as it again moves forward, it continues to bend its head away
-from the light, until it is crawling directly away from the source. When
-the light first strikes the worm, the two sides will be differently
-illuminated. This causes a bending of the head, as it stretches forward,
-toward the side of less illumination, and the bending is due to a
-stronger contraction of some of the muscles on the less illuminated
-side; at least the reaction appears to be due to a simple response of
-this kind. When the body has been so far turned that the two sides are
-equally illuminated, the muscles of the two sides will contract equally,
-and the movement will be straight forward and away from the light. If
-the reaction is as simple as this (which is in principle the explanation
-advanced by Loeb), the result is a simple reflex act, and need not
-involve any consciousness or intentional action on the part of the worm
-to crawl away from the light. In fact, the same reaction takes place
-when the brain is removed, not so quickly or definitely, it is true, but
-this may be due to the removal of the anterior segments of the worm, in
-which part the skin appears to be more sensitive to light than
-elsewhere.
-
-Another factor that plays an important rôle in the habits of the
-earthworm is the response to contact,—the so-called stereotropism. If,
-in crawling over a flat surface, the worm comes in contact with a
-crevice, it will crawl along it, and refuse to leave until the end is
-reached. The contact holds the worm as strongly as though it were
-actually pulled into the crevice. It can be forced to leave a crevice
-only by strong sunlight, and then it does not do so at once. If the worm
-crawls into a small glass tube, it is also held there by its response to
-contact, and the smaller the tube, the more difficult is it to make the
-worm leave by throwing strong sunlight upon it.
-
-Loeb has found that when winged aphids, the sexual forms, are collected
-in a tube, and the tube is kept in a room, the aphids crawl toward the
-light. This happens in ordinary diffuse light, as well as in lamplight.
-It is stated that the animals orientate themselves towards the light
-more quickly when it is strong than when it is weak. They turn their
-bodies toward the light, and then move forward in the direction from
-which the rays come. It can be shown by a simple experiment that the
-aphids are turned by the _direction_ of the light, and not by its
-intensity. If they are placed in a tube, and the tube laid obliquely
-before a window in such a way that the direct sunlight falls only on the
-inner end of the tube, the aphids will, if started at the inner end of
-the tube, first crawl toward the outer surface of the tube, and then
-wander along this wall, passing out of the region of sunlight into the
-end of the tube nearest the window, where they come to rest at the end.
-They have moved constantly towards the direction from which the rays
-come, passing, as it were, from ray to ray, but each time toward a ray
-nearer the source of the light.
-
-If the tube be turned toward the window, and the window end be covered
-with blue glass, the aphids crawl into this end of the tube, as they
-would have done had the tube been uncovered. If, on the other hand, the
-end of the tube be covered with red glass, they do not crawl into the
-part of the tube that is covered, unless they are very sensitive to
-light. Even in the latter case they may remain scattered in the red
-part, and do not all accumulate at the end, as they do when blue glass
-is used. In other words, while they respond to blue as they do to
-ordinary light, they behave toward red as they do towards a very faint
-light.
-
-In diffuse daylight the aphids, as has been said, crawl toward the
-light, but if they come suddenly into the sunlight they begin to fly.
-Thus they remain on the food-plant until the sun strikes it, and then
-they fly away.
-
-The aphid also shows another response; it is negatively geotropic,
-_i.e._ it tends to crawl upward against gravity. If placed on an
-inclined, or on a vertical, surface, it will crawl upward. Such an
-experiment is best made in the dark, since in the light the aphid also
-responds to the light. If put on a window it crawls upward never
-downward.
-
-Aphids are also sensitive to heat. If they are placed in a darkened tube
-and put near a stove, they crawl away from the warmer end; but if they
-are acted upon by the light at the same time, they will be more strongly
-attracted by the light than repulsed by the heat. We thus see that there
-are at least three external agents that determine the movements of this
-animal, and its ordinary behavior is determined by a combination of
-these, or by that one that acts so strongly as to overpower the others.
-
-The swarming of the male and female ants is also largely directed by the
-influence of light. Loeb observed that when the direct sunlight fell
-full upon a nest in a wall the sexual forms emerged, and then flew away.
-Other nests in the ground were affected earlier in the day, because the
-sun reached them first. These ants, when tested, were found to respond
-to light in the same way as do the aphids. The wingless forms, or worker
-ants, do not show this response, and the winged forms soon lose their
-strong response to light after they have left the nest. Thus we see that
-the heliotropism is here connected with a certain stage in the
-development of the individual; and this is useful to the species, as it
-leads the winged queens and males to leave the nest, and form new
-colonies. Even the loss of response that takes place later may be looked
-upon as beneficial to the species, since the queens do not leave the
-nest after they have once established it.
-
-It is familiar to every one that many of the night-flying insects are
-attracted to a lamplight, and since those that fly most rapidly may be
-actually carried into the flame before they can turn aside, it may seem
-that such a response is worse than useless to them. The result must be
-considered, however, in connection with other conditions of their life.
-The following experiments carried out by Loeb on moths show some of the
-responses of these insects to light.
-
-Night-flying moths were placed in a box and exposed in a room to
-ordinary light. As twilight approached the moths became active and began
-to fly always toward the window side of the box. They were positively
-heliotropic to light of this intensity. If let out of the case, they
-flew toward the window, where they remained even during the whole of the
-next day, fully exposed to light. If the moth is disturbed in the
-daytime, so that it flies, it goes always toward the light, and never
-away from it. These facts show that the moth is always positively
-heliotropic, and also that the flight toward the lamp is a natural
-response, misapplied in this case. That the moths do not fly by day is
-due to another factor, namely, the alternation in the degree of their
-sensitiveness at different times. But this condition alone does not seem
-to account fully for all the facts.
-
-If the moths are given the alternative of flying toward the evening
-light, or toward the lamp, they always go toward the brighter light.
-Thus if, when they swarm at dusk, they are set free in the middle of the
-room, at the back of which a lamp is burning, the moths fly toward the
-window. If, however, they are set free within a metre of the lamp, they
-fly toward it.
-
-The explanation that Loeb offers of the habit of these moths to fly only
-in the evening is, that, although they are at all times positively
-heliotropic, they respond to light only in the evening. In other words,
-it is assumed that there is a periodic change in their sensitiveness to
-light, which corresponds with the change from day to night. Loeb says
-that, just as certain flowers open only at night, and others only during
-the day, so do moths become more responsive in the evening, and
-butterflies during the day. Both moths and butterflies are positively
-heliotropic, and the sensitiveness of moths to light may be even greater
-in the evening than is that of butterflies, for the light of the evening
-to which the moth reacts is less than the minimal to which the butterfly
-responds.
-
-Moths appear to pass into a sort of sleep during the day, while
-butterflies are quiescent only at night. The periodicity of the sleeping
-time continues, at least for several days, when the insects are kept in
-the dark. For instance, moths kept in the dark become restless as the
-evening approaches, as Réaumur observed long ago. It has been found in
-plants that this sort of periodicity may continue for several days, but
-gradually disappears if the plants are kept in the dark. By using
-artificial light, and exposing the plants to it during the night, and
-putting them in the dark during the day, a new periodicity, alternating
-with the former one, may be induced; and this will continue for some
-days if the plants are then kept continually in the dark.
-
-Loeb tried the experiment of exposing the quiescent moths suddenly to a
-lower intensity of light, in order to see if they would respond equally
-well at any time of day. It was found that if the change was made in the
-forenoon, between six o’clock and noon, it was not possible to awaken
-the moths by a sudden decrease in the intensity of the light. But it was
-possible to do so in the afternoon, long before the appearance of dusk.
-It appears, therefore, that in this species, _Sphinx euphorbiæ_, it is
-possible to influence the period of awakening by decreasing the
-intensity of light, but this can be done only near the natural period of
-awakening. It seems to me that this awaking of a positively heliotropic
-animal by decreasing the light needs to be further investigated.
-
-The day butterflies are also positively heliotropic. Butterflies of the
-species _Papilio machaon_, that have been raised from the pupa, remain
-quietly on the window in the diffuse daylight of a bright day. They can
-be carried around on the finger without leaving it, but the moment they
-come into the direct rays of the sun they fly away.
-
-Butterflies that have just emerged from their pupa case exhibit a marked
-negative geotropic reaction, and this appears to be connected with the
-necessity of unfolding their wings at this time. Loeb says that the same
-cause that determines the direction of the falling stone and the paths
-of the planets, namely, gravity, also directs the actions of the
-butterfly that has just left its pupa case. The geotropic response is
-especially strong at first. The animal wanders around until it reaches a
-vertical wall, which it immediately ascends, straight upward, and
-remains hanging at the top until its wings have unfolded. A similar
-response occurs in the final stage of the larva of the May-fly, which
-leaves the water and crawls up a blade of grass, or other vertical
-support, and there, bursting the pupa skin, it dries its wings and flies
-away. That this is a reaction to gravity and not to light is shown by
-Loeb’s observation, that their empty skins are sometimes observed under
-a bridge where the light does not come from above. “This observation on
-the larva of the May-fly contradicts the assumption that the ‘purpose’
-of the geotropic response of the butterfly is that it may the better
-unfold its new wings, for in the ephemerid larva the negative geotropism
-appears at a time when no wings are present.” On the other hand, it
-should not be overlooked that the reaction is important for the May-fly
-larva in other ways, because it leads the larva to leave the water at
-the right period, and come out into the air, where the flying insect can
-more safely emerge.
-
-It is not without interest to find that caterpillars exhibit some of the
-same reaction shown by butterflies. Loeb has made numerous experiments
-with the caterpillars of _Porthesia chrysorrhœa_. The caterpillars of
-this moth collect together in the autumn and spin a web or nest in which
-they pass the winter. If they are taken from the nest and brought into a
-warm room, they will orientate themselves to the light, and also crawl
-toward it. If placed in a tube, they crawl to the upper side of the
-glass and then along this side toward the light. If a covering is placed
-over the end of the tube that is turned toward the window, the
-caterpillars will crawl only as far as the edge of the cloth. They also
-react negatively to gravity. If kept in a dark room, they will crawl
-upward to the top of the receptacle in which they are enclosed. If
-subjected to the influences of both light and gravity, they respond more
-strongly to the light. The caterpillars also show a contact reaction.
-They tend to collect on convex sides or on corners and angles of solid
-bodies. They may even pile up one on top of the other in response to
-this reaction; the convex side of a quiescent animal acting on another
-animal crawling over it as any convex surface would do and holding the
-animal fast.
-
-These three kinds of reactions determine the instincts of these
-caterpillars. In the spring, when they become warm, they leave the nest.
-Positive heliotropism and negative geotropism compel them to crawl
-upward to the tops of the branches of the trees, and there the contact
-reaction with the small buds holds them fast in this place. That they
-are not attracted to the end of the branches by the food that they find
-there is shown by placing buds in the bottom of the tubes in which the
-caterpillars are contained. The caterpillars remain at the top of the
-tube, although food is within easy reach. If, however, they are placed
-directly on the buds, the contact reaction will hold them there, and
-they will not crawl farther upward. Curiously enough, as soon as the
-caterpillars have fed and the time for shedding approaches, the
-responsiveness to light and to gravity decreases, and at the time of
-shedding they do not respond at all to these agents. These same
-caterpillars react also to warmth above a certain point. In a dark tube
-placed near a stove, the caterpillars collect at the end farthest away
-from the source of the heat. They react to light best at a temperature
-between 20 and 30 degrees C., and above this temperature point they
-become restless and wander about.
-
-The very close connection between the reactions of this caterpillar and
-its mode of life is perfectly obvious. The entire series of changes
-seems to have for its “purpose” the survival of the individual by
-bringing it to the place where it will find its food. It may seem
-natural to conclude that these responses have been acquired for this
-very purpose, but let us not too quickly jump at this obvious conclusion
-until the whole subject has been more fully examined.
-
-The upward and downward movements of some pelagic animals have been
-shown to depend on certain tropic responses. Every student of marine
-zoology is familiar with the fact that many animals come to the surface
-at night, and go down at the approach of daylight. It has been shown
-that this migration is due largely to a response to light. Light can
-penetrate to only about four hundred metres in sea-water, and there is
-complete darkness below this level. It has been shown that the swimming
-larvæ of one of the barnacles is positively heliotropic in a weak light,
-but negatively heliotropic in a stronger light. Animals having responses
-like these will come to the surface as the light fades away in the
-evening and remain there until the light becomes too bright in the
-following morning. They will then become negatively heliotropic and
-begin to go down. When they reach a level where the intensity of the
-light is such that they become positively heliotropic, they will turn
-and start upward again. Thus during the day they will keep below the
-surface, remaining in the region where they change from positive to
-negative, and _vice versa_.
-
-It would not be difficult to imagine that this upward and downward
-migration of pelagic animals is useful to them, but, on the other hand,
-it may be equally well imagined that the response may be injurious to
-them. Thus it might be supposed that certain forms could procure their
-food by coming to the surface at night, and avoid their enemies by going
-down during the day. But it is difficult to see why organisms that serve
-as prey should not have acquired exactly the opposite tropisms in order
-to escape.
-
-Some of these marine forms are also geotropic. Loeb has determined that
-“the same circumstances that make the animals negatively heliotropic
-also make them positively geotropic, and _vice versa_.” It was found,
-for instance, that the larva of the marine worm Polygordius is
-negatively geotropic at a low temperature, while at a higher temperature
-it is positively geotropic. This response would drive the animals upward
-when the water becomes too cold, and back again if the surface water
-becomes too warm; but whether the response is so adjusted that the
-animals keep, as far as possible, in water of that temperature that is
-best for their development, we do not know. We can easily imagine that
-within wide limits this is the case.
-
-The change from positive to negative can also be brought about in other
-ways. One of the most striking cases of this sort is that described by
-Towle in one of the small crustaceans, _Cypridopsis vidua_. It was found
-that after an animal had been picked up in a pipette its response was
-always positive; that is, it swam toward the light, no matter what its
-previous condition had been. The disturbance caused by picking the
-animal up induced always a positive response towards light. If the light
-were moved, the Cypridopsis followed the light. In this way it could be
-kept positive for some time, but if it came to rest, or if it came into
-contact with the sides or end of the trough, it became, after a short
-time, negatively heliotropic, and remained negative as long as it could
-be kept in motion, without being disturbed, or coming into contact with
-a solid object. If when positive it were allowed to reach the glass at
-the end of the trough, it would swim about there, knocking against the
-glass, and then soon turn and swim away from the light. If the light
-were shifted while the negative animal was in the middle of the trough,
-it would turn and swim directly away, as before, from the source of
-light. It could be kept in this negative state as long as it did not
-come into contact with the ends.
-
-It appears that the positive condition in Cypridopsis is of short
-duration, and ceases after a while either as a response to contact or
-without any observable external factor causing the change.
-
-This crustacean lives at the bottom of pools, amongst water-plants, and
-here also, no doubt, the same change from one to the other reaction
-takes place. What possible advantage it may be to the animal to be kept
-continually changing in this way is not at all obvious, nor, in fact,
-are we obliged to assume that this reaction may be of any special use to
-it. Indeed, it is far from obvious how the change that causes the animal
-to swim toward the light when it is disturbed could be of the least
-advantage to it.
-
-In another crustacean, one of the marine copepods, _Labidocera æstiva_,
-it has been shown by Parker that the male and female react in a somewhat
-different way both to light and to gravity. The females are strongly
-negatively geotropic, and this sends them up to the top of the water.
-The males are very slightly negatively geotropic. The females are
-strongly positively heliotropic toward light of low intensity; the males
-show the same response to a less degree. To strong light the females are
-negative and the males are indifferent. On the other hand, the males are
-attracted to the females, probably in response to some chemical
-substance diffusing from the females, since the males show the same
-reaction when the females are enclosed in an opaque tube through whose
-ends a diffusion of substances may take place. This crustacean frequents
-the surface of the ocean from sunset to sunrise. During the day it
-retires to deeper water. Its migrations can be explained as follows: The
-females come to the surface at night, because they are positively
-heliotropic to weak light, and also because they are negatively
-geotropic. They go down during the day, because they react to bright
-light more strongly than to gravity. The males follow the females,
-largely because they react positively chemotactically toward the
-females.
-
-Some other animals respond in a somewhat different way to light, as
-shown by the fresh-water planarians. These animals remain during the day
-under stones, where the amount of light is relatively less than outside.
-If they are placed in a dish in the light in front of a window, they
-crawl away from the light, but when they reach the back of the dish they
-do not come to rest, but continue to crawl around the sides of the dish
-even toward the light. The light makes the worms restless, and while
-they show a negative response as long as they are perfectly free to move
-away from the light, they will not come to rest when they come to the
-back of the dish if they are there still in the light, because the
-irritating action of the light on them is stronger than its directive
-action. If, however, in crawling about they come accidentally into a
-place less bright than that in which they have been, they stop, and will
-not leave this somewhat darker spot for a brighter one, although they
-might leave the newly found spot for one still less bright.
-
-At night the planarians come out and wander around, which increases
-their chance of finding food, although it would not be strictly correct
-to say that they come out in search of food. If, however, food is placed
-near them, a piece of a worm, for example, they will turn toward it,
-being directed apparently by a sense of smell, or rather of taste.
-
-The heliotropic responses of the planarians appear to be of use to them,
-causing them to hide away in the daytime, and to come out only after
-dark, when their motions will not discover them to possible enemies. But
-some of the planarians are protected in other ways, so that they will
-not be eaten by fish, probably owing to a bad taste; so that it is not
-so apparent that they are in real need of the protection that their
-heliotropic response brings to them. Their turning towards their food
-is, however, beyond question of great advantage to them, for in this way
-they can find food that they cannot detect in any other way.
-
-The unicellular plants were amongst the first organisms whose tropic
-responses were studied, and the classical work of Strasburger gave the
-impetus to much of the later work. In recent years the unicellular
-animals, the protozoans, have been carefully studied, more especially by
-Jennings. His results show that the reactions in these animals are
-different in some important respects from those met with in higher
-forms. For instance, most of the free-swimming infusoria are
-unsymmetrical, as are also many of the flagellate forms, and as they
-move forward they rotate freely on a longitudinal axis. It is therefore
-impossible that they could orientate themselves as do the higher animals
-that have been described above, and we should not expect these Protozoa
-to react in the same way. In fact, Jennings shows that they exhibit a
-different mode of response. Paramœcium offers a typical case. As it
-moves forward it rotates toward the aboral side of the body. As a result
-of the asymmetry of the body, the path followed, as it revolves on its
-own axis, is that of a spiral. Did the animal not rotate, as it swims
-forward, its asymmetrical form would cause it to move in a circle, but
-its rotation causes, as has been said, the course to be that of a
-spiral, and the general direction of movement is forward.[31] The
-rotation of a paramœcium on its axis is in turn caused by the oblique
-stroke of the cilia that cover the surface of the body. Their action
-when reversed causes the animal to rotate backward.
-
-Footnote 31:
-
-  The same result is attained by a bullet that is caused by the rifling
-  to rotate as it moves forward.
-
-If a drop of weak acid be put into the water in which the paramœcia are
-swimming,—for instance, in the water between a cover-slip and a
-slide,—it will be found, after a time, that many individuals have
-collected in the drop. It was at first supposed that the paramœcia are
-attracted by the diffusion of the acid in the water, and turn toward the
-source of the chemical stimulus; but Jennings has shown that this is not
-the way in which the aggregation is brought about. If the individuals
-are watched, it will be found that they swim forward in a spiral path
-without regard to the position of the drop of acid. If one happens, by
-chance, to run into the drop, there is no reaction as it enters, but
-when it reaches the other side of the drop, and comes into contact with
-the water on this side, it suddenly reacts. It stops, backs into the
-middle of the drop, rotates somewhat toward the aboral side (_i.e._ away
-from the vestibule), and then starts forward again, only to repeat the
-action on coming into contact with the edge of the drop again. The
-paramœcium has been caught in a veritable trap. All paramœcia that
-chance to swim into the drop will also be caught, until finally a large
-number will accumulate in the region. The result shows, that, in passing
-from ordinary water into a weak acid, no reaction takes place; but
-having once entered the acid, the animal reacts on coming into contact
-with the water again.
-
-On the other hand, there are some substances to which the paramœcium may
-be said to be negatively chemotropic. If a drop of a weak alkaline
-solution be put into water in which paramœcium is swimming, an
-individual that happens to run against it reacts at once. It stops
-instantly, backs off, revolving in the opposite direction, turns
-somewhat to one side, and swims forward again. The chances are that it
-will again hit the drop, in which case it repeats the same reaction,
-turning again to one side. If it continues to react in this way, it
-will, in the course of time, turn so far that when it swims forward it
-will miss the edge of the drop, and then continue on its way. If an
-individual were put into an alkaline drop, it would leave it, because it
-would not react when it passed from inside the drop into the surrounding
-water.
-
-Unicellular animals react to other things besides differences in the
-chemical composition of different parts of a solution. In many cases
-they react to light, swimming toward or away from it according to
-whether they are positively or negatively heliotropic. If they are
-positively heliotropic, and while swimming run into a shadow, they react
-as they would on coming into contact with a drop of acid. Since they
-rotate as they swim forward, we cannot explain their orientation as in
-the case of other animals that hold a fixed vertical position. If we
-assume that the two ends of the body are differently affected by the
-light, for which there is some evidence, we can perhaps in this way
-account for their turning toward, or away from, the source of light.
-
-Changes in the osmotic pressure of the different parts of the fluid,
-mechanical stimulation produced by jarring, extremes of heat and of
-cold, all cause this same characteristic reaction in Paramœcium; and
-this accounts for their behavior toward these agents that are so
-different in other respects.
-
-Paramœcia, as well as other protozoans, show a contact response. They
-fix themselves to certain kinds of solid bodies. If, for example, a
-small bit of bacterial slime is put into the water, the paramœcia
-collect around it in crowds, and eat the bacteria; but they will collect
-in the same way around almost any solid. On coming in contact with
-bodies having a certain physical texture, the cilia covering the
-paramœcium stop moving, only those in the oral groove continuing to
-strike backward. The animal comes to rest, pressed against the solid
-body. If one or more paramœcia remain in the same place, they set free
-carbon dioxide, as a result of their respiratory processes. There is
-formed around them a region containing more of this acid than does the
-surrounding water. If other moving paramœcia swim, by chance, into this
-region, they are caught, and as a result an accumulation of individuals
-will take place. The more that collect the larger will the area become,
-and thus large numbers may be ultimately entrapped in a region where
-there is formed a substance that, from analogy with other animals, we
-should expect to be injurious.
-
-The question as to how far these responses of the unicellular forms are
-of advantage to them is difficult to decide, for while, as in the above
-case, the response appears to be injurious rather than useful, yet under
-other conditions the same response may be eminently advantageous. In
-other cases, as when the paramœcia back away, and then swim forward
-again, only to repeat the process, the act appears to be such a stupid
-way of avoiding an obstacle that the reaction hardly appears to us in
-the light of a very perfect adaptation. If we saw a higher animal trying
-to get around a wall by butting its head into it until the end was
-finally reached, we should probably not look upon that animal as well
-adapted for avoiding obstacles.
-
-Bacteria, which are generally looked upon as unicellular plants, appear,
-despite the earlier statements to the contrary, to react in much the
-same way as do the protozoans, according to the recent work of Rothert,
-and of Jennings and Crosby. The bacteria do not seem to turn toward or
-away from chemical substances, but they collect in regions containing
-certain substances in much the same way as do the protozoans. The
-collecting of bacteria in regions where oxygen is present has been known
-for some time, but it appears from more recent results that they are not
-attracted toward the oxygen, but by accidentally swimming into a region
-containing more oxygen they are held there in the same way as is
-paramœcium in a drop of acid. On the other hand bacteria do not enter a
-drop of salt solution, or of acids, or of alkalies. They react
-negatively to all such substances. Some kinds of bacteria have a
-flagellum at each end, and swim indifferently in either direction. If
-they meet with something that stimulates them, as they move forward,
-they swim away in the opposite direction, and continue to move in the
-new direction until something causes again a reversal of their movement.
-In this respect their mode of reaction seems of greater advantage than
-that followed by paramœcium.
-
-Another instinct, that appears to be due to a tropic response, is the
-definite time of day at which some marine animals deposit their eggs.
-The primitive fish, Amphioxus, sets free its eggs and sperm only in the
-late afternoon. A jellyfish, Gonionema, also lays its eggs as the light
-begins to grow less in the late afternoon, and in this case it has been
-found that the process can be hastened if the animals are placed in the
-dark some hours before their regular time of laying. There is no
-evidence that this habit is of any advantage to the animal. We may
-imagine, if we like, that the early stages may meet with less risk at
-night, but this is not probable, for it is at this time that countless
-marine organisms come to the surface, and it would seem that the chance
-of the eggs being destroyed would then be much greater. It is more
-probable that the response is of no immediate advantage to the animals
-that exhibit it, although in particular cases it may happen to be so.
-
-This response recalls the diurnal opening and closing of certain
-flowers. The flowers of the night-blooming cereus open only in the dusk
-of evening, and then emit their strong fragrance. Other flowers open
-only in the daytime, and some only in bright sunlight. It is sometimes
-pointed out that it is of advantage to some of these flowers to open at
-a certain time, since the particular insects that are best suited to
-fertilize them may then be abroad. This may often be the case, but we
-cannot but suspect that in other cases it may be a matter of little
-importance. In special instances it may be that the time of opening of
-the flowers is of importance to the species; but even if this is so,
-there is no need to assume that the response has been gradually acquired
-for this particular purpose. If it were characteristic of a new form to
-open at a particular time, and there were insects in search of food at
-this time that would be likely to fertilize the plant, then the plant
-would be capable of existing; but this is quite different from supposing
-that the plant developed this particular response, because this was the
-most advantageous time of day for the fertilization of its flowers.
-
-We can apply this same point of view, I believe, to many of the
-remarkable series of tropisms shown by plants, whose whole existence in
-some cases is closely connected with definite reactions to their
-environment. Let us examine some of these cases.
-
-When a seed germinates, the young stem is negatively geotropic, and, in
-consequence, as it elongates it turns upward towards the light that is
-necessary for its later growth. The root, on the contrary, is positively
-geotropic, and, in consequence, it is carried downward in the ground.
-Both responses are in this case of the highest importance to the
-seedling, for in this way its principal organs are carried into that
-environment to which they are especially adapted. It matters very little
-how the seed lies in the ground, since the stem when it emerges will
-grow upward and the root downward. The young stem, when it emerges from
-the soil, will turn toward the light if the illumination comes from one
-side, and this also may often be of advantage to the plant, since it
-turns toward the source from which it gets its energy. The leaves also
-turn their broad surfaces toward the light, and as a result they are
-able to make use of a greater amount of the energy of the sunlight. The
-turning is due to one side of the stem growing more slowly than the
-opposite side, and it is true, in general, that plants grow faster at
-night than in the daylight. Very bright light will in some cases
-actually stop all growth for a time. Thus we see that this bending of
-the stem toward the light and the turning of the leaves to face the
-light are only parts of the general relation of the whole plant toward
-the light.
-
-Negative heliotropism is much less frequent in plants. It has been
-observed in aërial roots, in many roots that are ordinarily buried in
-the ground, in anchoring tendrils that serve as holdfasts, and even in
-the stems of certain climbers. In all of these cases, and more
-especially in the case of the climbers, the reaction is obviously of
-advantage to the plant; and it is significant to find, in plants that
-climb by tendrils carrying adhering disks, that there is a reversal of
-the ordinary heliotropism shown by homologous organs in other plants.
-There is an obvious adaptation in the behavior of the tendril, since its
-growth away from the more illuminated side is just the sort of reaction
-that is likely to bring it into contact with a solid body.
-
-In this connection it is important to observe that these reactions to
-light are perfectly definite, being either positive or negative under
-given conditions, and therefore there is at present nothing to indicate
-that there has been a gradual transformation from positive to negative,
-or _vice versa_. It seems to me much more probable that when the
-structural change took place, that converted the plant into a climber,
-there appeared a new heliotropic response associated with the other
-change. In other words, both appeared together in the new organ, and
-neither was gradually acquired by picking out fluctuating variations.
-
-The leaves of plants also show a sort of transverse heliotropic
-response. It has been found, for example, that the leaves of Malva will
-turn completely over if illuminated by a mirror from below. A curious
-case of change of heliotropism is found in the flower stalks of Linaria.
-They are at first positively heliotropic, but after the flower has been
-fertilized the stalk becomes negatively heliotropic. As the stalks
-continue to grow longer, they push the fruits into the crevices of the
-rocks on which the plants grow, and in this way insure the lodgement of
-the seeds. Here we have an excellent example showing that the negative
-heliotropism of the flower stalk could scarcely have been acquired by
-slight changes in the final direction, for only the complete change is
-useful to the plant. Intermediate steps would have no special value.
-
-As has been pointed out in the case of the seedling plant, the main stem
-responds positively and the roots negatively to gravity. In addition to
-this, the lateral position taken by the lateral roots and branches and
-by underground stems are also, in part, due to a geotropic response. In
-this case also the effect is produced by the increased growth on the
-upper side when the response is positive, and on the lower when it is
-negative. Leaves also assume a transverse position in response to the
-action of gravity, or at least they make a definite angle with the
-direction of its action.
-
-The most striking case of geotropic response is seen in plants that
-climb up the stems of other plants. The twining around the support is
-the result of a geotropic response of the sides of the stem. The young
-seedling plant stands at first erect. As its end grows it begins to
-curve to one side in an oblique position, and this is due to an increase
-in growth on one side of the apex of the shoot. As a result the stem
-bends toward the other side. Not only does the end “sweep round in a
-circle like the hands of a watch,” but it rotates on its long axis as it
-revolves. As a result of this rotation “the part of the stem subjected
-to the action of the lateral geotropism is constantly changing; and the
-revolving movement once begun, must continue, as no position of
-equilibrium can be attained.” This movement will carry the end around
-any support, not too thick, that the stem touches.
-
-Most climbers turn to the left, _i.e._ against the hands of a watch,
-others are dextral, and a few climb either way.[32] Strasburger states
-that whenever any external force, or substance, is important to the
-vital activity of the plant or any of its organs, there will also be
-found to be developed a corresponding irritability to their influence.
-Roots in dry soil are diverted to more favorable positions by the
-presence of greater quantities of moisture. This may, I venture to
-suggest, be putting the cart before the horse. The plant may be only
-able to exist whose responses are suited to certain external conditions,
-and these determine the limits of distribution of the plant or the
-places in which it is found.
-
-Footnote 32:
-
-  These cases recall the spiral growth of the shell of the snail, but
-  the spiral in the latter is due to some other factor.
-
-A number of plants climb in a different way, and show another sort of
-tropism. Those that climb by means of tendrils twist their tendrils
-about any support that they happen to come in contact with, and thus the
-plant is able to lift its weak stem, step by step, into the air. The
-twining of the tendrils is due to contact, which causes a cessation of
-growth at the points of contact. The growth of the opposite side
-continues, and thus the tendril bends about its support. In the grape
-and in ampelopsis the tendril is a modified branch. The stalk of the
-leaves in a few plants, as in Lophospermum, act as tendrils. Other
-climbers are able to ascend vertical walls owing to the presence of
-disks, whose secretions hold the tendril firmly against the support, as
-in ampelopsis.
-
-It is interesting to find in practically all these cases that, whatever
-the stimulus may be, the results are reached in the same way, namely, by
-one part growing faster than another. The fact of importance in this
-connection is that the plant is so constructed that the response is
-often beneficial to the organism.
-
-Before leaving this subject there is one set of responses to be referred
-to that is not the result of growth. Certain movements are brought about
-by the change in the turgidity of certain organs. The small lateral
-leaflets of _Desmodium gyrans_ make circling movements in one to three
-minutes. No apparent benefit results from their action. The terminal
-leaflets of _Trifolium pratense_ oscillate in periods of two to four
-hours, but do so only in the dark; in the light the leaflets assume a
-rigid position. There is nothing in the process to suggest that the
-movement is useful to the plant, and yet it appears to be as definite as
-are those cases in which the response is of vital importance. Had these
-movements been of use, their origin would, no doubt, have been explained
-because of their usefulness, and the conclusion would have been wrong.
-
-The leaves of the Mimosa respond, when touched, and it cannot be
-supposed that this is of any great advantage to the plant. The sleep
-movements of many plants are also due to the effect of light. In some
-cases the leaflets are brought together with their upper surfaces in
-contact with one another; in other cases the lower surfaces are brought
-together. Darwin supposed that these sleep movements served to protect
-the leaves from a too rapid loss of heat through radiation, but it has
-been pointed out that tropical plants exhibit the same responses. We
-have here another admirable instance of the danger of concluding that
-because we can imagine an advantage of a certain change, that the change
-has, therefore, been acquired because of the advantage. In the Mimosa
-not only do the leaflets close together, but the whole leaf drops down
-if the stimulus is strong. Other plants also show in a less degree the
-same movements, Robinia and Oxalis for instance, and certainly in these
-latter the result does not appear to be of any advantage to the plants.
-
-The preceding account of some of the tropisms in animals and plants will
-serve to give an idea of how certain movements are direct responses to
-the environment. Some of the reactions appear to be necessary for the
-life of the individual, others seem to be of less importance, and a few
-of no use at all. Yet the latter appear to be as definite and
-well-marked as are the useful responses. I think the conviction will
-impress itself on any one who examines critically the facts, that we are
-not warranted in applying one explanation to those responses that are of
-use, and another to those that are of little or of no value. Inasmuch as
-the Darwinian theory fails to account for the origin of organs of little
-or of no value, it is doubtful if it is needed to explain the origin of
-the useful responses. If, on the other hand, we assume that the _origin_
-of the responses has nothing to do with their value to the organism, we
-meet with no difficulty in those cases in which the response is of
-little or of no use to the organism. That great numbers of responses are
-of benefit to the organism that exhibits them can be accounted for on
-the grounds that those new species, that have appeared, that have useful
-responses, are more likely, in the long run, to survive, than are those
-that do not respond adaptively.
-
-We may now examine some of the more complicated responses and instincts,
-more especially those of the higher animals. Some of these are pure
-tropisms, _i.e._ definite responses or reactions to an external exciting
-agent; others may be, in part, the result of individual experience,
-involving memory; others, combinations of the two; and still others may
-depend on a more complex reaction in the central nervous system of the
-animal. These cases can be best understood by means of a few
-illustrations.
-
-As an example of a simple action may be cited a well-known reflex after
-cutting the nerve-cord of the frog, or after destroying the brain. If
-the frog is held up, and its side tickled, the leg is drawn up to rub
-the place touched. To accomplish this requires a beautifully adjusted
-system of movements, yet the act seems to be a direct reflex, involving
-only the spinal cord.
-
-An example of a somewhat more complex reflex is the biting off of the
-navel-string by the mother in rodents and other mammals; an act
-eminently useful to the young animal, although of no importance to the
-mother herself. The protection of the young by their parents from the
-attacks of other animals appears to be a somewhat complex instinct, and
-it is interesting to note that the protection is extended to the young
-only so long as they are in need of it, and as soon as they are able to
-shift for themselves the maternal protection is withdrawn.
-
-The instinct of the young chick to seize in its beak any small moving
-object is a simple and useful reflex action, but if the object should
-happen to be a bee which stings the chick, another bee or similar insect
-will not be seized. Here we see that a reflex has been changed, and
-changed with amazing quickness. Moreover, the chick has learnt to
-associate this experience with a particular sort of moving object. It is
-this power to benefit by the result of a brief experience that is one of
-the most advantageous properties of the organism.
-
-Young chicks first show a drinking reflex if by chance their beaks are
-wet by water. At once the head is lifted up, and the drop of water
-passes down the throat. In this way the chick first learns the meaning
-of water, and no doubt soon comes to associate it with its own condition
-of thirst. The sight of water produces no effect on the inexperienced
-chick, and it may even stand with its feet in the water without
-drinking; but as soon as it touches, by chance, the water with its beak,
-the reflex, or rather the set of reflexes is started.
-
-A more complicated instinct is that shown by the spider in making its
-web. In some cases the young are born from eggs laid in the preceding
-summer, and can have had, therefore, no experience of what a web is
-like; and yet, when they come to build this wonderfully complex
-structure, they do so in a manner that is strictly characteristic of the
-species.
-
-The formation of the comb by bees, in which process, with a minimum of
-wax, they secure a maximum number of small storehouses in which to keep
-their honey and rear their young, is often cited as a remarkable case of
-adaptation.
-
-There has been some discussion as to whether birds build their nests in
-imitation of the nest in which they were reared, or whether they do so
-independently of any such experience. There can be no doubt, however,
-that in some birds neither memory nor imitation can play any important
-part in the result, and that they build their nests as instinctively as
-spiders make webs.
-
-These instincts of spiders, bees, and birds appear to be more complex
-than the reflexes and tropisms that were first described. Whether they
-are really so, or only combinations of simple responses, we do not yet
-know. That they have come suddenly into existence as we now find them
-does not seem probable, but this does not mean that they must have been
-slowly acquired as the result of selection. The mutation theory also
-assumes that the steps of advance may have been small.
-
-Our account may be concluded with the recital of some instincts, chosen
-almost at random, that serve to show some other adaptations which are
-the result of these inborn responses.
-
-It is known that ants travel long distances from their nests, and yet
-return with unerring accuracy. It has been shown that they are able to
-do this through a marvellous sense of smell. The track left by the ant,
-as it leaves the nest, serves as a trail in returning to the
-starting-point. Moreover, it appears that the ant can pick out her own
-trail, even when it has been crossed by that of other ants. This means
-that she can distinguish the odor of her own trail from that of other
-members of the colony. The sense-organs by means of which the odor is
-detected lie in the antennæ. This fact accounts for certain actions of
-ants that have been described as showing that they have an affection for
-each other. Two ants, meeting, pat each other with their antennæ. In
-this way they are quickly able to distinguish members of their own nest
-from those of other nests. If they are of the same nest, they separate
-quietly; if of other nests, they may fight. If an ant from one nest is
-put into another nest, it is instantly attacked and killed—an act that
-appears to be injurious rather than useful, for the ant might become a
-valuable member of the new colony. If, however, an ant is first immersed
-in the blood of a member of the community into which she is to be
-introduced, she will not be attacked, and may soon become a part of the
-new community. By her baptism of blood she has no doubt acquired
-temporarily the odor of the new nest, and by the time that this has worn
-off she will have acquired this odor by association, and become thereby
-a member of another colony.
-
-Numerous stories have been related of cases in which an ant, having
-found food, returns to the nest with as much of it as she can carry, and
-when she comes out again brings with her a number of other ants. This
-has been interpreted to mean that in some mysterious way the ant
-communicates her discovery to her fellow-ants. A simpler explanation is
-probably more correct. The odor of the food, or of the trail, serves as
-a stimulus to other ants, that follow to the place where the first ant
-goes for a new supply of the food. The fact that the first individual
-returns to the supply of food seems to indicate that the ant has memory,
-and this is obviously of advantage to her and to the whole colony.
-
-The peculiar habits of some of the solitary wasps, of stinging the
-caterpillar or other insect which they store up as food for their young,
-is often quoted as a wonderful case of adaptive instinct. The poison
-that is injected into the wound paralyzes the caterpillar, but as a rule
-does not kill it, so that it remains motionless, but in a fresh state to
-serve as food for the young that hatch from the egg of the wasp. A
-careful study of this instinct by Mr. and Mrs. Peckham has shown
-convincingly that the act is not carried out with the precision formerly
-supposed. It had been claimed that the sting is thrust into the
-caterpillar on the lower side, a ventral ganglion being pierced, the
-poison acting with almost instantaneous effect. But it may be questioned
-whether this is really necessary, and whether the same end might not be
-gained, although not quite so instantaneously, if the caterpillar were
-pierced in almost any other part of the body. Can we be seriously asked
-to believe that this instinct has been perfected by the destruction of
-those individuals (or of their descendants) that have not pierced the
-caterpillar in exactly the middle of a segment of the anterior ventral
-surface? It seems to me that the argument proves too much from the
-selectionist’s point of view. If the wasp pierced the caterpillar in the
-middle of its back, we should have passed over the act without comment;
-but since the injection is usually made on the ventral side, and since
-we know that the nervous system lies in this position, it has been
-assumed that the act is carried out in this way, in order that the
-poison may penetrate the nervous system more quickly. Yet a fuller
-knowledge may show that there is really no necessity for such precision.
-
-A curious response is the so-called death-feigning instinct shown by a
-number of animals, especially by certain insects, but even by some
-mammals and birds. Certain insects, if touched, draw in their legs, let
-go their hold, and fall to the ground, if they happen to be on a plant.
-It is not unusual to meet with the statement that this habit has been
-acquired because it is useful to the insect, since it may often escape
-in this way from an enemy. This does not appear on closer examination to
-be always the case, and sometimes as much harm as good may result, or
-what is more probable, neither much advantage, nor disadvantage, is the
-outcome. This can, of course, only be determined in each particular case
-from a knowledge of the whole life of a species and of the enemies that
-are likely to injure it.
-
-Hudson has recorded[33] a number of cases of this death-feigning
-instinct in higher animals, and attributes it to violent emotion, or
-fear, that produces a sort of swoon. He describes the gaucho boys’
-method, in La Plata, of catching the silver-bill by throwing a stick or
-a stone at it, and then rushing toward the bird, “when it sits perfectly
-still, disabled by fear, and allows itself to be taken.” He also states
-that one of the foxes (_Canis azaræ_) and one of the opossums
-(_Didelphys azaræ_) “are strangely subject to the death-simulating
-swoon.”
-
-Footnote 33:
-
-  “The Naturalist in La Plata.”
-
-Hudson remarks that it seems strange that animals so well prepared to
-defend themselves should possess this “safeguard.” When caught or run
-down by dogs, the fox fights savagely at first, but after a time its
-efforts stop, it relaxes, and it drops to the ground. The animal appears
-dead, and Hudson states that the dogs are “constantly taken in by it.”
-He has seen the gauchos try the most barbarous tricks on a captive fox
-in this condition, and, despite the mutilations to which it was
-subjected, it did not wince. If, however, the observer draws a little
-away from the animal, “a slight opening of the eye may be detected, and
-finally, when left to himself, he does not recover and start up like an
-animal that has been stunned, but cautiously raises his head at first
-and only gets up when his foes are at a safe distance.” Hudson, coming
-once suddenly upon a young fox, saw it swoon at his approach, and
-although it was lashed with a whip it did not move.
-
-The common partridge of the pampas of La Plata (_Hothura maculosa_)
-shows this death-feigning instinct in a very marked degree. “When
-captured, after a few violent struggles to escape, it drops its head,
-gasps two or three times, and to all appearance dies.” But if it is
-released it is off in an instant. The animal is excessively timid, and
-if frightened, may actually die simply from terror. If they are chased,
-and can find no thicket or burrow into which to escape, “they actually
-drop down dead on the plain. Probably when they feign death in their
-captor’s hand they are in reality very near to death.”
-
-In this latter instance it must appear very improbable that we are
-dealing with an instinct that has been built up by slow degrees on
-account of the benefit accruing at each stage to the individual. In
-fact, it appears that the instinct is in this case of really no use at
-all to the animal, for there can scarcely be any question of an escape
-by this action. Yet so far as we can judge it is the same instinct shown
-by other animals, and it is not logical to account for its origin in one
-case on the grounds of its usefulness, when we cannot apply the
-explanation in the other cases. If this be admitted, we have another
-illustration of the importance of keeping apart the origin of an
-instinct or of a structure and the fact of its usefulness or
-non-usefulness to the organism. Thus under certain conditions this
-death-feigning instinct might really be of use to the animal, while
-under other conditions and in other animals it may be of no advantage at
-all, and in still other conditions it may be a positive injury to its
-possessor. Perhaps we need not go outside of our own experience to find
-a parallel case, for the state of fright into which imminent danger may
-throw an individual may deprive him for the moment of the proper use of
-those very mental qualities of which he stands in this crisis in
-greatest need.
-
-The peculiar behavior of cattle caused by the smell of blood is another
-case of an instinct whose usefulness to its possessors is far from
-apparent. It is known that cattle and horses and several wild animals
-become violently excited by the smell of blood. Hudson gives a vivid
-account of a scene witnessed by himself, the animals congregating, “and
-moving around in a dense mass, bellowing continually.” Those animals
-that forced their way into the centre of the mass where the blood was
-“pawed the earth and dug it up with their horns, and trampled each other
-down in their frantic excitement.”
-
-This action leads us to a consideration of the behavior of animals
-toward companions in distress. “Herbivorous animals at such times will
-trample and gore the distressed one to death. In the case of wolves and
-other savage-tempered carnivorous species the distressed fellow is
-frequently torn to pieces and devoured on the spot.” If any one will be
-bold enough to claim in this case that this habit has been acquired
-because of advantage to the pack, _i.e._ if it be imagined that the pack
-gains more by feeding on a weak member than by letting him take his
-chances of recovery, it may be pointed out in reply that cattle also
-destroy their weak or injured, but do not devour them, and the same
-statement holds for birds, where the same instinct has often been
-observed. Romanes has suggested that the instinct of destroying the weak
-or injured members is of use because such members are a source of danger
-to the rest of the herd; but Hudson points out that it is not so much
-the weak and sickly members of the herd that are attacked in this way,
-as those that are injured, and concludes, “the instinct is not only
-useless, but actually detrimental.” He suggests that these “wild
-abnormal movements of social animals” are a sort of aberration, so “that
-in turning against a distressed fellow they oppose themselves to the law
-of being.” Yet whether we gain anything by calling this action aberrant
-or abnormal, the important fact remains that it is a definite response
-under certain external conditions, and is shown by all the individuals
-of the species.
-
-The preceding illustrations of reactions that go to make up the
-so-called instincts of animals may be separated into those that are
-essential to the life of the individual or of the race, those that are
-of some apparent use, although not absolutely essential, and a few of no
-use at all, and fewer still that appear to be even injurious. If the
-latter reactions take place only rarely, as appears often to be the
-case, they are not sufficiently harmful to cause the destruction of the
-race. The evidence points to the conclusion, I believe, that the origin
-of these tropisms and instincts cannot be accounted for on the ground of
-their benefit to the individual or to the race; and it does not seem
-reasonable to make up one explanation for the origin of those that are
-essential, and another for those that are of little use or even of no
-use at all.
-
-From what has been already said more than once, while discussing each
-particular case, the simplest course appears to be in all instances to
-look upon these instincts as having appeared independently of the use to
-which they may be put, and not as having been built up by selection of
-the individual variations that happen to give an organism some advantage
-over its fellows in a life and death struggle. It appears reasonable to
-deal with the origin of tropisms and instincts in general in the same
-way as in dealing with structures; for, after all, the tropism is only
-the outcome of some material or structural basis in the organism.
-
-No attempt has been made here to interpret the more complex reactions of
-the nervous system, for until we can get some insight into the meaning
-of the simpler processes, we are on safer ground in dealing with these
-first.
-
-
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-
-
-
-
-                              CHAPTER XII
-
-                          SEX AS AN ADAPTATION
-
-
-In what sense may the separation of all the individuals of a species
-into two kinds of individuals, male and female, be called an adaptation?
-Does any advantage result to the species that would not come from a
-non-sexual method of reproduction? Many attempts have been made to
-answer these questions, but with what success I shall now try to show.
-
-There are four principal questions that must be considered:—
-
-I. The different kinds of sexual individuals in the animal and plant
-kingdoms.
-
-II. The historical question as to the evolution of separate sexes.
-
-III. The factors that determine the sex in each individual developing
-from an egg.
-
-IV. The question as to whether any advantage is gained by having each
-new individual produced by the union of two germ-cells, or by having the
-germ-cells carried by two kinds of individuals.
-
-While our main problem is concerned with the last of these topics, yet
-there would be little hope of giving a complete answer to it unless we
-could get some answer to the first three questions.
-
-
-               The Different Kinds of Sexual Individuals
-
-Amongst the unicellular animals and plants the fusion of two (or more)
-individuals into a single one is generally regarded as the simplest, and
-possibly also the most primitive, method of sexual reproduction. Two
-amœbas, or amœba-like bodies, thus flow together, as it were, to produce
-a new individual.
-
-In the more highly specialized unicellular animals, the processes are
-different. Thus in vorticella, a small, active individual unites with a
-larger fixed individual. The protoplasm fuses into a common mass, and a
-very complicated series of changes is passed through by the nucleus. In
-paramœcium, a free-swimming form very much like vorticella, two
-individuals that are alike unite only temporarily, and after an
-interchange of nuclear material they separate.
-
-In the lower plants, and more especially in some of the simple
-aggregates or colonial forms, there are found a number of stages between
-species in which the uniting individuals are alike, and those in which
-they are different. There are several species whose individuals appear
-to be exactly alike; and other species in which the only apparent
-difference between the individuals that fuse together is one of size;
-and still other species in which there are larger resting or passive
-individuals, and smaller active individuals that unite with the larger
-ones. In several of the higher groups, including the green algæ and
-seaweeds, we find similar series, which give evidence of having arisen
-independently of each other. If we are really justified in arranging the
-members of these groups in series, beginning with the simpler cases and
-ending with those showing a complete differentiation into two kinds of
-germ-cells, we seem to get some light as to the way in which the change
-has come about. It should not be forgotten, however, that it does not
-follow because we can arrange such a series without any large gaps in
-its continuity, that the more complex conditions have been gradually
-formed in exactly this way from the simplest conditions.
-
-So far we have spoken mainly of those cases in which the forms are
-unicellular, or of many-celled species in which all the cells of the
-individual resolve themselves into one or the other kind of germ-cells.
-This occurs, however, only in the lowest forms. A step higher we find
-that only a part of the cells of the colony are set aside for purposes
-of reproduction. The cells surrounding these germ-cells may form
-distinct organs, which may show certain differences according to whether
-they contain male or female germ-cells. When these two kinds of cells
-are produced by two separate individuals, the individuals themselves may
-be different in other parts of the body, as well as in the reproductive
-organs.
-
-When this condition is reached, we have individuals that we call males
-and females, because, although they do not themselves unite to form new
-individuals, they produce one or the other kind of germ-cell. It is the
-germ-cells alone that now combine to form the new individual.
-
-Amongst living groups of animals we find no such complete series of
-forms as exist in plants, and the transition from the one-celled to the
-many-celled forms is also more abrupt. On the other hand, we find an
-astonishing variety of ways in which the reproduction is accomplished,
-and several ways in which the germ-cells are carried by the sexual
-individuals. Let us examine some of the more typical conditions under
-the following headings: (1) sexes separate; (2) sexes united in the same
-individual; (3) parthenogenetic forms; (4) exceptional methods of
-propagation.
-
-1. _Sexes Separate; Unisexual Forms._[34]—Although the animals with
-which we are more familiar have the sexes separate, this is far from
-being universal amongst animals and plants; and, in fact, can scarcely
-be said to be even the rule. When the sexes are separate they may be
-externally alike, and this is especially true for those species that do
-not unite, but set free their eggs and spermatozoa in the water, as
-fish, frogs, corals, starfish, jellyfish, and many other forms. In other
-animals there are sometimes other secondary differences in the sexes
-besides those connected with the organs of reproduction. Such
-differences are found, as we have seen, in insects, in some spiders,
-crustaceans, and in many birds and mammals. In a few cases the
-difference between the sexes is very great, especially when the female
-is parasitic and the male free, as in some of the crustaceans. In some
-other cases the male is parasitic on the female. Thus in Bonellia the
-male is microscopic in size, being in length only one-hundredth part of
-the female. In _Hydatina senta_ the male is only about a third as large
-as the female. It has no digestive tract, and lives only a few days. In
-another rotifer the males are mere sacs enclosing the male reproductive
-organs.
-
-Footnote 34:
-
-  Geddes and Thompson’s “The Evolution of Sex” has been freely used in
-  the preparation of this part of this chapter.
-
-2. _Hermaphroditic Forms._—There are many species of animals and plants
-in which each individual contains both the male and the female organs of
-reproduction, and there are whole groups in which only these
-hermaphroditic forms occur. Thus in the ctenophors the eggs develop
-along one side of each radial canal and spermatozoa along the other. The
-group of flatworms is almost exclusively hermaphroditic. The earthworms
-and the leeches have only these bisexual forms, and in the mollusks,
-while a few groups have separate sexes, yet certain groups of
-gasteropods and of bivalve forms are entirely hermaphroditic.
-
-In the common garden snail, although there are two sets of sexual ducts
-closely united, yet from the same reproductive sac both eggs and sperm
-are produced. The barnacles and the ascidians are for the most part
-hermaphroditic forms. Many other examples might be cited, but these will
-suffice to show that it is by no means unusual in the animal kingdom for
-the same individual to produce both male and female germ-cells. However,
-one of the most striking facts in this connection is that
-self-fertilization seldom takes place, so that the result is the same in
-certain respects as though separate sexes existed. This point will come
-up later for further consideration.
-
-3. _Parthenogenetic Reproduction._—It has long been known that, in some
-cases, eggs that are not fertilized will begin to develop and may even
-produce new individuals. Tichomiroff showed that by rubbing with a brush
-the unfertilized eggs of the silkworm moth, a larger percentage would
-produce caterpillars than if they were not rubbed. During the last few
-years it has been shown that the development of a non-fertilized egg may
-be started in a number of ways. Such, for example, as by certain
-solutions of salt or of sugar, by subjecting the eggs to cold, or by
-simply shaking them.
-
-There are certain groups of animals in which the males appear only at
-regular (in others at irregular) intervals. In their absence the females
-produce eggs that develop without being fertilized, _i.e._
-parthenogenetically. The following examples will serve to show some of
-the principal ways in which this “virgin reproduction” takes place. In
-the group of rotifers the males are generally smaller than the females
-and are usually also degenerate. In some species, although degenerate
-males are present, they are unnecessary, since parthenogenesis is the
-rule. In still other species no males exist and the eggs develop,
-therefore, without being fertilized. In some of the lower crustaceans
-parthenogenesis occurs in varying degrees. In Apus males may be entirely
-absent at times in certain localities, and at other times a few, or even
-very many, males may appear. Some species of ostracod crustaceans seem
-to be purely parthenogenetic; others reproduce by means of fertilized
-eggs; and others by an alternation of the two processes. The crustaceans
-of the genus _Daphnia_ produce two kinds of eggs. The summer eggs are
-small, and have a thin shell. These eggs develop without being
-fertilized, but in the autumn both male and female individuals develop
-from these unfertilized eggs, and the eggs of the female, the so-called
-winter eggs, are fertilized. These are also larger than the summer eggs,
-have thicker shells, and are much more resistant to unfavorable
-conditions. They give rise in the following spring to females only, and
-these are the parthenogenetic individuals that continue to produce
-during the summer new parthenogenetic eggs.
-
-It is within the group of insects that some of the most remarkable cases
-of parthenogenesis that we know are found. In the moth, _Psyche helix_,
-only females are present, as a rule, but rarely males have been found.
-In another moth, _Solenobia trinquetrella_, the female reproduces by
-parthenogenesis, but at times males appear and may then be even more
-numerous than the females. In the gall-wasps parthenogenetic generations
-may alternate with a sexual generation, and it is interesting to note
-that the sexual and the parthenogenetic generations are so different
-that they were supposed to belong to separate species, until it was
-found that they were only alternate generations of the same species.
-
-The aphids or plant-lice reproduce during the summer by parthenogenesis,
-but in the autumn winged males and females appear, and fertilized winter
-eggs are produced. From these eggs there develop, in the following
-spring, the wingless parthenogenetic summer forms, which produce the
-successive generations of the wingless forms. As many as fourteen summer
-broods may be produced. By keeping the aphids in a warm temperature and
-supplying them with plenty of moist food, it has been possible to
-continue the parthenogenetic reproduction of the wingless forms for
-years. As many as fifty successive broods have been produced in this
-way. It has not been entirely determined whether it is the temperature
-or a change in the amount, or kind, of food that causes the appearance
-of the winged males and females, although it seems fairly certain that
-diminution in the food, or in the amount of water contained in it, is
-the chief cause of the change.
-
-In the honey-bee the remarkable fact has been well established that
-fertilized eggs give rise only to females (queens and workers), while
-unfertilized eggs develop into males. Whether a fertilized egg becomes a
-queen or a worker (sterile female) depends solely on the kind of food
-that is given to the young larva, and this is determined, in a sense,
-entirely by the bees themselves.
-
-In plants also there are many cases of parthenogenesis known. Some
-species of Chara when kept under certain conditions produce only female
-organs, and seem to produce new plants parthenogenetically. In this case
-it appears that the same conditions that caused the plants to produce
-only female organs may also lead to the development of the egg-cells
-without fertilization. In fact it is only by a combination of this kind
-that parthenogenesis could arise. The result is similar when the eggs of
-insects produce only females whose eggs are capable of parthenogenetic
-development. If a case should arise in which only females appeared whose
-eggs did not possess the power of parthenogenetic development, the
-species would die out.
-
-In the green alga, Spirogyra, it has been found that if conjugation of
-two cells is prevented, a single cell may become a parthenogenetic cell.
-In a number of parasitic fungi the male organs appear to be degenerate,
-and from the female organs parthenogenetic development takes place. A
-small number of flowering plants are also capable of parthenogenetic
-reproduction.
-
-There is a peculiarity in the development of the parthenogenetic eggs of
-animals that will be more fully discussed later, but may be mentioned
-here. Ordinarily an egg that becomes fertilized gives off two polar
-bodies, but in a number of cases in which parthenogenetic development
-occurs it has been found that only one polar body is given off. It is
-supposed that in such cases one polar body is retained, and that it
-plays the same part as the entrance of the spermatozoon of the male.
-
-4. _Exceptional Cases._—Occasionally in a species that is unisexual an
-individual is found that is bisexual. The male of the toad, _Pelobates
-fuscus_, has frequently a rudimentary ovary in front of the testis. The
-same thing has been found in several species of fish. In Serranus, a
-testis is present in the wall of the ovary, and the eggs are said to be
-fertilized by the spermatozoa of the same individual. In frogs it has
-been occasionally found that ovary and testis may be associated in the
-same individual, or a testis may be present on one side, and a testis
-with an anterior ovarian portion on the other. Cases like these lead up
-to those in which the body itself may also show a mosaic of
-sex-characters, and it is noticeable that when this occurs there is
-nearly always a change in the reproductive organs also. Thus butterflies
-have been found with the wings and the body of one side colored like the
-male and the other side like the female. Similar cases have also been
-found in bees and ants. Bees have been found with the anterior part of
-the body of one sex and posterior part of another!
-
-The preceding cases illustrate, in different ways, the fact that in the
-same individual both kinds of reproductive organs may suddenly appear,
-although it is the rule in such species that only one set develops.
-Conversely, there are cases known, especially amongst plants, in which
-individuals, that usually produce male and female organs (or more
-strictly spores of two kinds from which these organs develop), produce
-under special conditions only one or the other kind. Facts like these
-have led to the belief that each individual is potentially bisexual, but
-in all unisexual forms one sex predominates, and the other remains
-latent. This idea has been the starting-point for nearly all modern
-theories of sex.
-
-An excellent illustration of this theory is found in those cases in
-which the same individual may be male at one time and female at another.
-For instance, it is said that in one of the species of starfish
-(_Asterina gibbosa_) the individuals at Roscoff are males for one or two
-years, and then become females. At Banyuls they are males for the first
-two or three years, and then become females; while at Naples some are
-always males, others females, some hermaphrodites, others transitional
-as in the cases just given. In one of the isopod crustaceans,
-_Angiostomum_, the young individuals are males and the older females. In
-_Myzostomum glabrum_ the young animal is at first hermaphroditic, then
-there is a functional male condition, followed by a hermaphroditic
-condition, and finally a functional female phase, during which the male
-reproductive organs disappear.
-
-The flowers of most of the flowering plants have both stamens and
-pistils, which contain the two kinds of spores out of which the male and
-female germ-cells are formed. The stamens become mature before the
-pistils, as a rule, but in some cases the reverse is the case. This
-difference in the time of ripening of the two organs is often spoken of
-as an adaptation which prevents self-fertilization. The latter is
-supposed to be less advantageous than cross-fertilization. This question
-will be more fully considered later.
-
-Before we come to an examination of the question of the adaptations
-involved in the cases in which the sexes are separate, and the different
-times at which the sex-cells are ripened, it will be profitable first to
-examine the question as to what determines in the egg or young whether a
-male or a female or a hermaphroditic form shall arise.
-
-
-                        The Determination of Sex
-
-A large number of views have been advanced as to what determines whether
-an egg will give rise to a male or to a female individual. The central
-question is whether the fertilized egg has its sex already determined,
-or whether it is indifferent; and if the latter, what external factor or
-factors determine the sex of the embryo. Let us first examine the view
-that some external factor determines the sex of the individual, and then
-the evidence pointing in the opposite direction. Among the different
-causes suggested as determining the sex of the embryo, that of the
-condition of the egg itself at the time of fertilization has been
-imagined to be an important factor in the result. Another similar view
-holds that the condition of the spermatozoon plays the same rôle. For
-instance, it has been suggested that if the egg is fertilized soon after
-it leaves the ovary, it produces a female, but if the fertilization is
-delayed, a male is produced. It has also been suggested that the
-relative age of the male and the female parents produces an effect in
-determining the sex of the young. There is no satisfactory evidence,
-however, showing that this is really the case.
-
-Another view suggested is that the sex is determined by the more
-vigorous parent; but again there is no proof that this is the case, and
-it would be a difficult point to establish, since as Geddes and Thompson
-point out, what is meant by greater vigor is capable of many
-interpretations. Somewhat similar is the idea that if the conditions are
-favorable, the embryo develops further, as it were, and becomes a male;
-but there are several facts indicating that this view is untenable.
-
-Düsing maintains that several of these factors may play a part in
-determining the sex of the embryo, and if this be true, the problem
-becomes a very complex one. He also suggests that there are
-self-regulative influences of such a kind that, when one sex becomes
-less numerous, the conditions imposed in consequence on the other sex
-are such as to bring the number back to the normal condition; but this
-idea is far from being established. The fact that in some species there
-are generally more individuals of one sex than of the other shows that
-this balance is not equally adjusted in such forms.
-
-Of far greater value than these speculations as to the origin of sex are
-the experiments that appear to show that nutrition is an important
-factor in determining sex. Some of the earlier experiments in this
-direction are those of Born and of Yung. By feeding one set of tadpoles
-with beef, Yung found the percentage of females that developed to be
-greatly increased, and a similar increase was observed when the tadpoles
-were fed on the flesh of fish. An even greater effect was produced by
-using the flesh of frogs, the percentage rising to 92 females in every
-hundred. These results have been given a different interpretation by
-Pflüger and by others, and, as will be pointed out later, there is a
-possible source of error that may invalidate them.
-
-Somewhat similar results have been obtained by Nussbaum for one of the
-rotifers. He found that if the rotifer is abundantly fed in early life,
-it produces _female eggs_, that is, larger eggs that become females;
-while if sparingly fed, it produces only small eggs, from which males
-develop. It has been claimed also in mammals, and even in man, that sex
-is to some extent determined by the nourishment of the individual.
-
-Some experiments made by Mrs. Treat with caterpillars seemed to show
-that if the caterpillars were well nourished more female moths were
-produced, and if starved before pupation more males emerged. But Riley
-has pointed out that since the larger female caterpillars require more
-food they will starve sooner than the males, and, in consequence, it may
-appear that proportionately more male butterflies are born when the
-caterpillars are subjected to a starvation diet. This point of view is
-important in putting us on our guard against hastily supposing that food
-may directly determine sex. Unless the entire number of individuals
-present at the beginning of the experiment is taken into account, the
-results may be misleading, because the conditions may be more fatal to
-one sex than to the other.
-
-In some of the hymenopterous insects, the bees for example, it has been
-discovered that the sex of the embryo is determined by the entrance, or
-lack of entrance, of the spermatozoon. In the honey-bee all the
-fertilized eggs produce females and the unfertilized eggs males. The
-same relation is probably true also in the case of ants and of wasps. In
-the saw-flies, the conditions are very remarkable. Sharp gives the
-following account of some of these forms:[35]—“It is a rule in this
-family that males are very much less numerous than females, and there
-are some species in which no males have been discovered. This would not
-be of itself evidence of the occurrence of parthenogenesis, but this has
-been placed beyond doubt by taking females bred in confinement,
-obtaining unfertilized eggs from them, and rearing the larvæ produced
-from the eggs. This has been done by numerous observers with curious
-results. In many cases the parthenogenetic progeny, or a portion of it,
-dies without attaining full maturity. This may or may not be due to
-constitutional weakness, arising from the parthenogenetic state.
-Cameron, who has made extensive observations on this subject, thinks
-that the parthenogenesis does involve constitutional weakness, fewer of
-the parthenogenetic young reaching maturity. This, he suggests, may be
-compensated for—when the parthenogenetic progeny is all of the female
-sex—by the fact that all those that grow up are producers of eggs. In
-many cases the parthenogenetic young of Tenthredinidæ are of the male
-sex, and sometimes the abnormal progeny is of both sexes. In the case of
-one species—the common currant-fly, _Nematus ribesii_—the
-parthenogenetic progeny is nearly, but not quite always, entirely of the
-male sex; this has been ascertained again and again, and it is
-impossible to suggest in these cases any advantage to the species to
-compensate for constitutional parthenogenetic weakness. On the whole, it
-appears most probable that the parthenogenesis, and the special sex
-produced by it, whether male or female, are due to physiological
-conditions of which we know little, and that the species continues in
-spite of the parthenogenesis rather than profits by it. It is worthy of
-remark that one of the species in which parthenogenesis with the
-production of males occurs—_Nematus ribesii_—is perhaps the most
-abundant of saw-flies.”
-
-Footnote 35:
-
-  “The Cambridge Natural History,” Vol. V, “Insects,” by David Sharp.
-
-It has been pointed out that in a number of species of animals and
-plants only parthenogenetic females are present at certain times. In a
-sense this means a preponderance of one sex, but since the eggs are
-adapted only to this kind of development, it may be claimed that the
-conditions in such cases are somewhat different from those in which eggs
-that would be normally fertilized may develop in the absence of
-fertilization. Nevertheless, it is generally supposed that the actual
-state of affairs is about the same. It is usually assumed, and no doubt
-with much probability, that these parthenogenetic forms have evolved
-from a group which originally had both male and female forms. One of the
-most striking facts in this connection is that in the groups to which
-these parthenogenetic species belong there are, as a rule, other species
-with occasional parthenogenesis, and in some of these the males are also
-fewer in number than the females.
-
-In the aphids, the parthenogenetic eggs give rise during the summer to
-parthenogenetic females, but in the autumn the parthenogenetic eggs give
-rise without fertilization both to males and to females. It appears,
-therefore, that we can form no general rule as to a relation between
-fertilization and the determination of sex. While in certain cases, as
-in the bees, there appears to be a direct connection between these two,
-in other cases, as in that of the aphids just mentioned, there is no
-such relation apparent.
-
-Geddes and Thompson have advocated a view in regard to sex which at best
-can only serve as a sort of analogy under which the two forms of sex may
-be considered, rather than as a legitimate explanation of the phenomenon
-of sex. They rest their view on the idea that living material is
-continually breaking down and building up. An animal in which there is
-an excess of the breaking-down process is a male, and one that is more
-constructive is a female. Furthermore, whichever process is in the
-excess during development determines the sex of the individual. Thus, if
-conditions are very favorable, there will be more females produced; but
-if, on the other hand, there is an excess of the breaking-down process,
-males are produced. So far, the process is conceived as a purely
-physiological one, but to this the authors then apply the selection
-hypothesis, which, they suppose, acts as a sort of break or regulation
-of the physiological processes, or in other words as a directive agent.
-They state: “Yet the sexual dimorphism, in the main, and in detail, has
-an adaptive significance, also securing the advantages of
-cross-fertilization and the like, and is, therefore, to some extent the
-result of the continual action of natural selection, though this may, of
-course, check variation in one form as well as favor it in another.”
-Disregarding this last addition, with which Geddes and Thompson think it
-necessary to burden their theory, let us return to the physiological
-side of the hypothesis. Their idea appears to me a sort of symbolism
-rather than a scientific attempt to explain sex. If their view had a
-real value, it ought to be possible to determine the sex of the
-developing organism with precision by regulating the conditions of its
-growth, and yet we cannot do this, nor do the authors make any claim of
-being able to do so. The hypothesis lacks the only support that can give
-it scientific standing, the proof of experiment.
-
-There have been made, from time to time, a number of attempts to show
-that the sex of the embryo is predetermined in the egg, and is not
-determined later by external circumstances. In recent years this view
-has come more to the front, despite the apparent experimental evidence
-which seemed in one or two cases to point to the opposite view. One of
-the most complete analyses of the question is that of Cuénot, who has
-attempted to show that the sex of the embryo is determined in the egg,
-before or at the time of fertilization. He has also examined critically
-the evidence that appeared to show that external conditions, acting on
-the embryo, may determine the sex, and has pointed out some possible
-sources of error that had been overlooked. The best-known case is that
-of the tadpole of the frog, but Cuénot shows not only that there are
-chances of error in this experiment as carried out, but also, by his own
-experiments and observations, that the facts themselves are not above
-suspicion. He points out that at the age at which some of the tadpoles
-were when the examination was made, it was not always possible to tell
-definitely the sex of the individual, and least of all by means of the
-size alone of the reproductive organs, as was supposed, in one case at
-least, to be sufficient. In his own experiments he did not find an
-excess of one sex over the other as a result of feeding.
-
-Cuénot points out that Brocadello found that the larger eggs laid by the
-silkworm give rise to from 88 to 95 per cent of females, and the small
-eggs to from 88 to 92 per cent of males. Joseph has confirmed this for
-_Ocneria dispar_, and Cuénot himself also reached this conclusion.
-Korschelt found that the large eggs of Dinophilus produced females and
-the small ones males. Cuénot experimented with three species of flies,
-and found that when the maggots were well nourished the number of the
-individuals of the two sexes was about equal, and when poorly nourished
-there were a few more females in two cases, and in another about the
-same number of males and females.
-
-It has been claimed that the condition of nourishment of the mother may
-determine the number of eggs of a particular sex, but Cuénot found, in
-three species of flies which he raised, that there was a slight response
-in the opposite direction. He concludes that the condition of the mother
-is not a factor in the determination of sex.
-
-The first egg of the two laid in each set by the pigeon is said, as a
-rule, to produce a male, and the second a female. Both Flourens and
-Cuénot found this to be the case in the few instances that they
-examined, but Cuénot has shown that this does not always happen. Even
-when this occurs, it has not been determined whether the result depends
-on something in the egg itself, that causes a male egg to be set free
-first, or on some external condition that determines that the first egg
-shall become a male. It has been claimed that the age of the
-spermatozoon might in this and in other cases determine the result; but
-Gerbe has shown that if the domestic hen is isolated for fifteen days
-after union with the male, she will continue to produce fertile eggs
-from which both sexes are produced, without showing any relation between
-the time the eggs are laid and the particular sex that develops.
-
-Cuénot does not discuss whether sex is determined by the nucleus or by
-the protoplasm, but if, as he thinks probable, the size of the egg is a
-determining factor, it would appear that the protoplasm must be the
-chief agent. Even if this were the case it would still be possible that
-the size of the egg itself might be connected with some action on the
-part of the nucleus. If, as seems probable, identical twins come from
-halves of the same egg, then, since they are of the same sex, the
-absolute amount of protoplasm cannot be a factor in sex determination.
-
-
-[Illustration:
-
-  Fig. 6.—Diagram showing the maturation of the egg.]
-
-As a basis for the discussion that follows, certain processes that take
-place during the maturation divisions of the egg and of the spermatozoon
-must be briefly noticed. After the egg leaves the ovary it extrudes a
-minute body called the first polar body (Fig. 6 B, C, D). This process
-of extrusion is really a cell division accompanied by the regular
-mitotic division of the nucleus; but since one of the products of the
-division, the polar body, is extremely small, the meaning of the process
-was not at first understood. The half of the nucleus, that remains in
-the egg, divides again, and one of its halves is thrown out into a
-second polar body (Fig. 6 E, F, G)). Meanwhile, the first polar body has
-divided into two equal parts, so that we find now three polar bodies and
-the egg (Fig. 6 G)). A strictly analogous process takes place in the
-formation of the spermatozoa (Fig. 7 B-F). The mother-cell of the
-spermatozoon divides into two parts, which are equal in this case (Fig.
-7 B-D). Each of these then divides again (Fig. 7 E, F), producing four
-cells that are comparable to the three polar bodies and the mature egg.
-Each of the four becomes a functional spermatozoon (Fig. 7 G, H). Thus
-while in the maturation of the egg only the egg itself is capable of
-development, in the case of the male cells all four products of the two
-maturation divisions are functional.
-
-
-[Illustration:
-
-  Fig. 7.—Diagram showing the maturation of the spermatozoon.]
-
-
-Now, in certain cases of parthenogenesis, it has been found that one of
-the polar bodies may not be given off, but, remaining in the egg, its
-nucleus reunites with the egg nucleus, and thus takes the place of the
-spermatozoon, which does exactly the same thing when it fertilizes the
-egg, _i.e._ the nucleus of the spermatozoon unites with the nucleus of
-the egg. This fact in regard to the action of the polar body in
-fertilization is not as surprising as appears at first sight, for if
-each of the polar bodies is equivalent to a spermatozoon, the
-fertilization of the egg by one of its own polar bodies conforms to
-theory.
-
-There is a considerable body of evidence showing that in many eggs at
-one of the two maturation divisions the chromatin rods derived from the
-nucleus are divided crosswise (Fig. 6 B, C). The same thing occurs at
-one of the two divisions in the formation of the spermatozoon (Fig. 7 B,
-C). At the other division to form the other polar body (or the other
-sperm-cell) the chromatin rods appear to be split lengthwise, as in
-ordinary cell division (Fig. 6 E, F, G). In recent years the
-_cross-division_ of the chromatin rods has attracted a great deal of
-notice, and Weismann in particular drew attention to the possible
-importance of this kind of division.
-
-There is another fact that gives this division especial significance. It
-has been discovered that the number of chromosomes that appears in each
-dividing cell of the organism is a constant number, but it has also been
-discovered that the egg, before extruding its polar bodies, and the
-mother-cell of the spermatozoon (Figs. 6, 7 B), contain exactly half of
-the number of chromosomes that are characteristic of the body-cells of
-the same animal (Figs. 6, 7 A). Now there is good evidence to show that
-the reduction in number is due to the chromosomes uniting sometimes end
-to end in pairs, as shown in Figures A and B. Furthermore, it has been
-suggested that at one of the maturation divisions, when the chromosomes
-divide crosswise, the united chromosomes are separated (Figs. 6, 7 B,
-C), so that one remains in the egg and the other goes out into the polar
-body. The same thing is supposed to occur at one of the maturation
-divisions of the sperm mother-cell. A further consideration of capital
-importance in this connection has been advocated by Montgomery and by
-Sutton, namely, that, when the chromosomes unite in pairs, a chromosome
-from one parent unites with one from the other parent. Consequently at
-one of the two reduction divisions maternal and paternal chromosomes may
-separate again, some to go to one cell, some to the other.
-
-When the spermatozoon enters the egg it brings into the egg as many new
-chromosomes as the egg itself possesses at this time, and the two
-nuclei, uniting into a single one, furnish the total number of
-chromosomes characteristic of the animal that develops from the egg. At
-first the chromosomes that are brought in by the spermatozoon lie at one
-side of the fused nucleus, and those from the egg itself at the other
-side. This arrangement appears, however, in some cases at least, to be
-lost later. At every division of the nucleus, each chromosome divides
-and sends a half to each of the daughter-nuclei. Thus every cell in the
-body contains as many paternal as maternal chromosomes. This statement
-also applies to the first cells that go into the reproductive organs,
-some of which become the mother-cells of the germ-cells. Later, however,
-in the history of the germ-cells,—just before the maturation
-divisions,—these chromosomes are supposed to unite in pairs, end to end,
-as explained above, to give the reduced number. Later there follows the
-separation of these paired chromosomes at one of the two maturation
-divisions. If at this time all the paternal chromosomes should pass to
-one pole, and all the maternal to the other, the germ-cell ceases to be
-mixed, and becomes purely paternal or maternal. If this ever occurs, the
-problem of heredity may become simplified, and even the question of sex
-may be indirectly involved; but it has not been established that, when
-the reduced number of chromosomes is formed, there is a strict union
-between the paternal and maternal chromosomes, and if not, the
-subsequent separation is probably not along these lines. If, however,
-the chromosomes contain different qualities, as Boveri believes, there
-may be two kinds of eggs, and two kinds of spermatozoa in regard to
-_each particular character_. It is this last assumption only that is
-made in Mendel’s theory of the purity of the germ-cells.
-
-Several attempts have been made at different times to connect the facts
-in regard to the extrusion of the polar bodies with those involved in
-the determination of sex. Minot suggested, in 1877, that the egg ejects
-by means of the polar bodies its male elements, which are again received
-in the fertilization of the egg by the spermatozoon. The same idea has
-also been expressed by others. It has been objected to this view that
-one polar body ought to suffice, and that no similar throwing out of
-part of its substance is found in the process of formation of the
-spermatozoon, which should, on the hypothesis, throw out its female
-elements. It would seem, on first thought, that this view might find
-support in the idea expressed above, namely, that in one of the polar
-bodies half of the chromosomes pass out, so that there is conceivably a
-separation of the maternal from the paternal. If this were the case also
-in the spermatozoa, then two of each four would be paternal and two
-maternal. This is, however, a very different thing from supposing them
-to be male and female, for it by no means follows, because the
-chromosomes correspond to those of the father or of the mother in the
-sum of their characters, that they are, therefore, also male or female
-in regard to sex.
-
-It has been pointed out already, that in most parthenogenetic eggs only
-one polar body is extruded. There are, it is true, a few apparent
-exceptions to this rule, but in most cases it is certain that only one
-is extruded. In several cases the beginning of the formation of the
-second maturation division of the nucleus takes place, but after the
-chromosomes have divided they come together again in the nucleus. If
-each polar body be interpreted as equivalent to a spermatozoon, then
-this result is rather a process of self-fertilization than true
-parthenogenesis. It is, nevertheless, true that in some cases
-development seems to go on after both polar bodies have been extruded.
-Moreover, it has been found possible to cause the eggs of the sea-urchin
-to begin their development by artificial solutions after they have
-extruded both polar bodies. A single spermatozoon may also produce an
-embryo if it enters a piece of egg-protoplasm without a nucleus. The
-last instance is a case of male parthenogenesis, and if the theory of
-the equivalency of spermatozoon and egg be correct, this is what should
-occur.
-
-Quite recently, Cuénot, Beard, Castle, and Lenhossek have contended that
-the differentiation of sex is the outcome of internal factors. They
-think that the view that sex is determined by external agents is
-fundamentally erroneous. The fallacies that have given rise to this
-conception, Castle points out, are, first, that in animals that
-reproduce sometimes by parthenogenesis and sometimes by fertilized eggs,
-the former process is favored by good nutrition and the latter by poor
-nutrition. This only means, in reality, Castle thinks, that
-parthenogenetic reproduction is favored by external conditions, and this
-kind of reproduction, he thinks, is a thing _sui generis_, and not to be
-compared to the formation of more females in the sexual forms of
-reproduction. There is no proof, however, that this is anything more
-than a superficial distinction, and it ignores the fact that in ordinary
-cases the females sometimes lay parthenogenetic eggs which differ, as
-far as we can see, from eggs that are destined to be fertilized in no
-important respect. More significant, it seems to me, is the fact that
-only parthenogenetic females develop the following spring from the
-fertilized eggs of the last generation of the autumn series, whose
-origin is described to be due to lack of food. We find, in the case of
-aphids, that unfertilized parthenogenetic eggs and also fertilized eggs
-give rise to females only, while a change in the amount of food causes
-the parthenogenetic eggs to give rise both to males and to females. This
-point is not, I think, fully met by Castle, for even if the change in
-food does not, as he claims, cause only one sex to appear, yet lack of
-food does seem to account for the appearance of the males at least.
-
-The other fallacy, mentioned by Cuénot, is that the excess of males that
-has been observed when the food supply is limited is due to the early
-death of a larger percentage of females, which require more food, but
-this still fails to account for the excess of females when more food is
-given, provided Yung’s experiments on tadpoles are correct. It may be,
-however, in the light of Pflüger’s results, that there has been some
-mistake in the experiments themselves.
-
-We may now proceed to examine Castle’s argument, attempting to show in
-what way sex is predetermined in the embryo. His hypothesis rests on the
-three following premises: “(1) the idea of Darwin, that in animals and
-plants of either sex the characters of the opposite sex are latent; (2)
-the idea of Mendel, that in the formation of the gametes [germ-cells] of
-hybrids a segregation of the parental characters takes place, and when
-in fertilization different segregated characters meet, one will
-dominate, the other become latent or recessive; (3) the idea of
-Weismann, that in the maturation of egg and spermatozoon a segregation
-is attended by a visible reduction in the number of chromosomes in the
-germinal nuclei.”
-
-Expressed in a somewhat more general way, Castle suggests that each egg
-and each spermatozoon is either a male or a female germ-cell (and not a
-mixture of the two), and when a female egg is fertilized by a male
-spermatozoon, or _vice versa_, the individual is a sexual hybrid with
-one sex dominating and the other latent. The assumption that there are
-two kinds of eggs, male and female, and two kinds of spermatozoa, male
-and female, is not supported by any direct or experimental evidence.
-Moreover, in order to carry out the hypothesis, it is necessary to make
-the further assumption that a female egg can only be fertilized by a
-male spermatozoon, and a male egg by a female spermatozoon. While such a
-view is contrary to all our previous ideas, yet it must be admitted that
-there are no facts which disprove directly that such a selection on the
-part of the germ-cells takes place. If these two suppositions be
-granted, then Castle’s hypothesis is as follows:—
-
-In order that half of the individuals shall become males and half
-females it is necessary to assume that in some individuals the male
-element dominates and in others the female, and since each fertilized
-egg contains both male and female elements, it is necessary to assume
-that either the egg or the spermatozoon contains the dominating element.
-
-Castle supposes that in hermaphroditic organisms the two characters
-“exist in the balanced relationship in which they were received from the
-parents,” but, as has just been stated, in unisexual forms one or the
-other sex dominates, except of course in those rare cases, as in the
-bees and ants, where half of the body may bear the characters of one
-sex, and the other half that of the other sex.
-
-In parthenogenetic species the female character is supposed to be
-uniformly stronger, so that it dominates in every contest, “for the
-fertilized egg in such species develops invariably into a female.” Under
-certain circumstances, as Castle points out, the parthenogenetic female
-produces both males and females, and this is also true in the occasional
-development of the unfertilized egg of the silkworm moth, and of the
-gypsy moth, in which both male and female individuals are produced by
-parthenogenesis. These facts show that even in unfertilized eggs both
-sexes are potentially present; but this might be interpreted to mean
-that some eggs are male and some female, rather than that each egg has
-the possibility of both kinds of development. If, however, one polar
-body is retained in these parthenogenetic eggs, then _ex hypothese_ each
-egg would contain the potentialities of both sexes (if the polar body
-were of the opposite sex character). It seems necessary to make this
-assumption because in some parthenogenetic forms males and females may
-be produced later by each individual, as in the aphids, and this could
-not occur if we assume that some parthenogenetic eggs are purely male
-and some female.
-
-Castle assumes, in fact, that in animals like daphnids and rotifers one
-polar body only is extruded, and the other (the second) is retained in
-the egg, and hence the potentiality of producing males is present. In
-the honey-bee, on the contrary, Castle assumes that both polar bodies
-are extruded in the unfertilized egg (and there are some observations
-that support this idea), and since only males are produced from these,
-he believes it is the female element that has been sent out into the
-second polar body. This hypothesis is necessary, because Castle assumes
-that when both elements are present in the bee’s eggs, the female
-element dominates. “Hence, if the egg which has formed two polar cells
-develops without fertilization, it must develop into a male. But if such
-an egg is fertilized, it invariably forms a parthenogenetic female ♀
-(♂), that is, an individual in which the male character is recessive.
-Accordingly the _functional_ spermatozoon must in such cases invariably
-bear the _female character_, and this is invariably dominant over the
-male character when the two meet in fertilization.”
-
-If it should prove generally true that the size of the egg is one of the
-factors determining the sex, we have still the further question to
-consider as to whether some eggs are bigger because they are already
-female, or whether all eggs that go beyond a certain size are females,
-and all those that fail to reach this are males. If this is the case, an
-animal might produce more females if the external conditions were
-favorable to the growth of the eggs, and if in some cases these large
-eggs were capable of developing, parthenogenetic races might become
-established. Should, however, the conditions for nutrition become less
-favorable, some of the eggs might fall below the former size and produce
-males. It is not apparent, however, why all the fertilized autumn eggs
-of the aphids should give rise to females, for although these eggs are
-known to be larger than the summer eggs, yet they are produced under
-unfavorable conditions.
-
-The preceding discussion will show how far we still are from knowing
-what factors determine sex. Castle’s argument well illustrates how many
-assumptions must be made in order to make possible the view that sex is
-a predetermined quality of each germ-cell. Even if these assumptions
-were admissible, we still return to the old idea that the _fertilized
-egg_ has both possibilities, and something determines which shall
-dominate. Until we have ascertained definitely by experimental work
-whether the sex in some forms can be determined by external conditions,
-it is almost worthless to speculate further. Whatever decision is
-reached, the conclusion will have an immediate bearing on the question
-to be next discussed. Meanwhile, we can at least examine some of the
-theories that have been advanced as to what advantage, if any, has been
-gained by having the individuals of many classes divided into two kinds,
-male and female.
-
-
-                   Sex as a Phenomenon of Adaptation
-
-Of what advantage is it to have the individuals of many species
-separated into males and females? It is obviously a disadvantage from
-the point of view of propagation to have half of the individuals
-incapable of producing young, and the other half also incapable of doing
-so, as a rule, unless the eggs are fertilized by the other sex. Is there
-any compensation gained because each new individual arises from two
-parents instead of from one? Many answers have been attempted to these
-questions.
-
-At the outset it should be recognized that we are by no means forced to
-assume, as is so often done, that because there is this separation of
-the sexes it must have arisen on account of its advantage to the
-species. Whether the result may be of some benefit regardless of how it
-arose, may be an entirely different question. It would be extremely
-difficult to weigh the relative advantages (if there are any) and
-disadvantages (that are obvious as pointed out above), nor is it
-probable that in this way we can hope to get a final answer to our
-problem. We may begin by examining some of the modern hypotheses that
-have been advanced in this connection.
-
-Darwin has brought together a large number of facts which appear to show
-the beneficial effects of the union of germ-cells from two different
-individuals. Conversely, it is very generally believed, both by breeders
-and by some experimenters, that self-fertilization in the case of
-hermaphroditic forms leads, in many cases, though apparently not in all,
-to the production of less vigorous offspring. Darwin’s general position
-is that it is an advantage to the offspring to have been derived from
-two parents rather than to have come from the union of the germ-cells of
-the same individual, and he sees, in the manifold contrivances in
-hermaphroditic animals and plants to insure cross-fertilization, an
-adaptation for this purpose.
-
-This question of whether self-fertilization is less advantageous than
-cross-fertilization is, however, a different question from that of
-whether _non-sexual_ methods of reproduction are less advantageous than
-sexual ones. Since some plants, like the banana, have been propagated
-for a very long time solely by non-sexual methods without any obvious
-detriment to them, it is at first sight not easy to see what other
-advantage could be gained by the sexual method. The case of the banana
-shows that some forms do not require a sexual method of propagation.
-Other forms, however, are so constituted, as we find them, that they
-cannot reproduce at the present time except by the sexual method. In
-other words, the latter are now adapted, as it were, to the sexual
-method, and there is no longer any choice between the two methods. The
-question of whether a non-sexual form might do better if it had another
-method of propagation is not, perhaps, a profitable question to discuss.
-
-What we really need to know is whether or not the sexual method was once
-acquired, because it was an advantage to a particular organism, or to
-the species to reproduce in this way. It is assumed by many writers that
-this was the case, but whether they have sufficient ground for forming
-such an opinion is our chief concern here. On the other hand, it is
-conceivable, at least, that if the sexual method once became
-established, it might continue without respect to any superiority it
-gave over other methods, and might finally become a necessary condition
-for the propagation of particular species. Thus the method would become
-essential to propagation without respect to whether the species lost
-more than it gained. Whichever way the balance should turn, it might
-make little difference, so long as the species was still able to
-propagate itself.
-
-Brooks made the interesting and ingenious suggestion that the separation
-of the sexes has been brought about as a sort of specialization of the
-individuals in two directions. The male cells are supposed to accumulate
-the newly acquired characters, and represent, therefore, the progressive
-element in evolution. The female cells are the conservative element,
-holding on to what has been gained in the past. It does not seem
-probable, in the light of more recent work, that this is the function of
-the two sexes, and it is unlikely that we could account for the origin
-of the two sexes through the supposed advantage that such a
-specialization might bring about. A number of writers, Galton, Van
-Beneden, Bütschli, Maupas, and others, have looked at the process of
-sexual reproduction as a sort of renewal of youth, or rejuvenescence of
-the individuals. There is certainly a good deal in the process to
-suggest that something of this sort takes place, although we must be on
-our guard against assuming that the rejuvenescence is anything more than
-the fulfilment of a necessary stage in the life history. Weismann has
-ridiculed this suggestion on the ground that it is inconceivable that
-two organisms, decrepit with old age, could renew their youth by
-uniting. Two spent rockets, he says, cannot be imagined to form a new
-one by combining. There is apparent soundness in this argument, if the
-implication is taken in a narrow physical sense. If, on the other hand,
-the egg is so constituted that at a certain stage in its development an
-outside change is required to introduce a new phase, then the conception
-of rejuvenescence does not appear in quite so absurd a light.
-
-This hypothesis of rejuvenescence is based mainly on certain processes
-that take place in the life history of some of the unicellular animals.
-Let us now see what this evidence is. The results of certain experiments
-carried out by Maupas on some of the ciliate protozoans have been
-fruitful in arousing discussion as to the ultimate meaning of the sexual
-process. Maupas’ experiments consisted in isolating single individuals,
-and in following the history of the descendants that were produced
-non-sexually by division. He found that the descendants of an individual
-kept on dividing, but showed no tendency to unite with each other. After
-a large number of generations had been passed through (in _Stylonychia
-pustulata_, between 128 and 175; in _Leucophys patula_, 300 to 450; and
-in _Onychodromus grandis_, 140 to 230 generations), the division began
-to slow down, and finally came to a standstill. Maupas found that if he
-took one of these run-down individuals, and placed it with another in
-the same condition from another culture, that had had a different
-parentage, the two would unite and the so-called process of conjugation
-take place. This process consists for the species used, in the temporary
-union and partial fusion of the protoplasm of the two individuals, of an
-interchange of micronuclei, and of a fusion, in each individual, of the
-micronucleus received from the other individual with one of its own. The
-individuals then separate, and a new nucleus (or nuclei) is formed out
-of the fused pair.
-
-The individuals in question, in which this interchange of micronuclei
-has taken place, undergo a change, and behave differently from what they
-did before. They feed, become larger and less vacuolated, and are more
-active. They soon begin once more to divide. Maupas found that an
-individual that has conjugated will run through a new cycle of
-divisions, which will, however, after a time also slow down, unless
-conjugation with another individual having a different history takes
-place. If conjugation is prevented, the individual will die after a
-time. These results seemed to show that the division phase of the life
-history cannot go on indefinitely, and that through conjugation the
-individual is again brought back to the starting-point.
-
-Quite recently Calkins has carried out a somewhat similar series of
-experiments, which have an important bearing on the interpretation of
-Maupas’ results. The experiment of isolating an individual and tracing
-the career of its descendants was repeated with the following results:
-two series were started, the original forms coming from different
-localities. Of their eight descendants four of each were isolated. The
-remaining four of each set were kept together as stock material. The
-rate of division was taken as the measure of vitality. The animals
-divided more or less regularly from February to July. After each
-division (or sometimes after two divisions) the individuals were
-separated. About the 30th of July the paramœcia began to die “at an
-alarming rate, indicating that a period of depression had apparently set
-in, or degeneration in Maupas’ sense.” Up to this time the animals had
-been living in hay infusion, renewed every few days, from which they
-obtained the bacteria on which they feed. Calkins tried the effect of
-putting the weakened paramœcia into a new environment. Infusion of
-vegetables gave no good results, but meat infusions proved successful.
-“The first experiment with the latter was with teased liver, which was
-added to the usual hay infusion. The result was very gratifying, for the
-organisms began immediately to grow and to divide, the rate of division
-rising from five to nine divisions in successive ten-day periods.” This
-beneficial effect was not lasting, however, and after ten days the
-paramœcia began to die off faster than before, and the renewed
-application of the liver extract failed to revive them. A number of
-other extracts were then tried without effect. Finally they were
-transferred to the clear extract of lean beef in tap water. The effect
-of this medium was interesting, for, although it restored the weakened
-vitality, there was no rapid increase in the rate of division, as when
-first treated with the teased liver. The infusoria were, however, now
-large and vigorous, and did not die unless transferred from the beef
-medium to the usual hay infusion. “When this was attempted, they would
-become abnormally active and would finally die. The division rate
-gradually increased during the month of August until, in the last ten
-days, they averaged six generations. Finally, in September, the attempts
-to get them back on the old diet of hay infusion were successful, and
-then the division rate went up at once to twelve times in ten days, and
-a month later they were dividing at the rate of fifty times a month.”
-
-“These cultures went on well until December, when the paramœcia began to
-die again. They were saved once more with the beef extract, and when
-returned later to the hay infusion continued through another cycle of
-almost three months. Some of these were treated, once a week for
-twenty-four hours, with the beef extract, and while the two sets ran a
-parallel course at first, those kept continuously in the hay infusion
-died after a time, but those that had been put once a week into the beef
-extract (which had been stopped, however, in March) continued their high
-rate of division throughout the period of decline of their sister cells,
-and did not show signs of diminished vitality until the first period in
-June.” At this time their rate of division increased rapidly. They were
-put back into the beef extract, but it failed now to have a beneficial
-effect, and the animals continued to die at a rapid rate. To judge from
-the appearance of the organisms the new decline was due to a different
-cause; for, while in the former periods the food vacuoles contained
-undigested food, at this period the interior was free from food masses.
-The protoplasm became granular and different from that of a healthy
-individual. None of the former remedies were now of any avail. “When the
-last of the _B_-series stock had died in the five hundred and seventieth
-generation (June 16th), it looked as though the cultures were about to
-come to an end.” Extract of the brain and of the pancreas were then
-tried. To this a favorable response took place at once. The organisms
-became normal in appearance and began to divide. After forty-eight
-hours’ treatment they were returned to the usual hay infusion. Here they
-continued to multiply and reached on June 28th the six hundred and
-sixty-fifth generation.
-
-There can be no doubt that the periods of depression that appear in
-these infusoria kept in cultures can be successfully passed if the
-animals are introduced into a new environment. Without a change of this
-sort they will die. Calkins thinks that the effect is produced, not by
-the new kind of food that is supplied, but by the presence of certain
-chemical compounds. The beef extract “does not have a direct stimulating
-effect upon the digestive process and upon division, for, while the
-organisms are immersed in it, there is a very slow division rate; when
-transferred again to the hay infusion, however, they divide more rapidly
-than before.”
-
-This brings us back to the idea of the “renewal of youth” through
-conjugation. Maupas claimed that union of individuals having the same
-immediate descent is profitless. Calkins suggests that this is due to
-the similarity in the chemical composition of the protoplasm of the two
-individuals. When in nature two individuals that have lived under
-somewhat different conditions conjugate, the result should be
-beneficial, since there takes place the commingling of different
-protoplasms.
-
-Calkins’s work has shown that by means of certain substances much the
-same effect can be produced as that which is supposed to follow from the
-conjugation of two unrelated individuals. The presumption, therefore, is
-in favor of the view that the two results may be brought about in the
-same way, although we should be careful against a too ready acceptation
-of this plausible argument; for we have ample evidence to show that many
-closely similar (if not identical) responses of organisms may be brought
-about by very different agencies. The experiments seem to indicate that
-paramœcium might go on indefinitely reproducing by division, provided
-its environment is changed from time to time. If this is true, it is
-conceivable that the same thing is accomplished through conjugation. In
-the light of this possible interpretation much of the mystery connected
-with the term _rejuvenescence_ is removed, for we see that there is
-nothing in the process itself except that it brings the organism into a
-new relation with other substances. Difficult as it assuredly is to
-understand how this benefits the animal, the experimental fact shows,
-nevertheless, that such a change is for its good. That there is really
-nothing in the process of conjugation itself apart from the difference
-in the constitution of the conjugating individuals is shown by the
-result that the union of individuals having the same history and kept
-under the same conditions is of no benefit.
-
-Can we apply this same conception to the process of fertilization in the
-higher animals and plants? Is the substance of which their bodies are
-made of such a sort that it cannot go on living indefinitely under the
-same conditions, but must at times be supplied with a new environment?
-If this could be established, we could see the advantage of sexual
-reproduction over the non-sexual method. It would be extremely rash at
-present to make a generalization of this kind, for there are many forms
-known in which the only method of propagation that exists is the
-non-sexual one. In other words, there are no grounds for the assumption
-that this is a necessary condition for all kinds of protoplasm, but only
-for certain kinds.
-
-In the insects, crustaceans, rotifers, and in some plants there are a
-few species whose egg develops without fertilization. This makes it
-appear probable that the particular kind of protoplasm of these animals
-does not absolutely require union from time to time with the protoplasm
-of another individual having a somewhat different constitution.
-
-There is also an interesting parallel between the effects of solutions
-on the protozoans in Calkins’s experiments and certain results that have
-been obtained in artificial parthenogenesis. It has been stated, that by
-brushing the unfertilized eggs of the silkworm moth a larger percentage
-will develop parthenogenetically; and more recently it has been shown by
-Matthews that by agitation of the water in which the unfertilized eggs
-of the starfish have been placed many of them will begin their
-development. It was first shown by Richard Hertwig that by putting the
-unfertilized eggs of the sea-urchin in strychnine solutions, they will
-begin to segment, and I obtained the same results much better by placing
-the eggs in solutions of magnesium chloride. Loeb then succeeded in
-carrying the development to a later stage by using a different strength
-of the same solution, as well as by other solutions. Under the most
-favorable circumstances some of the eggs may produce larvæ that seem
-normal in all respects, but whether they can develop into adult
-sea-urchins has not yet been shown.
-
-These results indicate that one at least of the factors of fertilization
-is the stimulus given to the egg. On the other hand, the lack of vigor
-shown by many eggs that have been artificially fertilized indicates that
-some other result is also accomplished by the normal method of
-fertilization that is here absent. This may mean no more than that as
-yet we have not found all the conditions necessary to supply the place
-of the spermatozoon.
-
-In our study of the phenomena of adaptation we have found that sometimes
-the adaptation is for the benefit of the individual and at other times
-for the benefit of the species. May it not be true also that the process
-of sexual reproduction has more to do with a benefit conferred on the
-race rather than on the individual? In fact, Weismann has elaborated a
-view based on the conception that the process of sexual reproduction is
-beneficial to the race rather than to the individual. His idea, however,
-is not so much that the result is of direct benefit to a particular
-species, as it is advantageous to the formation of new species from the
-original one. In a sense this amounts, perhaps, to nearly the same
-thing, but in another sense the idea involves a somewhat different point
-of view.
-
-According to his view “the deeper significance of conjugation” and of
-sexual reproduction is concerned “with the mingling of the hereditary
-tendencies of two individuals.” In this way, through the different
-combinations that are formed, variations which he supposes are
-indispensable for the action of natural selection originate. The purpose
-of the sexual process is solely, according to Weismann, to supply the
-variations for natural selection. If it be asked how this process has
-been acquired for the purpose of supplying natural selection with the
-material on which it can work, we find the following reply given by
-Weismann. “But if amphimixis [by which he means the union of sex-cells
-from different individuals] is not absolutely necessary, the rarity of
-purely parthenogenetic reproduction shows that it must have a widespread
-and deep significance. Its benefits are not to be sought in the single
-individual; for organisms can arise by agamic methods, without thereby
-suffering any loss of vital energy; amphimixis must rather be
-advantageous for the maintenance and modification of species. As soon as
-we admit that amphimixis confers some such benefits, it is clear that
-the latter must be augmented, as the method appears more frequently in
-the course of generations; hence we are led to inquire how nature can
-best have undertaken to give this amphimixis the widest possible range
-in the organic world.” Nature, Weismann says, could find no more
-effectual means of bringing about the union of the sexual cells than by
-rendering them incapable of developing alone. “The male germ-cells,
-being specially adapted for seeking and entering the ovum, are, as a
-rule, so ill provided with nutriment that their unaided development into
-an individual would be impossible; but with the ovum it is otherwise,
-and accordingly the ‘reduction division’ removes half the germ-plasm and
-the power of developing is withdrawn.” It can scarcely be claimed, in
-the light of more recent discoveries, that the reduction division takes
-place in order to prevent the development of the ovum, for how then
-could we explain the corresponding division of the male germ-cells?
-
-Whatever means has been employed to bring about the process of sexual
-reproduction, the guiding principle is supposed by Weismann to be
-natural selection as stated in the following paragraph: “If we regard
-amphimixis as an adaptation of the highest importance, the phenomenon
-can be explained in a simple way. I only assume that amphimixis is of
-advantage in the phyletic development of life, and furthermore that it
-is beneficial in maintaining the level of adaptation, which has been
-once attained, in every single organism; for this is as dependent upon
-the continuous activity of natural selection as the coming of new
-species. According to the frequency with which amphimixis recurs in the
-life of a species, is the efficiency with which the species is
-maintained; since so much the more easily will it adapt itself to new
-conditions of life, and thus become modified.”
-
-Thus we reach the somewhat startling conclusion that through natural
-selection the germ-cells and their protozoan prototypes have been
-rendered incapable, through natural selection, of reproducing by
-non-sexual methods, in order that variations may be supplied for the
-farther action of this same process of natural selection. The
-speculation has the appearance of arguing in a circle, although if it
-were worth the attempt an ingenious mind might perhaps succeed in
-showing that such a thing is not logically inconceivable.
-
-It seems strange that a claim of this sort should have been made, when
-it is so apparent that the most immediate effect of intercrossing is to
-swamp all variations that depart from the average. Even if it were true
-that new combinations of characters would arise through the union of the
-germ-cells of two different animals, it is certainly true that in the
-case of fluctuating variations this new combination would be lost by
-later crossing with average individuals. Moreover, it is well known that
-variations occur amongst forms that are produced asexually. On the
-whole, it does not seem to be a satisfactory solution of the problem to
-assume that sexual reproduction has been acquired in order to supply
-natural selection with material on which it may work.
-
-Our examination of the suggestions that have been made and of the
-speculation indulged in, as to what benefit the process of sexual
-reproduction confers on the animals and plants that make use of this
-method of propagation, has failed to show convincingly that any
-advantage to the individual or to the species is the outcome. This may
-mean, either that there is no advantage, or that we have as yet failed
-to understand the meaning of the phenomenon. The only light that has
-been thrown on the question is that a certain amount of renewed vigor is
-a consequence of this process, but we cannot explain how this takes
-place. There is also the suggestion that the union of different cells
-produces the same beneficial effect as a change in the conditions of
-life produces on the organism. The bad effects of close interbreeding
-that seem sometimes to follow is explicable on this view. This, it seems
-to me, is the most plausible solution of the question that has been
-advanced; but, even if this should prove to be the correct view, we need
-not assume that the process has been acquired on account of this
-advantage, for there is nothing to show that it has been acquired in
-this way.
-
-
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-
-
-
-
-                              CHAPTER XIII
-
-                    SUMMARY AND GENERAL CONCLUSIONS
-
-
-The question of the origin of the adaptations with which the last three
-chapters have so largely dealt is one of the most difficult problems in
-the whole range of biology, and yet it is one whose immense interest has
-tempted philosophers in the past, and will no doubt continue to excite
-the imagination of biologists for many years to come. No pretence has
-been made in the preceding pages to account for the cause of a single
-useful variation. We have examined the evidence, and from this we
-believe the assumption justified that such variations do sometimes
-appear. The more fundamental question as to the origin of these
-variations has not been taken up, except in those cases in which the
-adaptive response appeared directly in connection with a known external
-cause. But these kinds of responses do not appear to have been the
-source of the other adaptations of the organic world. Our discussion has
-been largely confined to the problem of the widespread occurrence of
-adaptation in living things, and to the most probable kinds of known
-variations that could have given rise to these adaptations. But, to
-repeat, we have made no attempt to account for the causes or the origin
-of the different kinds of variation.
-
-Nägeli, in speaking of the methods of the earlier theorists in Germany,
-remarks with much acumen: “We might have expected that after the period
-of the Nature-philosophizers, which in Germany crippled the best forces
-that might have been used for the advance of the science, we should have
-learnt something from experience, and have carefully guarded the field
-of real scientific work from philosophical speculation. But the outcome
-has shown that, in general, the philosophical, philological, and
-æsthetic expression always gets the upper hand, and a fundamental and
-exact treatment of scientific questions remains limited to a small
-circle. The public at large always shows a distinct preference for the
-so-called idealistic, poetic, and speculative modes of expression.” The
-truth of this statement can scarcely be doubted when in our own time we
-have seen more than once the same method employed with great public
-applause. Nowhere is this more apparent than in the writings of many of
-the followers of Darwin in respect to the adaptations of living things.
-To imagine that a particular organ is useful to its possessor, and to
-account for its origin because of the imagined benefit conferred, is the
-general procedure of the followers of this school. Although protests
-have from time to time been raised against this unwarrantable way of
-settling the matter, they have been largely ignored and forgotten. The
-fallacy of the argument has, for example, been admirably pointed out by
-Bateson in the following statement:[36] “In examining cases of variation
-I have not thought it necessary to speculate on the usefulness or
-harmfulness of the variations described. For reasons given in Section II
-such speculation, whether applied to normal structures or to variation,
-is barren and profitless. If any one is curious on these questions of
-Adaptation, he may easily thus exercise his imagination. In any case of
-Variation there are a hundred ways in which it may be beneficial or
-detrimental. For instance, if the ‘hairy’ variety of the moor-hen became
-established on an island, as many strange varieties have been, I do not
-doubt that ingenious persons would invite us to see how the hairiness
-fitted the bird in some special way for life in that island in
-particular. Their contention would be hard to deny, for on this class of
-speculation the only limitations are those of the ingenuity of the
-author. While the only test of utility is the success of the organism,
-even this does not indicate the utility of one part of the economy, but
-rather the net fitness of the whole.” Keeping in mind the admonitions
-contained in the two preceding quotations, let us pass in review and
-attempt to analyze more fully the different points that have been
-considered in the preceding chapters.
-
-Footnote 36:
-
-  “Materials for the Study of Variation.”
-
-It has been pointed out that the evidence in favor of the theory of
-evolution appears to establish this theory with great probability,
-although a closer examination shows that we are almost completely in the
-dark as to how the process has come about. For example, we have not yet
-been able to determine whether the great groups of animals and plants
-owe their resemblance to descent from a single original species or from
-a large number of species. The former view is more plausible, because on
-it we appear to be furnished with a better explanation of resemblances
-as due to divergence of character. Yet even here a closer scrutiny of
-the homologies of comparative anatomy shows that this explanation may be
-more apparent than real. If discontinuous variation represents the steps
-by which evolution has taken place, the artificiality of the explanation
-is apparent, at least to a certain degree.
-
-Admitting that the theory of evolution is the most probable view that we
-have to account for the facts, we next meet with two further
-questions,—the origin of species and the meaning of adaptation. These
-are two separate and distinct questions, and not one and the same as the
-Darwinian theory claims. The fact that all organisms are more or less
-adapted to live in some environment appears from our examination to have
-no direct connection with the origin of the adaptation, for, in the
-first place, it seems probable that, in general, organisms do not
-respond adaptively to the environment and produce new species in this
-way; and, in the second place, there is no evidence to show that
-variation from internal causes is so regulated that only adaptive
-structures arise (although only adaptive ones may survive).
-
-Our general conclusion is then as follows: A species does not arise from
-another one because it is better adapted. Selection, in other words,
-does not account for the origin of new species; and adaptation cannot be
-taken as the measure of a species.
-
-It may sound like a commonplace to state that only those individuals
-survive and propagate themselves that can find some place in nature
-where they can exist and leave descendants; and yet this statement may
-contain all that it is necessary to assume, in order to account for the
-fact that organisms are, on the whole, adapted. Let us see how this view
-differs from the Darwinian statement of the origination of new forms
-through a process of natural selection.
-
-According to Darwin’s view of the origin of species, each new species is
-gradually formed out of an older one, because of the advantage that the
-new individual may have over the parent form. Each step forward is
-acquired, because it better adapts the organism to the old, or to a new
-set of conditions. In contrast to this, I have urged that the formation
-of the new species is, as a rule, quite independent of its adaptive
-value in regard to the parent species. But after it has appeared, its
-survival will depend upon whether it can find a place in nature where it
-can exist and leave descendants. If it should be well adapted to an
-environment, it will be represented in it by a large number of
-individuals. If it is poorly adapted, it may only barely succeed in
-existing, and leave correspondingly fewer descendants. If its
-adaptiveness falls below a certain point, it can never get a permanent
-foothold, however often it may appear. Thus the test of survival
-determines which species can remain in existence, and which cannot, but
-new species are not manufactured in this way. How far subsequent
-variations may be supposed to be determined by the survival of certain
-species and the destruction of others will be discussed presently.
-
-The difference between the two points of view that we are contrasting
-can be best brought out by considering the two other kinds of selection
-which Darwin supposes to have been at work; namely, artificial and
-sexual selection.
-
-Darwin thinks that the results of artificial selection are brought about
-by the breeder picking out fluctuating variations. It appears that he
-has probably overestimated the extent to which this process can be
-carried; for while there can be no doubt that a certain standard, or
-fixity of type, can be obtained by selecting fluctuating variations, yet
-it now seems quite certain that the extent to which this can be carried
-is very limited. It appears that other factors have also played an
-important rôle; amongst these the occasional appearance of discontinuous
-variation, also the bringing under cultivation of the numerous “smaller
-species” of De Vries, or the so-called “single variations” of Darwin.
-Further, the effects of intercrossing in all combinations of the above
-forms of variations, followed by the selection of certain of the new
-forms obtained, has been largely employed, and also the direct influence
-of food and of other external conditions, which may be necessary to keep
-the race up to a certain standard, have played a part in some cases. The
-outcome is, therefore, by no means so simple as one might infer from
-Darwin’s treatment of the subject in his “Origin of Species.” For these
-reasons, as well as for others that have been given, it will be evident
-that the process of artificial selection cannot be expected to give a
-very clear idea of how natural selection could act.
-
-It is, however, the process of sexual selection that brings out in the
-strongest contrast the difference between Darwin’s main idea of natural
-selection and the law of the survival of species. In sexual selection
-the competition is supposed to be always between the individuals of the
-same species and of the same sex. There can be no doubt in one’s mind,
-after reading “The Descent of Man,” that Darwin held firmly to the
-belief that the individual differences, or fluctuating variations,
-furnish the material for selection. In this way it could never happen
-that two competing species could exterminate each other, because in the
-one the males were better adorned, or killed each other off on a larger
-scale, owing to the presence of special weapons of warfare. It is clear
-that on the law of the survival of species, secondary sexual characters
-cannot be supposed to have evolved because of their value. Their origin
-is totally inexplicable on this view. In fact, the presence of the
-ornaments must be in some cases injurious to the existence of the
-species. The interpretation of this means, I think, that individual
-competition cannot be as severe as Darwin believed, and cannot lead to
-the results that he imagined it does. For this reason it seemed
-important to make as careful an examination of the claims of the theory
-of sexual selection as possible, and I hope that the outcome of the
-examination has shown quite definitely that the theory is incompetent to
-account for the facts that it claims to explain. It is certain in this
-case that we are dealing with a phenomenon that must be studied quite
-apart from any selective value that the secondary sexual organs may
-have. If this is granted, it will be seen that there is here a wide
-field for experimental investigation that is practically untouched.
-
-It is evident that the first step that will clear the way to a fuller
-understanding of the problem of evolution must be a more thorough
-examination of the question of variation. Darwin himself fully
-appreciated this fact, yet until within the last fifteen years the study
-of variation has been largely neglected. With a fuller knowledge of the
-nature of fluctuating variation as the outcome of the studies of Galton,
-Pearson, De Vries, and others, and with a fuller knowledge of the
-possibilities of discontinuous variation as emphasized by Bateson and by
-De Vries, and, further, with a better knowledge of some of the laws of
-inheritance in these cases, we have begun to get a different conception
-of how evolution has come about. It may be well, therefore, to go once
-more over the main points in regard to the different kinds of variation.
-
-While it has been found that no two individuals of a species are exactly
-alike, yet, taken as a group, the variations appear as though they
-followed the law of chance. The descendants of the group show the same
-differences. Thus the group _as a whole_ appears constant, while the
-individuals fluctuate continually in all directions. This is what we
-understand by fluctuating variation. If the external conditions are
-changed, a new “_mode_” may appear, but the change is generally only a
-temporary one, and lasts only as long as the new conditions remain.
-Thus, while the direct influence of the environment may show for a time,
-the result is transient. Even if it were permanent, there is no evidence
-that the adaptation of organisms could be accounted for in this way
-unless the response were useful. It appears that this sometimes really
-occurs, especially in responses to temperature, to moisture, to the
-amount of salts in solution, to poisonous substances, etc. In this way,
-one kind of adaptation is brought about, but there is no evidence that
-the great number of structural adaptations have thus arisen.
-
-The Lamarckian principle of the inheritance of acquired characters has
-also been supposed by many writers to be an important source of adaptive
-variation. An examination of this theory is not found to inspire
-confidence. We have, therefore, eliminated this hypothesis on the ground
-that it lacks evidence in its favor, and also because it appears
-improbable that in this way many of the adaptations in organisms could
-have been acquired.
-
-Finally, there is the group of discontinuous variations. Of these there
-may be several kinds, and there is some evidence showing that there are
-such. For the present we may include all the different sorts under the
-term _mutation_, meaning that the new character or group of characters
-suddenly appears, and is inherited in its new form. From the results of
-De Vries it appears that mutations are sometimes scattering, at least in
-the case of the evening primrose. From such scattering mutations, the
-smaller species or varieties (in so far as these do not depend on local
-conditions) arise. There is here an important point of agreement with
-Darwin’s idea in regard to evolution, inasmuch as he supposed that
-varieties are incipient species. Our point of view is different,
-however, in that we do not suppose these varieties (mutations) to have
-been gradually formed out of fluctuating variations by a process of
-selection, but to have arisen at once by a single mutation. It also
-appears that in some cases a single new mutation may develop in a
-species. We may suppose that the new form might in such a case supplant
-the parent species by absorbing it, or both may go on living side by
-side, as will be more likely the case if they are adapted to somewhat
-different conditions.
-
-A number of writers have supposed that evolution marches steadily
-forward toward its final goal, which may even lead in some cases to the
-final but inevitable destruction of the species. By certain writers this
-view has been called orthogenesis, although at other times the idea is
-not so much that there is advance in a straight line, as advance in all
-directions. This appears to be Nägeli’s view. It gives a splendid
-picture of the organic world, as irresistibly marching toward its
-goal,—a relentless process in some cases, leading to final annihilation,
-a beneficent process in other cases, leading to the fullest perfection
-of form of which the type is capable. Compared with the vacillating
-progress which is supposed to be the outcome of individual selection,
-this view of progression has a grandeur that appeals directly to the
-imagination. We must be guided, however, by evidence, rather than by
-sentiment. The case will, moreover, bear closer scrutiny. If evolution
-has indeed taken place by the survival of a series of mutations, whose
-origin has no connection with their value, does not this in the end
-amount to nearly the same thing as maintaining that evolution of
-organisms has been a steady progress forward,—a progress undirected by
-external forces, but the outcome of internal development? Admitting that
-innumerable creations have been lopped off, because they could find no
-foothold, yet, as Nägeli points out, the result is that, instead of a
-dense tangle of forms, there has been left relatively few that have been
-found capable of existing,—those that have found some place in which
-they can live and leave progeny. From this point of view it may appear,
-at first thought, that the idea of evolution through mutations involves
-a fundamentally different view from that of the Darwinian school of
-selection; but in so far as selection also depends on the spontaneous
-appearance of fluctuating variations, the same point of view is to some
-extent involved,—only the steps are supposed to be smaller. This point
-is usually ignored and passed over in silence by the Darwinians, but, as
-Wigand has pointed out, it makes very little difference whether the
-stages in the process of evolution are imagined to be very small or
-somewhat larger, so long as they are spontaneous. Selection does not do
-more than determine the survival of what is offered to it, and does not
-create anything new.
-
-It is true that if the fluctuating variations that are selected be
-connected by very slight differences with an almost continuous series of
-other forms, and if little by little such a series be advanced in a
-given direction by selection, we get the idea of a continuity, whose
-advance is determined by selection. It is this conception that appears
-to give the theory of natural selection a creative power, which in
-reality it does not possess, and certainly not in the modified form in
-which the theory was finally left by Darwin. For Darwin found himself
-forced to admit that, unless a very considerable number of individuals
-varied at the same time and in the same direction, the formation of new
-species could not take place, and this idea of many individuals varying
-at the same time, and in the same direction, at once involves the
-conception that evolution moves forward by some force residing in the
-organism, driving it forwards or backwards. Instability comes, perhaps,
-nearer to expressing this idea than any other term, and yet to evolve
-from a protozoan to a man implies the idea of something more than simple
-unstableness.
-
-The idea that Weismann has touched upon in this connection, namely, that
-the survival of a given form determines the future course of evolution
-for that form, is very plausible, and also fits in well with the results
-of our experience in the field of the inheritance of variations. We see
-new variations or mutations departing in some or in many characters from
-the original type, apparently by new combinations or perturbations of
-those already present. We never expect to see a bird emerge from the egg
-of an alligator. Thus it appears that by the survival of certain forms
-the future course of evolution is determined in so far as the new types
-of mutation are thereby limited. Weismann means, however, that in this
-way new plus or minus steps will be indefinitely determined amongst the
-new fluctuating variations, but this statement is contradicted by our
-experience of the results of artificial selection. The upper limit does
-not keep on pushing out indefinitely in the direction determined by the
-first selection, but is soon brought to a standstill. So that, as far as
-Weismann’s hypothesis is concerned, the idea appears to have no special
-value. On the other hand, this idea may be fruitful if applied to
-mutations, but here unfortunately we have not sufficient experience to
-guide us, and we do not know definitely whether a new character that
-appears as a mutation will be more likely, in subsequent mutations, to
-go on increasing in some of the descendants. Thus, while the mutation
-theory must assume that some new characters will go on heaping up, we
-lack the experimental evidence to show that this really occurs. It would
-be also equally important to determine, whether, if after several
-mutations have successively appeared in the same direction, there would
-be an established tendency to go on in the same direction in some of the
-future mutations. But here again we must wait until we have more data
-before we attempt to build up a theory on such a basis.
-
-The attacks on the Darwinian school by the followers of the modern
-school of experimentalists are with few exceptions based on the
-assumption that the natural selectionists pretend that their principle
-is a sort of creative force,—a factor in evolution in the sense of being
-an active agent. This assumption of the selectionists has led many of
-them to ignore a fundamental weakness of their theory, namely, the
-origin of the variations themselves, although Darwin did not overlook or
-ignore this side of the problem, or fail to realize its importance, as
-have some of his more ardent, but less critical, followers. They have
-contented themselves, as a rule, with pointing out that certain
-structures are useful, and this has seemed to them sufficient proof that
-the structures must have been acquired because of their value. In
-contrast to this complacency of the selectionists, we find here and
-there naturalists who have, from time to time, insisted that the
-scientific problem of evolution is not to be found in the principle of
-selection, but in the origin of the variations themselves. It will be
-clear, from what has been said, that this is our position also, and for
-us adaptation itself does not appear to be any more a problem that can
-be examined by scientific methods, than the lack of adaptation. The
-causes of the change of whatever kind should be our immediate quest. The
-destruction of the unfit, because they can find no place where they can
-exist, does not explain the origin of the fit.
-
-Over and beyond the primary question of the _origin_ of the adaptive, or
-non-adaptive, structure is the fact that we find that the great majority
-of animals and plants show distinct evidence of being suited or adapted
-to live in a special environment, _i.e._ their structure and their
-responses are such that they can live and leave descendants behind them.
-I can see but two ways in which to account for this condition, either
-(1) teleologically, by assuming that only adaptive variations arise, or
-(2) by the survival of only those mutations that are sufficiently
-adapted to get a foothold. Against the former view is to be urged that
-the evidence shows quite clearly that variations (mutations) arise that
-are not adaptive. On the latter view the dual nature of the problem that
-we have to deal with becomes evident, for we assume that, while the
-origin of the adaptive structures must be due to purely physical
-principles in the widest sense, yet whether an organism that arises in
-this way shall persist depends on whether it can find a suitable
-environment. This latter is in one sense selection, although the word
-has come to have a different significance, and, therefore, I prefer to
-use the term _survival of species_.
-
-The origin of a new form and its survival after it has appeared have
-been often confused by the Darwinian school and have given the critics
-of this school a fair chance for ridiculing the selection theory. The
-Darwinian school has supposed that it could explain the origin of
-adaptations on the basis of their usefulness. In this it seems to me
-they are wrong. Their opponents, on the other hand, have, I believe,
-gone too far when they state that the present condition of animals and
-plants can be explained without applying the test of survival, or in a
-broad sense the principle of selection amongst species.
-
-It will be clear, therefore, in spite of the criticism that I have not
-hesitated to apply to many of the phases of the selection theory,
-especially in relation to the selection of the individuals of a species,
-that I am not unappreciative of the great value of that part of Darwin’s
-idea which claims that the _condition_ of the organic world, as we find
-it, cannot be accounted for entirely without applying the principle of
-selection in one form or another. This idea will remain, I think, a most
-important contribution to the theory of evolution. We may sum up our
-position categorically in the following statements:
-
-Animals and plants are not changed in this or in that part in order to
-become better adjusted to a given environment, as the Darwinian theory
-postulates. Species exist that are in some respects very poorly adapted
-to the environment in which they must live. If competition were as
-severe as the selection theory assumes, this imperfection would not
-exist.
-
-In other cases a structure may be more perfect than the requirements of
-selection demand. We must admit, therefore, that we cannot measure the
-organic world by the measure of utility alone. If it be granted that
-selection is not a moulding force in the organic world, we can more
-easily understand how both less perfection and greater perfection may be
-present than the demands of survival require.
-
-If we suppose that new mutations and “definitely” inherited variations
-suddenly appear, some of which will find an environment to which they
-are more or less well fitted, we can see how evolution may have gone on
-without assuming new species have been formed through a process of
-competition. Nature’s supreme test is survival. She makes new forms to
-bring them to this test through mutation, and does not remodel old forms
-through a process of individual selection.
-
-
-------------------------------------------------------------------------
-
-
-
-
-                                 INDEX
-
-
- Acclimatization, 319.
- Acorn, 24.
- Acracids, 160.
- Adaptation, definition of, 1.
- Adjustments, individual, 12.
- Agassiz, 1, 44, 61.
- Agelæus, 173.
- Alcohol, 13.
- Algæ, red, 9.
- Alkaloids, 13.
- Allen, 173, 307-310.
- Allolobophora, 380.
- Alpheus, 344.
- Ammophila, 5.
- Ammotragus, 208.
- Ampelopsis, 403.
- Amphimixis, 448-449.
- Amphioxus, 399.
- Ancon race, 315-316.
- Angiostomum, 422.
- Anguillidæ, 320.
- Annelids, 19, 20.
- Anolis, 10, 194.
- Ant-eater, 227, 228.
- Antelope, 6, 206, 208.
- Antitoxin, 14.
- Ants, 141-146, 354, 386, 407.
- Aphids, 384-386, 419, 426.
- Apus, 418.
- Archæopteryx, 41, 42, 53, 54.
- Ardea, 200.
- Argus pheasant, 199.
- Aristolochia Clematitis, 10, 11, 12.
- Arsenic, 13.
- Artemia, 306.
- Ascidians, 417.
- Askenasy, 161.
- Aspalax, 227.
- Asterina, 421-422.
- Autenrieth, 58.
-
-
- Baboon, 209.
- Bacteria, 14, 15, 111, 398.
- Baer, Von, 60, 61, 74, 75.
- Bamboo, 313.
- Barnacles, 417.
- Bartlett, 209, 220.
- Bat, 2.
- Bates, 183, 186.
- Bateson, 273, 278, 453.
- Beard, 210, 211, 216.
- Beard, J., 435.
- Bee, 2, 3, 19, 143, 179, 303, 350, 406, 420, 421, 425, 438.
- Beethoven, 218.
- Beetles, 182, 183, 189.
- Bell-bird, 198.
- Beneden, Van, 441.
- Berbura goat, 208.
- Biogenetic Law, 71.
- Birds, 6, 407;
-   definition of group, 36;
-   evolution of, 41;
-   instincts of young, 4;
-   nest, 4;
-   of paradise, 6;
-   teeth of, 301;
-   variation in, 309-312.
- Blind animals, 354.
- Blow-fly, 383.
- Bonellia, 353, 417.
- Born, 424.
- Bos, 206.
- Boveri, 433.
- Bovidæ, 207.
- Branchipus, 306.
- Brocadello, 428.
- Brooks, 441.
- Brown-Séquard, 232, 241, 250-257.
- Buffon, 300.
- Bull, 207, 315.
- Bütschli, 441.
- Butterfly, 3, 184, 389.
-
-
- Cactus, 10.
- Caffein, 13.
- California salmon, 19.
- Calkins, 443-447.
- Callionymus, 191.
- Calocalanus, 177.
- Cameron, 425.
- Canestrini, 178.
- Canidæ, 308.
- Canis, 410.
- Carbonnier, 190, 192.
- Cardamine, 335.
- Cardinalis, 173.
- Cardium, 305.
- Cassowary, 202.
- Castle, 148, 321, 435, 438.
- Caterpillar, 5, 8, 186.
- Cattle, 411.
- Cats, 209.
- Cercopithecus, 208.
- Cervus, 304.
- Chara, 420.
- Charrin, 257.
- Chick, 57, 406.
- Child, 72.
- Chinese pheasants, 6.
- Chlorophyl, 9.
- Cicadas, 187, 188.
- Ciona, 148.
- Classification, 31-36.
- Classification, scheme of, 38.
- Cockatoo, 6.
- Colaptes, 310.
- Colias, 185.
- Colonial forms, 127.
- Color, 18, 19, 24, 133, 375.
- Coloration, 5, 6, 7, 23, 357-360.
- Columba livia, 76.
- Comb of bees, 4.
- Communal marriages, 210.
- Competition, 104, 112, 119, 120, 121, 122, 123.
- Compositæ, 130.
- Cones, 310.
- Conklin, 72.
- Cope, 49, 259.
- Copridæ, 183.
- Coral-snakes, 194.
- Correlated variation, 94.
- Correlation, 134.
- Cottus, 191.
- Crab, 15, 248, 344, 354.
- Crickets, 188.
- Crocodiles, 193.
- Crosby, 398.
- Cross-fertilization, 21.
- Crossing of species, 148, 149, 150.
- Crystal, 29.
- Cryptocerus, 144.
- Ctenophors, 417.
- Cuckoo, 139, 140, 141.
- Cuénot, 427-428, 435.
- Culicidæ, 188.
- Cunningham, 257-260.
- Cuvier, 44, 301.
- Cynocephalus, 209.
- Cypridopsis, 392-393.
- Cyprinodonts, 190.
- Cypris, 320.
-
-
- Dall, 260.
- Dallinger, 320.
- Danaids, 160.
- Dances, 195.
- Daphnia, 305, 418.
- Darwin, C., numerous references throughout the text.
- Darwin, Erasmus, 223.
- Date-palm, 313.
- Davenport, 264, 266, 321.
- Dean, 358.
- Death, 370.
- Death, feigning, 410, 411.
- Deer, 309.
- Degeneration, 165.
- Delamare, 257.
- Descent theory, 31-35.
- Desmarest, 206.
- Desmodium, 403.
- Dianthus, 149.
- Didelphys, 410.
- Dimorphism, 360.
- Dingoes, 314.
- Dinophilus, 428.
- Diptera, 180, 188.
- Divergence of character, 127, 128.
- Dog, 226.
- Draba, 288, 289, 290, 292, 294.
- Draco, 194.
- Dragonet, 191.
- Drill, 209.
- Ducks, 94, 314.
- Düsing, 423.
- Dutrochet, 320.
-
-
- Earthworm, 380, 382, 383, 384, 417.
- Echidna, 54.
- Eciton, 144.
- Egerton, 204.
- Egg, 429-430, 432.
- Eggs, number of, 19.
- Egypt, animals of, 225.
- Egyptian remains of animals, 43, 44.
- Eimer, 158, 260.
- Eisig, 72.
- Electric organs, 22, 132, 372.
- Elephant, 110-111, 206, 304.
- Emu, 202.
- Entoscolax, 353.
- Epihippus, 50.
- Equus, 50.
- Eristales, 188.
- Esmeralda, 182.
- Euploids, 160.
- Eustephanus, 201.
- Evolution, 29.
- Ewart, 238.
- Exercise, 12.
- External conditions, 130.
- Eye, 13, 131, 132.
- Eye, evolution of, 131, 132.
- Eye, of flatfish, 137.
-
-
- Fayal Islands, 124.
- Felidæ, 308.
- Felis, 308.
- Fish, change of color, 16.
- Fishes, 7.
- Fishes, secondary sexual character of, 190.
- Flatfish, 137, 138.
- Flatworms, 417.
- Fleischmann, 45-57.
- Flounders, 228, 346, 347.
- Flowers, 9, 17, 21, 342, 399, 422, 429.
- Fly, 428.
- Foot of horse, 47.
- Forel, 5.
- Fossil horses, 52.
- Foxes, 210, 410.
- Franqueiros cattle, 315.
- Frogs, 193, 320, 382, 405.
- Frogs, cross-fertilization, 150.
- Fruit, down of, 133.
- Fundulus, 16.
-
-
- Galton, 236, 270-272, 289, 441.
- Gavials, 301.
- Geddes and Thompson, 417, 423, 426, 427.
- Geer, De, 178.
- Gegenbaur, 49.
- Gelasimus, 177.
- Geoffroy St.-Hilaire, 44, 67, 300-303.
- Geological evidence, 39.
- Gerbe, 429.
- Germinal selection, 154.
- Gibbon, 213.
- Gill-clefts, 62, 63, 64, 73.
- Giraffe, 6, 203, 229, 248-249.
- Glacier, 28.
- Glowworm, 23.
- Goat, 206, 208.
- Gonionema, 399.
- Gorilla, 205.
- Gothic period, 47, 48.
- Gould, 197.
- Graba, 124, 125.
- Grafting, 153.
- Grasshoppers, 8, 188.
- Gray, 126.
- Greyhound, 134.
- Growth of plants, 17.
- Guillemots, 124.
- Guinea-pigs, 232.
- Günther, 190.
- Gymnotus, 132.
-
-
- Haeckel, 48, 49, 56, 70, 71, 79, 80, 82.
- Hartman, 187.
- Heart, 66, 67.
- Heliconids, 160.
- Helix, 344, 345-346.
- Hemiptera, 181.
- Heredity, 270.
- Hermaphroditic animals, 126.
- Hertwig, O., 78, 79, 80, 81, 82, 83.
- Hertwig, R., 447.
- Hieracium, 330, 331.
- Hildebrand, 148.
- Hill, 252.
- Hipparion, 51.
- Hippeastrum, 148.
- His, 71, 72.
- Holmes, 72.
- Hornbills, 219.
- Horns, 229.
- Horse, 42, 224.
- Horse-chestnut, 24.
- Hothura, 410.
- Hottentots, 212.
- Hudson, 140, 195, 409-412.
- Humming-birds, 6, 197, 228.
- Hurst, 75, 76, 77, 78.
- Huxley, 49, 156, 233.
- Hyatt, 259.
- Hybrids, 149, 239.
- Hydatina, 417.
- Hydroides, 348.
- Hylobates, 205.
- Hymenoptera, 181.
-
-
- Ice, 28.
- Ichneumonidæ, 181.
- Idioplasm, 335.
- Immunity, 13.
- India cattle, 208.
- Infanticide, 25.
- Inorganic adaptations, 26.
- Insectivorous plants, 10.
- Insects, coloration of, 7;
-   wingless, 228.
- Instinct, 25, 139, 140, 141.
- Irish elk, 247.
-
-
- Jackson, 260.
- Jaguar, 209.
- Japanese cock, 163.
- Jennings, 395.
- Jonghe, 314.
- Jordan, 292.
- Joseph, 428.
- Junco, 311.
-
-
- Kallima, 7, 161, 162, 358.
- Kangaroo, 229, 351.
- Katydid, 8.
- Kent, W. Saville, 191.
- Kidneys, 66.
- Kielmeyer, 58.
- Kirby, 232.
- Kiwi, 354.
- Kölreuter, 149.
- Korschelt, 428.
-
-
- Labidocera, 393.
- Lamarck, 146, 222-233.
- Lamarckian factor, 94, 205, 211, 222, 458.
- Lang, 345.
- Law of Biogenesis, 30.
- Leaf, resemblance to, 7.
- Leaves, closing of, 11.
- Leeches, 417.
- Leguminosæ, 124.
- Leidy, 46.
- Length of life, 20.
- Lenhossek, 435.
- Leopard, 209.
- Lepidoptera, 172.
- Leptothrix, 320.
- Leucophys, 442.
- Lichen, 9.
- Lillie, 72.
- Limbs of vertebrates, 46.
- Linaria, 401.
- Linnæan species, 83.
- Linnæus, 191.
- Lion, 6.
- Lizards, 7, 16, 17, 193.
- Lobelia, 148.
- Lobster, 343.
- Lockwood, 138.
- Locusts, 188.
- Loeb, 383-392, 447.
- Lomaria, 290.
- Lowell lectures, 61.
- Lumbriculus, 15.
- Luminous organs, 133.
- Lymnæa, 305, 322.
- Lythrum, 363-370.
-
-
- Machines, 26, 27, 28.
- McIntosh, 176.
- McNeill, 204.
- Macropus, 192.
- Malva, 401.
- Mammalia, origin, 54, 202.
- Man, 210.
- Marsh, 49.
- Matthews, 447.
- Mauchamp, 315.
- Maupas, 441, 442, 445.
- May-flies, 19, 353, 389.
- Mead, 72.
- Meckel, 59, 60.
- Melanism, 209.
- Melospiza, 311.
- Mendel, 278-286, 433, 436.
- Mesohippus, 51.
- Mimosa, 404.
- Minnow, 16.
- Minot, 433.
- Mirabilis, 149, 150.
- Mivart, 136, 137.
- Mole, 1, 2, 18, 227.
- Mole-cricket, 1, 2.
- Molothrus, 140.
- Monkeys, 207, 208.
- Mons, Van, 332.
- Montgomery, 432.
- Moor-hen, 453.
- Moquin-Tandon, 303.
- Morton, Lord, 238.
- Moschus, 206.
- Moths, 184, 387, 388.
- Moussu, 257.
- Mozart, 218.
- Mulberry, 313.
- Müller, 182, 188.
- Müller, Fritz, 148.
- Muscles, 12.
- Mycetes, 205.
- Myzostomum, 422.
-
-
- Nägeli, 161, 325-339, 459.
- Natural selection, 104-107, 108, 109, 110, etc.;
-   definition of, 117.
- Nauplius, 69.
- Nectar, 124.
- Nectar-feeding insects, 126, 127.
- Nectarines, 134.
- Negroes, 212.
- Nematode, number of eggs, 110.
- Nematus, 425.
- Nemertian worms, 176.
- Neo-Lamarckians, 240, 259-260.
- Nepenthes, 10.
- Nephela, 178.
- Nest of birds, 4, 407-408.
- Neuters, 142.
- Nicotine, 13.
- Nostocs, 320.
- Notochord, 64, 65.
- Nussbaum, 424.
-
-
- Ocneria, 428.
- Œnothera, 294-297.
- Oken, 56, 58.
- Old age, 21, 25.
- Onites, 232.
- Onychodromus, 442.
- Opossum, 410.
- Organs of little use, 22.
- “Origin of Species,” 129.
- Ornithorynchus, 54.
- Orobanchia, 330.
- Osborn, 259.
- Oscillaria, 320.
- Ostrich, 203, 354.
- Oxalis, 290, 404.
- Oxen, 304.
- Oxide, 29.
-
-
- Packard, 231, 260.
- Paludina, 320, 322.
- Pangenesis, 233-240.
- Papilio, 158, 360, 388;
-   polyxenes, 3.
- Paradisea, 197.
- Paramæcium, 395-398, 442-447.
- Parasitism, 352-353.
- Parker, 393.
- Parrots, 6.
- Partridge, 410.
- Passerella, 311.
- Passiflora, 148.
- Pavo, 317.
- Peach, 134.
- Peacock, 200, 317-318.
- Peafowl, 198.
- Pearson, 265, 267, 268-270.
- Peas, 281-286.
- Peckham, 178, 408.
- Pelobates, 421.
- Pflüger, 424, 430.
- Phosphorescent organs, 22, 133.
- Physa, 320, 322.
- Pigeons, selection in, 102.
- Pipilo, 311.
- Pisum, 278.
- Pithecia, 208.
- Planaria, 380.
- Planarians, 394.
- Plants, 403, 415;
-   color of, 24;
-   influence of light, 17.
- Plato, 304.
- Plover, 202.
- Poisons, 13, 14, 15, 18, 20, 377.
- Polar bear, 6.
- Pollen, 2, 125.
- Polygon, 262.
- Porthesia, 389.
- Primula, 361-365.
- Prionidæ, 182.
- Probosces of insects, 127.
- Protective coloration, 5, 6, 16, 158, 159.
- Proteus, 227.
- Protohippus, 51.
- Przibram, 347.
- Psyche, 419.
- Ptarmigan, 5.
- Pyrodes, 182.
-
-
- Quetelet, 289.
- Quiscalus, major, 173.
-
-
- Rabbit, Porto Santo, 316-317.
- Rabbits, 304.
- Rabbits in Australia, 112.
- Race-horse, 134.
- Ranunculus, 305.
- Ray-florets, 135.
- Rays, electric organs of, 22.
- Réaumur, 388.
- Recapitulation theory, 58-83.
- Reduction division, 432-433.
- Regeneration, 15, 16, 27, 379.
- Regulations, 27, 28.
- Reproductive organs, 19.
- Reptiles, fossil, 52, 53.
- Rengger, 205.
- Rhododendron, 330.
- Rhynchæa, 201.
- Riley, 424.
- Rivers, 28.
- Robinia, 404.
- Romanes, 132, 250-256, 412.
- Rose, 307.
- Rothert, 398.
- Rotifers, 118, 353, 424.
- Roulin, 304.
- Roundworms, 176, 353.
- Rudimentary organs, 22.
- Ryder, 260.
-
-
- Sacculina, 353.
- Sachs, 10.
- Salmon, 19.
- Salter, 314.
- Salvin, 201.
- Saphirina, 176.
- Savages, 210.
- Saw-flies, 425.
- Scarlet tanager, 198.
- Schaefer, 244.
- Sclater, 198.
- Scops, 312.
- Scott, 148, 259.
- Sea-anemone, 341.
- Sea-urchin, 341.
- Secondary sexual characters, 21.
- Selection, 116.
- Selection, artificial, 91, 92, 96, 97, 98.
- Self-fertilization, 126.
- Semper, 260.
- Setchel, 320.
- Sexual characters, secondary, 372-374.
- Sexual selection, 167.
- Sharp, 350, 425.
- Sheep, 208.
- Sherrington, 244.
- Shrew mice, 206.
- Silkworm, 428, 447.
- Silver-bill, 410.
- Sirex, 181.
- Siricidæ, 181.
- Sitaria, 194.
- Skin, thickening of, 12, 13.
- Skull, 37, 65.
- Skunk, 3.
- Slaves of ants, 141.
- Sleep in plants, 404.
- Sloth, 229.
- Snail, 417.
- Snails, color of, 23.
- Snakes, 14, 193-194, 227.
- Snowy owl, 6.
- Solenobia, 419.
- Soles, 137, 228.
- Sparassus, 178.
- Sparrow, 200;
-   English, 112.
- Species, 31, 32, 33;
-   adaptation for good of, 19;
-   sharp separation of, 131.
- Spencer, 240-246, 247, 290.
- Spermatozoa, 150, 430-433.
- Sphinx, 186, 388.
- Spiders, 177-178, 179, 406;
-   web, 3.
- Spirogyra, 420.
- Spontaneous variability, 134.
- Spores, 322.
- Squilla, 177.
- Squirrels, 210.
- Stag-beetle, 179.
- Stags, 203-204, 219.
- Sterility, 147-152.
- Strasburger, 395.
- Stridulating organs, 188, 189.
- Struggle for existence, 109, 110.
- Stylonychia, 442.
- Survival of the fittest, 107, 108, 109, 117.
- Sutton, 432.
- Swallow, 115.
- Sweating, 12.
-
-
- Tadpole, 321, 428.
- Tail, 2.
- Tanager, 6.
- Tapeworm, 353;
-   number of eggs, 110.
- Taraxacum, 305.
- Tear-sacs, 206.
- Teeth, bird’s, 67, 68.
- Telegony, 95, 234, 237, 238, 239.
- Tenthredinidæ, 181, 425.
- Termite, number of eggs, 110.
- Termitidæ, 350.
- Thrush, 115.
- Tipulæ, 188.
- Toad, 7.
- Torpedo, 132.
- Towle, 392.
- Transitional forms, 42.
- Transmutation theory, 31, 34.
- Traquair, 138.
- Treadwell, 72.
- Treat, 424.
- Tree-frogs, 7.
- Trichina, 353.
- Trifolium, 404.
- Triton, 193.
- Turkeys, 314.
- Turnix, 201, 202.
- Turtles, 193.
-
-
- Umbelliferæ, 135.
- Uria lacrymans, 124.
- Utricularia, 10,
-
-
- Vanessa, 360.
- Variability, 92, 93, 95, 96, 318-319.
- Variation, 261, 340.
- Variation, fluctuating, 100, 118, 123.
- Variation under domestication, 136.
- Varieties, 106, 107, 148.
- Varigny, De, 303-306, 314-315, 322.
- Venus fly-trap, 9.
- Verbascum, 148, 149.
- Vertebrates, evolution of, 40, 45.
- Vilmorin, 303, 314.
- Vinson, 178.
- Vries, De, 97, 278, 289-298, 340.
- Vulpine, 209.
-
-
- Wallace, 7, 162, 186, 202, 221, 249.
- Walrus, 203.
- Walsh, 181.
- Walther, 59.
- Wasp, 3, 5, 408, 409.
- Waterton, 198.
- Web, spider’s, 3, 4.
- Weir, 171.
- Weismann, 154-166, 441, 448-450.
- Westwood, 188.
- Whale, 227, 301.
- Wilson, E. B., 72.
- Wing of bat, 2.
- Wolf, 308, 376.
- Wolves, 412.
- Women, 210.
- Woodpecker, 228.
- Wounds, healing of, 15.
-
-
- Yarrell, 138.
- Yung, 424, 436.
-
-
- Zebu cattle, 208.
- Zeleny, 348.
- Zoea, 69, 70.
-
-
-
-
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-<h1 class="pgx" title="">The Project Gutenberg eBook, Evolution and Adaptation, by Thomas Hunt
-Morgan</h1>
-<p>This eBook is for the use of anyone anywhere in the United States
-and most other parts of the world at no cost and with almost no
-restrictions whatsoever.  You may copy it, give it away or re-use it
-under the terms of the Project Gutenberg License included with this
-eBook or online at <a
-href="http://www.gutenberg.org">www.gutenberg.org</a>.  If you are not
-located in the United States, you'll have to check the laws of the
-country where you are located before using this ebook.</p>
-<p>Title: Evolution and Adaptation</p>
-<p>Author: Thomas Hunt Morgan</p>
-<p>Release Date: October 24, 2020  [eBook #63540]</p>
-<p>Language: English</p>
-<p>Character set encoding: UTF-8</p>
-<p>***START OF THE PROJECT GUTENBERG EBOOK EVOLUTION AND ADAPTATION***</p>
-<p>&nbsp;</p>
-<h4 class="pgx" title="">E-text prepared by<br />
-    Turgut Dincer, Barry Abrahamsen,<br />
-    and the Online Distributed Proofreading Team<br />
-    (<a href="http://www.pgdp.net">http://www.pgdp.net</a>)<br />
-    from page images generously made available by<br />
-    Internet Archive<br />
-    (<a href="https://archive.org">https://archive.org</a>)</h4>
-<p>&nbsp;</p>
-<table border="0" style="background-color: #ccccff;margin: 0 auto;" cellpadding="10">
-  <tr>
-    <td valign="top">
-      Note:
-    </td>
-    <td>
-      Images of the original pages are available through
-      Internet Archive. See
-      <a href="https://archive.org/details/evolutionadaptat00morg">
-      https://archive.org/details/evolutionadaptat00morg</a>
-    </td>
-  </tr>
-</table>
-<p>&nbsp;</p>
-<hr class="pgx" />
-<p>&nbsp;</p>
-<p>&nbsp;</p>
-<p>&nbsp;</p>
-
-<div  class='figcenter id001'>
-<img src='images/cover.jpg' alt='' class='ig001' />
-<div class='ic001'>
-<p><span class='small'>The cover image was created by the transcriber and is placed in the public domain.</span></p>
-</div>
-</div>
-<div class='pbb'>
- <hr class='pb c000' />
-</div>
-<div>
-  <h1 class='c001'><span class='xxlarge'>EVOLUTION AND ADAPTATION</span></h1>
-</div>
-<div class='pbb'>
- <hr class='pb c002' />
-</div>
-<p class='c003'>&nbsp;</p>
-<div  class='figcenter id002'>
-<img src='images/publogo.jpg' alt='' class='ig001' />
-</div>
-<div class='pbb'>
- <hr class='pb c002' />
-</div>
-
-<div class='nf-center-c0'>
-<div class='nf-center c004'>
-    <div><span class='pageno' id='Page_I'>I</span><span class='xxlarge'>EVOLUTION</span></div>
-    <div class='c000'><span class='xxlarge'>AND ADAPTATION</span></div>
-    <div class='c002'>BY</div>
-    <div class='c005'>THOMAS HUNT MORGAN, <span class='sc'>Ph.D.</span></div>
-  </div>
-</div>
-
-<div class='blackletter'>
-
-<div class='nf-center-c0'>
-  <div class='nf-center'>
-    <div>New York</div>
-  </div>
-</div>
-
-</div>
-
-<div class='nf-center-c0'>
-  <div class='nf-center'>
-    <div>THE MACMILLAN COMPANY</div>
-    <div>LONDON: MACMILLAN &amp; CO., <span class='sc'>Ltd.</span></div>
-    <div class='c000'>1908</div>
-    <div class='c000'><i>All rights reserved</i></div>
-  </div>
-</div>
-
-<div class='pbb'>
- <hr class='pb c006' />
-</div>
-
-<div class='nf-center-c0'>
-<div class='nf-center c002'>
-    <div><span class='pageno' id='Page_II'>II</span><span class='sc'>Copyright</span>, 1903,</div>
-    <div class='c000'><span class='large'><span class='sc'>By</span> THE MACMILLAN COMPANY.</span></div>
-  </div>
-</div>
-
-<hr class='c007' />
-
-<div class='nf-center-c0'>
-  <div class='nf-center'>
-    <div>Set up and electrotyped. Published October, 1903. Reprinted January, 1908.</div>
-  </div>
-</div>
-
-<div class='blackletter'>
-
-<div class='nf-center-c0'>
-<div class='nf-center c002'>
-    <div>Norwood Press</div>
-  </div>
-</div>
-
-</div>
-
-<div class='nf-center-c0'>
-  <div class='nf-center'>
-    <div>J. S. Cushing Co.—Berwick &amp; Smith Co.</div>
-    <div>Norwood, Mass., U.S.A.</div>
-  </div>
-</div>
-
-<div class='pbb'>
- <hr class='pb c006' />
-</div>
-
-<div class='nf-center-c0'>
-<div class='nf-center c002'>
-    <div><span class='pageno' id='Page_III'>III</span><i>TO</i></div>
-  </div>
-</div>
-
-<div class='blackletter'>
-
-<div class='nf-center-c0'>
-  <div class='nf-center'>
-    <div><span class='xxlarge'>Professor William Keith Brooks</span></div>
-  </div>
-</div>
-
-</div>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div><span class='large'><i>AS A TOKEN OF SINCERE ADMIRATION AND RESPECT</i></span></div>
-  </div>
-</div>
-
-<div class='pbb'>
- <hr class='pb c002' />
-</div>
-<div class='chapter'>
-  <span class='pageno' id='Page_vii'>vii</span>
-  <h2 class='c008'>PREFACE</h2>
-</div>
-<p class='c009'>The adaptation of animals and plants to the conditions
-under which they live has always excited the interest, and
-also the imagination, of philosophers and scientists; for this
-relation between the organism and its environment is one of
-the most characteristic features of living things. The question
-at once suggests itself: How has such a relation been
-brought about? Is it due to something inherent in the living
-matter itself, or is it something that has been, as it were,
-superimposed upon it? An example may make my meaning
-clearer. No one will suppose that there is anything inherent
-in iron and other metals that would cause them to produce
-an engine if left to themselves. The particular arrangement
-of the pieces has been superimposed upon the metals, so that
-they now fulfil a purpose, or use. Have the materials of
-which organisms are composed been given a definite arrangement,
-so that they fulfil the purpose of maintaining the
-existence of the organism; and if so, how has this been
-accomplished? It is the object of the following pages to
-discuss this question in all its bearings, and to give, as far
-as possible, an idea of the present state of biological thought
-concerning the problem. I trust that the reader will not
-be disappointed if he finds in the sequel that many of the
-most fundamental questions in regard to adaptation are still
-unsettled.</p>
-
-<p class='c010'>In attempting to state the problem as clearly as possible,
-I fear that it may appear that at times I have “taken sides,”
-<span class='pageno' id='Page_viii'>viii</span>when I should only have been justified in stating the different
-aspects of the question. But this will do little harm provided
-the issue has been sharply drawn. Indeed, it seems to me
-that the only scientific value, that a discussion of what the
-French call “les grands problèmes de la Biologie” has, is to
-get a clearer understanding of the relation of what is known
-to what is unknown or only surmised.</p>
-
-<p class='c010'>In some quarters speculation concerning the origin of the
-adaptation of living things is frowned upon, but I have failed
-to observe that the critics themselves refrain entirely from
-theorizing. They shut one door only to open another, which
-also leads out into the dark. To deny the right to speculative
-thought would be to deny the right to use one of the best
-tools of research.</p>
-
-<p class='c010'>Yet it must be admitted that all speculation is not equally
-valuable. The advance of science in the last hundred years
-has shown that the kind of speculation that has real worth is
-that which leads the way to further research and possible
-discovery. Speculation that leads to this end must be recognized
-as legitimate. It becomes useless when it deals with
-problems that cannot be put to the actual test of observation
-or experiment. It is in this spirit that I have approached the
-topics discussed in the following pages.</p>
-
-<p class='c010'>The unsophisticated man believes that all other animals
-exist to minister to his welfare; and from this point of view
-their adaptations are thought of solely in their relation to
-himself. A step in advance was taken when the idea was
-conceived that adaptations are for the good of the organisms
-themselves. It seemed a further advance when the conclusion
-was reached that the <i>origin</i> of adaptations could be
-accounted for, as the result of the benefit that they conferred
-on their possessor. This view was the outcome of the acceptation
-of the theory of evolution, combined with Darwin’s
-theory of natural selection. It is the view held by most
-biologists at the present time; but I venture to prophesy
-<span class='pageno' id='Page_ix'>ix</span>that if any one will undertake to question modern zoologists
-and botanists concerning their relation to the Darwinian
-theory, he will find that, while professing <i>in a general way</i>
-to hold this theory, most biologists have many reservations
-and doubts, which they either keep to themselves or, at any
-rate, do not allow to interfere either with their teaching of
-the Darwinian doctrine or with the applications that they
-may make of it in their writings. The claim of the opponents
-of the theory that Darwinism has become a dogma
-contains more truth than the nominal followers of this school
-find pleasant to hear; but let us not, therefore, too hastily
-conclude that Darwin’s theory is without value in relation
-to one side of the problem of adaptation; for, while we can
-profitably reject, as I believe, much of the theory of natural
-selection, and more especially the idea that adaptations have
-arisen because of their usefulness, yet the fact that living
-things must be adapted more or less well to their environment
-in order to remain in existence may, after all, account
-for the widespread <i>occurrence</i> of adaptation in animals and
-plants. It is this point of view that will be developed in
-the following pages.</p>
-
-<p class='c010'>I am fully aware of the danger in attempting to cover
-so wide a field as that of “Evolution and Adaptation,” and
-I cannot hope to escape the criticism that is certain to be
-directed against a specialist who ventures nowadays beyond
-the immediate field of his own researches; yet, in my own
-defence, I may state that the whole point of view underlying
-the position here taken is the immediate outcome of
-my work on regeneration. One of the general questions
-that I have always kept before me in my study of regenerative
-phenomena is how such a useful acquirement as the
-power to replace lost parts has arisen, and whether the
-Darwinian hypothesis is adequate to explain the result.
-The conclusion that I have reached is that the theory is
-entirely inadequate to account for the <i>origin</i> of the power
-<span class='pageno' id='Page_x'>x</span>to regenerate; and it seemed to me, therefore, desirable to
-reëxamine the whole question of adaptation, for might it
-not prove true here, also, that the theory of natural selection
-was inapplicable? This was my starting-point. The results
-of my examination are given in the following pages.</p>
-
-<p class='c010'>I am deeply indebted to Professor G. H. Parker and to
-Professor E. G. Conklin for advice and friendly criticism;
-and in connection with the revision of the proof I am
-under many obligations to Professor Joseph W. Warren
-and to Professor E. A. Andrews. Without their generous
-help I should scarcely have ventured into a field so full of
-pitfalls.</p>
-<p class='c009'><span class='sc'>Bryn Mawr, Penn.</span>, June 10, 1903.</p>
-<div class='pbb'>
- <hr class='pb c006' />
-</div>
-<div class='chapter'>
-  <span class='pageno' id='Page_xi'>xi</span>
-  <h2 class='c008'>CONTENTS</h2>
-</div>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div>CHAPTER I</div>
-  </div>
-</div>
-
-<table class='table0' summary=''>
-<colgroup>
-<col width='85%' />
-<col width='14%' />
-</colgroup>
-  <tr>
-    <td class='c011'>&nbsp;</td>
-    <td class='c012'><span class='small'>PAGE</span></td>
-  </tr>
-  <tr>
-    <td class='c011'><span class='sc'>The Problem of Adaptation</span></td>
-    <td class='c012'><a href='#Page_1'>1</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Structural Adaptations</td>
-    <td class='c012'><a href='#Page_1'>1</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Adaptations for the Good of the Species</td>
-    <td class='c012'><a href='#Page_19'>19</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Organs of Little Use to the Individual</td>
-    <td class='c012'><a href='#Page_22'>22</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Changes in the Organism that are of No Use to the Individual or to the Race</td>
-    <td class='c012'><a href='#Page_25'>25</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Comparison with Inorganic Phenomena</td>
-    <td class='c012'><a href='#Page_26'>26</a></td>
-  </tr>
-</table>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div>CHAPTER II</div>
-  </div>
-</div>
-
-<table class='table0' summary=''>
-<colgroup>
-<col width='85%' />
-<col width='14%' />
-</colgroup>
-  <tr>
-    <td class='c011'><span class='sc'>The Theory of Evolution</span></td>
-    <td class='c012'><a href='#Page_30'>30</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Evidence in Favor of the Transmutation Theory</td>
-    <td class='c012'><a href='#Page_32'>32</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>–  – Evidence from Classification and from Comparative Anatomy</td>
-    <td class='c012'><a href='#Page_32'>32</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>–  – The Geological Evidence</td>
-    <td class='c012'><a href='#Page_39'>39</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>–  – Evidence from Direct Observation and Experiment</td>
-    <td class='c012'><a href='#Page_43'>43</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>–  – Modern Criticism of the Theory of Evolution</td>
-    <td class='c012'><a href='#Page_44'>44</a></td>
-  </tr>
-</table>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div>CHAPTER III</div>
-  </div>
-</div>
-
-<table class='table0' summary=''>
-<colgroup>
-<col width='85%' />
-<col width='14%' />
-</colgroup>
-  <tr>
-    <td class='c011'><span class='sc'>The Theory of Evolution</span> (<i>continued</i>)</td>
-    <td class='c012'><a href='#Page_58'>58</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– The Evidence from Embryology</td>
-    <td class='c012'><a href='#Page_58'>58</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>–  – The Recapitulation Theory</td>
-    <td class='c012'><a href='#Page_58'>58</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Conclusions</td>
-    <td class='c012'><a href='#Page_84'>84</a></td>
-  </tr>
-</table>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div>CHAPTER IV</div>
-  </div>
-</div>
-
-<table class='table0' summary=''>
-<colgroup>
-<col width='85%' />
-<col width='14%' />
-</colgroup>
-  <tr>
-    <td class='c011'><span class='sc'>Darwin’s Theories of Artificial and of Natural Selection</span></td>
-    <td class='c012'><a href='#Page_91'>91</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– The Principle of Selection</td>
-    <td class='c012'><a href='#Page_91'>91</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Variation and Competition in Nature</td>
-    <td class='c012'><a href='#Page_104'>104</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– The Theory of Natural Selection</td>
-    <td class='c012'><a href='#Page_116'>116</a></td>
-  </tr>
-</table>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div><span class='pageno' id='Page_xii'>xii</span>CHAPTER V</div>
-  </div>
-</div>
-
-<table class='table0' summary=''>
-<colgroup>
-<col width='85%' />
-<col width='14%' />
-</colgroup>
-  <tr>
-    <td class='c011'><span class='sc'>The Theory of Natural Selection</span> (<i>continued</i>)</td>
-    <td class='c012'><a href='#Page_129'>129</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Objections to the Theory of Natural Selection</td>
-    <td class='c012'><a href='#Page_129'>129</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Sterility between Species</td>
-    <td class='c012'><a href='#Page_147'>147</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Weismann’s Germinal Selection</td>
-    <td class='c012'><a href='#Page_154'>154</a></td>
-  </tr>
-</table>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div>CHAPTER VI</div>
-  </div>
-</div>
-
-<table class='table0' summary=''>
-<colgroup>
-<col width='85%' />
-<col width='14%' />
-</colgroup>
-  <tr>
-    <td class='c011'><span class='sc'>Darwin’s Theory of Sexual Selection</span></td>
-    <td class='c012'><a href='#Page_167'>167</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Sexual Selection</td>
-    <td class='c012'><a href='#Page_167'>167</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– General Criticism of the Theory of Sexual Selection</td>
-    <td class='c012'><a href='#Page_213'>213</a></td>
-  </tr>
-</table>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div>CHAPTER VII</div>
-  </div>
-</div>
-
-<table class='table0' summary=''>
-<colgroup>
-<col width='85%' />
-<col width='14%' />
-</colgroup>
-  <tr>
-    <td class='c011'><span class='sc'>The Inheritance of Acquired Characters</span></td>
-    <td class='c012'><a href='#Page_222'>222</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Lamarck’s Theory</td>
-    <td class='c012'><a href='#Page_222'>222</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Darwin’s Hypothesis of Pangenesis</td>
-    <td class='c012'><a href='#Page_233'>233</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– The Neo-Lamarckian School</td>
-    <td class='c012'><a href='#Page_240'>240</a></td>
-  </tr>
-</table>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div>CHAPTER VIII</div>
-  </div>
-</div>
-
-<table class='table0' summary=''>
-<colgroup>
-<col width='85%' />
-<col width='14%' />
-</colgroup>
-  <tr>
-    <td class='c011'><span class='sc'>Continuous and Discontinuous Variation and Heredity</span></td>
-    <td class='c012'><a href='#Page_261'>261</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Continuous Variation</td>
-    <td class='c012'><a href='#Page_261'>261</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Heredity and Continuous Variation</td>
-    <td class='c012'><a href='#Page_270'>270</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Discontinuous Variation</td>
-    <td class='c012'><a href='#Page_272'>272</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Mendel’s Law</td>
-    <td class='c012'><a href='#Page_278'>278</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– The Mutation Theory of De Vries</td>
-    <td class='c012'><a href='#Page_287'>287</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Conclusions</td>
-    <td class='c012'><a href='#Page_297'>297</a></td>
-  </tr>
-</table>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div>CHAPTER IX</div>
-  </div>
-</div>
-
-<table class='table0' summary=''>
-<colgroup>
-<col width='85%' />
-<col width='14%' />
-</colgroup>
-  <tr>
-    <td class='c011'><span class='sc'>Evolution as the Result of External and Internal Factors</span></td>
-    <td class='c012'><a href='#Page_300'>300</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– The Effect of External Influences</td>
-    <td class='c012'><a href='#Page_300'>300</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Responsive Changes in the Organism that adapt it to the New Environment</td>
-    <td class='c012'><a href='#Page_319'>319</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Nägeli’s Perfecting Principle</td>
-    <td class='c012'><a href='#Page_325'>325</a></td>
-  </tr>
-</table>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div><span class='pageno' id='Page_xiii'>xiii</span>CHAPTER X</div>
-  </div>
-</div>
-
-<table class='table0' summary=''>
-<colgroup>
-<col width='85%' />
-<col width='14%' />
-</colgroup>
-  <tr>
-    <td class='c011'><span class='sc'>The Origin of the Different Kinds of Adaptations</span></td>
-    <td class='c012'><a href='#Page_340'>340</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Form and Symmetry</td>
-    <td class='c012'><a href='#Page_340'>340</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Mutual Adaptation of Colonial Forms</td>
-    <td class='c012'><a href='#Page_350'>350</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Degeneration</td>
-    <td class='c012'><a href='#Page_352'>352</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Protective Coloration</td>
-    <td class='c012'><a href='#Page_357'>357</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Sexual Dimorphism and Trimorphism</td>
-    <td class='c012'><a href='#Page_360'>360</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Length of Life as an Adaptation</td>
-    <td class='c012'><a href='#Page_370'>370</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Organs of Extreme Perfection</td>
-    <td class='c012'><a href='#Page_371'>371</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Secondary Sexual Organs as Adaptations</td>
-    <td class='c012'><a href='#Page_372'>372</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Individual Adjustments as Adaptations</td>
-    <td class='c012'><a href='#Page_375'>375</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Color Changes as Individual Adaptations</td>
-    <td class='c012'><a href='#Page_375'>375</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Increase of Organs through Use and Decrease through Disuse</td>
-    <td class='c012'><a href='#Page_376'>376</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Reactions of the Organism to Poisons, etc.</td>
-    <td class='c012'><a href='#Page_377'>377</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Regeneration</td>
-    <td class='c012'><a href='#Page_379'>379</a></td>
-  </tr>
-</table>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div>CHAPTER XI</div>
-  </div>
-</div>
-
-<table class='table0' summary=''>
-<colgroup>
-<col width='85%' />
-<col width='14%' />
-</colgroup>
-  <tr>
-    <td class='c011'><span class='sc'>Tropisms and Instincts as Adaptations</span></td>
-    <td class='c012'><a href='#Page_382'>382</a></td>
-  </tr>
-</table>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div>CHAPTER XII</div>
-  </div>
-</div>
-
-<table class='table0' summary=''>
-<colgroup>
-<col width='85%' />
-<col width='14%' />
-</colgroup>
-  <tr>
-    <td class='c011'><span class='sc'>Sex as an Adaptation</span></td>
-    <td class='c012'><a href='#Page_414'>414</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– The Different Kinds of Sexual Individuals</td>
-    <td class='c012'><a href='#Page_414'>414</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– The Determination of Sex</td>
-    <td class='c012'><a href='#Page_422'>422</a></td>
-  </tr>
-  <tr>
-    <td class='c011'>– Sex as a Phenomenon of Adaptation</td>
-    <td class='c012'><a href='#Page_439'>439</a></td>
-  </tr>
-</table>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div>CHAPTER XIII</div>
-  </div>
-</div>
-
-<table class='table0' summary=''>
-<colgroup>
-<col width='85%' />
-<col width='14%' />
-</colgroup>
-  <tr>
-    <td class='c011'><span class='sc'>Summary and General Conclusions</span></td>
-    <td class='c012'><a href='#Page_452'>452</a></td>
-  </tr>
-</table>
-<table class='table1' summary=''>
-<colgroup>
-<col width='85%' />
-<col width='14%' />
-</colgroup>
-  <tr>
-    <td class='c011'>INDEX</td>
-    <td class='c012'><a href='#idx'>465</a></td>
-  </tr>
-</table>
-<div class='pbb'>
- <hr class='pb c000' />
-</div>
-
-<div class='nf-center-c0'>
-<div class='nf-center c002'>
-    <div><span class='pageno' id='Page_1'>1</span><span class='xlarge'>EVOLUTION AND ADAPTATION</span></div>
-  </div>
-</div>
-
-<div class='chapter'>
-  <h2 class='c008'>CHAPTER I<br /> <br /><span class='c013'>THE PROBLEM OF ADAPTATION</span></h2>
-</div>
-<p class='c009'><span class='sc'>Between</span> an organism and its environment there takes
-place a constant interchange of energy and of material. This
-is, in general, also true for all bodies whether living or lifeless;
-but in the living organism this relation is a peculiar one; first,
-because the plant or the animal is so constructed that it is
-suited to a particular set of physical conditions, and, second,
-because it may so respond to a change in the outer world
-that it further adjusts itself to changing conditions, <i>i.e.</i> the
-response may be of such a kind that it better insures the
-existence of the individual, or of the race. The two ideas
-contained in the foregoing statement cover, in a general way,
-what we mean by the adaptation of living things. The following
-examples will serve to illustrate some of the very
-diverse phenomena that are generally included under this
-head.</p>
-<h3 class='c014'><span class='sc'>Structural Adaptations</span></h3>
-
-<p class='c015'>The most striking cases of adaptations are those in which
-a special, in the sense of an unusual, relation exists between
-the individual and its surroundings. For example, the foreleg
-of the mole is admirably suited for digging underground.
-A similar modification is found in an entirely different group
-of the animal kingdom, namely, in the mole-cricket, in which
-the first legs are also well suited for digging. By their use the
-mole-cricket makes a burrow near the surface of the ground,
-<span class='pageno' id='Page_2'>2</span>similar to, but of course much smaller than, that made by the
-mole. In both of these cases the adaptation is the more
-obvious, because, while the leg of the mole is formed on the
-same general plan as that of other vertebrates, and the leg of
-the mole-cricket has the same fundamental structure as that
-of other insects, yet in both cases the details of structure and
-the general proportions have been so altered, that the leg is
-fitted for entirely different purposes from that to which the
-legs of other vertebrates and of other insects are put. The
-wing of the bat is another excellent case of a special adaptation.
-It is a modified fore-limb having a strong membrane
-stretched between the fingers, which are greatly elongated.
-Here we find a structure, which in other mammals is used
-as an organ for supporting the body, and for progression on
-the ground, changed into one for flying in the air.</p>
-
-<p class='c010'>The tails of mammals show a number of different adaptations.
-The tail is prehensile in some of the monkeys; and not
-only can the monkey direct its tail toward a branch in order to
-grasp it, but the tail can be wrapped around the branch and
-hold on so firmly that the monkey can swing freely, hanging
-by its tail alone. The animal has thus a sort of fifth
-hand, one as it were in the middle line of the body, which can
-be used as a hold-fast, while the fingered hands are put to
-other uses. In the squirrels the bushy tail serves as a protection
-during the winter for those parts of the body not so
-thickly covered by hair. The tail of the horse is used to
-brush away the flies that settle on the hind parts of the body.
-In other mammals, the dog, the cat, and the rat, for example,
-the tail is of less obvious use, although the suggestion has
-been made that it may serve as a sort of rudder when the
-animal is running rapidly. In several other cases, as in the
-rabbit and in the higher apes, the tail is very short, and is of
-no apparent use; and in man it has completely disappeared.</p>
-
-<p class='c010'>A peculiar case of adaptation is the so-called basket on the
-third pair of legs of the worker honey-bee. A depression
-<span class='pageno' id='Page_3'>3</span>of the outer surface of the tibia is arched over by stiff
-hairs. The pollen collected from the stamens of flowers
-is stowed away in this receptacle by means of the other
-pairs of legs. The structure is unique, and is not found in
-any other insects except the bees. It is, moreover, present
-only in the worker bees, and is absent in the queen and the
-males.</p>
-
-<p class='c010'>The preceding cases, in which the adapted parts are used
-for the ordinary purposes of life of the individual, are not
-essentially different from the cases in which the organ is
-used to protect the animal from its enemies. The bad taste
-of certain insects is supposed to protect them from being
-eaten by birds. Cases like this of passive protection grade
-off in turn into those in which, by some reflex or voluntary
-act, the animal protects itself. The bad-smelling horns of
-the caterpillar of the black swallow-tailed butterfly (<i>Papilio
-polyxenes</i>) are thrust out when the animal is touched, and it
-is believed that they serve to protect the caterpillar from
-attack. The fœtid secretion of the glands of the skunk is
-believed to serve as a protection to the animal, although the
-presence of the nauseous odor may lead finally to the extermination
-of the skunk by man. The sting of bees and of
-wasps serves to protect the individual from attack. The sting
-was originally an ovipositor, and used in laying the eggs.
-It has, secondarily, been changed into an organ of offence.</p>
-
-<p class='c010'>The special instincts and reflex acts furnish a striking
-group of adaptations. The building of the spider’s web is
-one of the most remarkable cases of this kind. The construction
-of the web cannot be the result of imitation, since,
-in many instances, the young are born in the spring of the
-year following the death of the parents. Each species of
-spider has its own type of web, and each web has as characteristic
-a form as has the spider itself. It is also important
-to find that a certain type of web may be characteristic of
-an entire family of spiders. Since, in many cases, the web
-<span class='pageno' id='Page_4'>4</span>is the means of securing the insects used for food, it fulfils
-a purpose necessary for the welfare of the spider.</p>
-
-<p class='c010'>The making of the nests by birds appears to be also in
-large part an instinctive act; although some writers are
-inclined to think that memory of the nest in which the
-young birds lived plays a part in their actions, and imitation
-of the old birds at the time of nest-building may, perhaps,
-also enter into the result. It has been stated that the first
-nest built by young birds is less perfect than that built by
-older birds, but this may be due to the bird’s learning something
-themselves in building their nests, <i>i.e.</i> to the perfecting
-of the instinct in the individual that makes use of it. In any
-case much remains that must be purely instinctive. The
-construction of the comb by bees appears to be largely, perhaps
-entirely, an instinctive act. That this is the case was
-shown by isolating young workers as soon as they emerged
-from the cell, and before they could have had any experience
-in seeing comb built. When given some wax they set to
-work to make a comb, and made the characteristic six-sided
-structures like those made by the bees in a hive. The formation
-of so remarkable a structure as the comb is worthy of
-admiration, for, with the greatest economy of material, a
-most perfect storeroom for the preservation of the honey is
-secured. This adaptation appears almost in the nature of
-foresight, for the store of honey is used not only to feed the
-young, but may be drawn on by the bees themselves in time
-of need. It is true that a comparison with other kinds of
-bees makes it probable that the comb was first made for the
-eggs and larvæ, and only later became used as a storehouse,
-but so far as its form is concerned there is the same economy
-of constructive materials in either case.</p>
-
-<p class='c010'>The behavior of young birds, more especially those that
-take care of themselves from the moment they leave the egg,
-furnishes a number of cases of instincts that are protective.
-If, for example, a flock of young pheasants is suddenly disturbed,
-<span class='pageno' id='Page_5'>5</span>the birds at once squat down on the ground, and
-remain perfectly quiet until the danger is past. Their resemblance
-to the ground is so perfect that they are almost
-invisible so long as they remain quiet. If, instead of remaining
-still, they were to attempt to run away when disturbed,
-they would be much more easily seen.</p>
-
-<p class='c010'>Certain solitary wasps (<i>Ammophila</i>) have the habit of
-stinging caterpillars and spiders, and dragging them to their
-nests, where they are stored away for the future use of the
-young that hatch from the eggs laid by the wasp on the
-body of the prey. As a result of the sting which the wasp
-administers to the caterpillar, the latter is paralyzed, and
-cannot escape from the hole in which it is stored, where it
-serves as food for the young wasp that emerges from the
-egg. It was originally claimed by Forel that the wasp stings
-the caterpillar in such a way that the central nervous system
-is always pierced, and many subsequent naturalists have marvelled
-at the perfection of such a wonderful instinct. But
-the recent results of the Peckhams have made it clear that
-the act of the wasp is not carried out with the precision
-previously supposed, although it is true that the wasp pierces
-the caterpillar on the lower surface where the ventral chain
-of ganglia lies. The habit of this wasp is not very dissimilar
-from that shown by many other kinds of wasps that sting
-their captive in order to quiet it. We need not imagine in
-this case that the act carries with it the consciousness that
-the caterpillar, quieted in this way, will be unable to escape
-before the young wasps have hatched.</p>
-
-<p class='c010'>The resemblance in color of many animals to their natural
-backgrounds has in recent years excited the interest and
-imagination of many naturalists. The name of protective
-coloration has been given to this group of phenomena. The
-following cases which have less the appearance of purely
-imaginative writing may serve by way of illustration. A
-striking example is that of the ptarmigan which has a pure
-<span class='pageno' id='Page_6'>6</span>white coat in winter, and a brown coat in summer. The
-white winter plumage renders the animal less conspicuous
-against the background of snow, while in summer the
-plumage is said to closely resemble the lichen-covered
-ground on which the bird rests. The snowy owl is a northern
-bird, whose color is supposed to make it less conspicuous,
-and may serve either as a protection against enemies, or
-may allow the owl to approach its prey unseen. It should
-not pass unnoticed, however, that there are white birds in
-other parts of the world, where their white color cannot be
-of any use to them as a protection. The white cockatoos,
-for example, are tropical birds, living amongst green foliage,
-where their color must make them conspicuous, rather than
-the reverse.</p>
-
-<p class='c010'>The polar bear is the only member of the family that is
-white, and while this can scarcely be said to protect it from
-enemies, because it is improbable that it has anything to fear
-from the other animals of the ice-fields, yet it may be claimed
-that the color is an adaptation to allow the animal to approach
-unseen its prey.</p>
-
-<p class='c010'>In the desert many animals are sand-colored, as seen for
-instance in the tawny color of the lion, the giraffe, the
-antelopes, and of many birds that live on or near the ground.</p>
-
-<p class='c010'>It has been pointed out that in the tropics and temperate
-zones there are many greenish and yellowish birds whose
-colors harmonize with the green and yellow of the trees
-amongst which they live; but on the other hand we must
-not forget that in all climes there are numbers of birds
-brilliantly colored, and many of these do not appear to be
-protected in any special way. The tanagers, humming-birds,
-parrots, Chinese pheasants, birds of paradise, etc., are extremely
-conspicuous, and so far as we can see they must
-be much exposed on account of the color of their plumage.
-Whether, therefore, we are justified in picking out certain
-cases as examples of adaptation, because of an agreement in
-<span class='pageno' id='Page_7'>7</span>color between the organism and its surroundings, and in
-neglecting all others, is, as has been already said, a point to
-be further examined.</p>
-
-<p class='c010'>Not only among mammals and birds have many cases of
-protective coloration been described by writers dealing with
-this subject, but in nearly every group of the animal kingdom
-similar cases have been recognized. The green and brown
-color of lizards may protect them, the green color of many
-frogs is supposed to conceal them as they sit amongst the
-plants on the edge of a stream or pond. The gray-brown
-color of the toad has been described as a resemblance to the
-dry ground, while the brilliant green of several tree-frogs
-conceals them very effectively amongst the leaves. Many
-fishes are brilliantly colored, and it has even been suggested
-that those living amongst corals and sea-anemonies have
-acquired their colors as a protection, but Darwin states that
-they appeared to him very conspicuous even in their highly
-colored environment.</p>
-
-<p class='c010'>Amongst insects innumerable cases of adaptive coloration
-have been described. In fact this is the favorite group
-for illustrating the marvels of protective coloration. A few
-examples will here serve our purpose. The oft-cited case
-of the butterfly <i>Kallima</i> is, apparently, a striking instance of
-protective resemblance. When at rest the wings are held
-together over the back, as in nearly all butterflies, so that
-only the under surface is exposed. This surface has an
-unquestionably close resemblance to a brown leaf. It is said
-on no less authority than that of Wallace that when this
-butterfly alights on a bush it is almost impossible to distinguish
-between it and a dead leaf. The special point in
-the resemblance to which attention is most often called is the
-distinct line running obliquely across the wings which looks
-like the midrib of a leaf. Whether the need of such a close
-resemblance to a leaf is requisite for the life of this butterfly,
-we do not know, of course, and so long as we do not have
-<span class='pageno' id='Page_8'>8</span>this information there is danger that the case may prove too
-much, for, if it should turn out that this remarkable case is
-accidental the view in regard to the resemblance may be
-endangered.</p>
-
-<p class='c010'>Amongst caterpillars there are many cases of remarkable
-resemblances in color between the animal and its surroundings.
-The green color of many of those forms that remain on the
-leaves of the food-plant during the day will give, even to the
-most casual observer, the impression that the color is for the
-purpose of concealment; and that it does serve to conceal
-the animal there can be no doubt. But even from the point
-of view of those who maintain that this color has been
-acquired because of its protective value it must be admitted
-that the color is insufficient, because some of these same green
-caterpillars are marvellously armed with an array of spines
-which are also supposed to be a protection against enemies.
-Equally well protected are the brown and mottled geometrid
-caterpillars. These have, moreover, the striking and unusual
-habit of fixing themselves by the posterior pairs of false legs,
-and standing still and rigid in an oblique position on the
-twigs to which they are affixed. So close is their resemblance
-to a short twig, that even when their exact position is known
-it is very difficult to distinguish them.</p>
-
-<p class='c010'>Grasshoppers that alight on the ground are, in many cases,
-so similar to the surface of the ground that unless their
-exact location is known they easily escape attention, while the
-green color of the katydid, a member of the same group of
-orthoptera, protects it from view in the green foliage of the
-trees where it lives. The veinlike wings certainly suggest a
-resemblance to a leaf, but whether there is any necessity
-for so close an imitation may be questioned.</p>
-
-<p class='c010'>There can be little doubt in some of these cases that the
-color of the animal may be a protection to it, but as has
-been hinted already, it is another question whether it
-acquired these colors because of their usefulness. Nevertheless,
-<span class='pageno' id='Page_9'>9</span>if the color is useful to its possessor, it is an adaptation
-in our sense of the word, without regard to the way in
-which it has been acquired. Even, for instance, if the resemblance
-were purely the outcome of chance in the sense that
-the color appeared without relation to the surroundings, it
-would still be an adaptation if it were of use to the animal
-under the ordinary conditions of life.</p>
-
-<p class='c010'>In the lower groups numerous cases in which animals
-resemble their surroundings could be given. Such cases are
-known in crustacea, worms, mollusks, hydroids, etc., and the
-possible value of these resemblances may be admitted in
-many instances.</p>
-
-<p class='c010'>It is rather curious that so few cases of adaptive coloration
-have been described for plants. No one supposes
-that the slate color of the lichen is connected with the color
-of the rocks on which it grows, in the sense that the resemblance
-is of any use to the lichen. Nor does the color of the
-marine red algæ serve in any way to protect the plants so
-far as is known. The green color of nearly all the higher
-plants is obviously connected with the substance, chlorophyl,
-that is essential for the processes of assimilation, and has
-no relation to external objects. But when we come to the
-colors of flowers we meet with curious cases of adaptation,
-at least according to the generally accepted point of view.
-For it is believed by many naturalists that the color of the
-corolla of flowering plants is connected with the visits of
-insects to the flowers, and these visits are in many cases
-essential for the cross-fertilization of the flowers. This adaptation
-is one useful to the species, rather than the individual,
-and belongs to another category.</p>
-
-<p class='c010'>The leaf of the Venus’s fly-trap, which suddenly closes
-together from the sides when a fly or other light body
-comes to rest on it, is certainly a remarkable adaptation.
-A copious secretion of a digestive fluid is poured out on the
-surface of the leaf, and the products of digestion are absorbed.
-<span class='pageno' id='Page_10'>10</span>There can be no question that this contrivance is of some
-use to the plant. In other insectivorous plants, the pitcher
-plants, the leaves are transformed into pitchers. In Nepenthes
-a digestive fluid is secreted from the walls. A line of glands
-secreting a sweet fluid serves to attract insects to the top
-of the pitcher, whence they may wander or fall into the fluid
-inside, and there being drowned, they are digested. A lidlike
-cover projecting over the opening of the pitcher is supposed
-to be of use to keep out the rain.</p>
-
-<p class='c010'>In <i>Utricularia</i>, a submerged water-plant, the tips of the
-leaves are changed into small bladders, each having a small
-entrance closed by an elastic valve opening inwards. Small
-snails and crustaceans can pass into this opening, to which
-they are guided by small outgrowths; but once in the cup
-they cannot get out again, and, in fact, small animals are
-generally found in the bladders where they die and their
-substance is absorbed by forked hairs projecting into the interior
-of the bladder.</p>
-
-<p class='c010'>The cactus is a plant that is well suited to a dry climate.
-Its leaves have completely disappeared, and the stem has
-become swollen into a water-reservoir. “It has been estimated
-that the amount of water evaporated by a melon
-cactus is reduced to one six-hundredth of that given off
-by any equally heavy climbing-plant.”</p>
-<div id='fig-1'  class='figcenter id003'>
-<img src='images/i011.jpg' alt='' class='ig001' />
-<div class='ic003'>
-<p><span class='sc'>Fig. 1.</span>—The fertilization of <i>Aristolochia Clematitis</i>.<br />A, portion of stem with flowers in axil of leaf in different stages.<br />B and C, longitudinal sections of two flowers, before and after fertilization. (After Sachs.)</p>
-</div>
-</div>
-<p class='c009'>Sachs gives the following account of the fertilization
-process in <i>Aristolochia Clematitis</i>, which he refers to as a
-conspicuous and peculiar adaptation. In Figure <a href='#fig-1'>1 A</a> a group
-of flowers is shown, and in Figure <a href='#fig-1'>1 B and C</a> a single
-flower is split open to show the interior. In B a small fly
-has entered, and has brought in upon its back some pollen
-that has stuck to it in another flower. The fly has
-entered through the long neck which is beset with hairs
-which are turned inwards so that the fly can enter but
-cannot get out. In roaming about, the pollen that is sticking
-to its back will be rubbed against the stigmatic surface.
-<span class='pageno' id='Page_11'>11</span>“As soon as this has taken place the anthers, which have
-been closed hitherto, dehisc and become freely accessible,”
-as a result in the change in the stigma and of the collapse
-of the hairs at the base of the enlargement which has
-widened. The fly can now crawl under the anthers, and,
-if it does so, new pollen may stick to its back. At this
-time the hairs in the throat dry up, and the fly can leave
-its prison house, Figure <a href='#fig-1'>1 C</a>. If the fly now enters another
-flower this is fertilized by repeating the process. The unfertilized
-flowers stand erect with widely open mouths. As soon
-as they have been fertilized they bend down, as seen in
-<span class='pageno' id='Page_12'>12</span>Figure <a href='#fig-1'>1 A</a>, and at the same time the terminal flap bends over
-the open mouth of the throat, “stopping the entrance to the
-flies, which have now nothing more to do here.”</p>
-<h3 class='c014'><span class='sc'>Adjustments of the Individual to Changes in the Environment</span></h3>
-
-<p class='c015'>The most familiar cases of adjustments of the individual to
-the environment are those that we recognize in our own
-bodies. After violent exercise we breathe more rapidly, and
-take deeper inspirations. Since during exercise our blood
-loses more oxygen and takes in more carbon dioxide from the
-muscles, it is clear that one result of more rapid breathing is
-to get more oxygen into the blood and more carbon dioxide
-out of it. The process of sweating, that also follows exercise,
-may be also looked upon as an adaptive process, since by
-evaporation the skin is kept cooler, and, in consequence, the
-blood, which at this time flows in larger quantities to the skin,
-is cooled also.</p>
-
-<p class='c010'>More permanent adaptive changes than these also take
-place as the result of prolonged use of certain parts. If the
-muscles work against powerful resistance, they become larger
-after several days or weeks, and are capable of doing more
-work than at first. Conversely, when any group of muscles is
-not used, it becomes smaller than the normal and capable of doing
-less work. It would be a nice point to decide whether this
-latter change is also an adaptation. If so it is one in a somewhat
-different sense from that usually employed. The result
-is of no direct advantage to the animal, except possibly in saving
-a certain amount of food, but since the same change will
-take place when an abundance of food is consumed, the result
-is, under these conditions, of no use.</p>
-
-<p class='c010'>The thickening of the skin on those parts of the body where
-continued pressure is brought to bear on it is a change in a
-useful direction. The thickening on the soles of the feet and
-<span class='pageno' id='Page_13'>13</span>on the palms of the hands is a case in point. Not only is the
-skin thicker at birth in these parts, but it becomes thicker
-through use. In other parts of the body also, the skin hardens
-and becomes thicker if pressure is brought to bear on it. We
-may regard this as a general property of the skin, which is
-present even in those parts where, under ordinary circumstances,
-it can rarely or never be brought into use.</p>
-
-<p class='c010'>Even as complicated and as much used an organ as the
-eye can become adaptively improved. It is said that the
-lateral region of the field of vision can be trained to perceive
-more accurately; and every one who has used a microscope
-is familiar with the fact that if one eye is habitually used it
-becomes capable of seeing more distinctly and better than
-the other eye. This seems to be due, in part at least, to the
-greater contraction of the iris.</p>
-
-<p class='c010'>Another phenomenon, which, I think, must be looked upon
-as an adaptation, is the immunity to certain poisons that can
-be gradually brought about by slowly increasing the amount
-introduced into the body. Nicotine is a most virulent poison,
-and yet by slowly increasing the dose an animal can be
-brought into a condition in which an amount of nicotine, fatal
-to an ordinary individual, can be administered without any
-ill effects at all resulting.</p>
-
-<p class='c010'>The same phenomenon has been observed in the case of
-other poisons, not only in case of other alkaloids, such as
-morphine and cocaine, but also in the case of caffein, alcohol,
-and even arsenic. There is a curious phenomenon in regard
-to arsenic, which appears to be well established, viz., that a
-person who has gradually increased the dose to an amount
-great enough to kill ten ordinary men, will die if he suddenly
-ceases altogether to take arsenic. He can, however, be
-gradually brought back to a condition in which arsenic is not
-necessary for his existence, if the dose is gradually decreased.
-It is a curious case of adaptation that we meet with here,
-since the man becomes so thoroughly adjusted to a poison
-<span class='pageno' id='Page_14'>14</span>that if he is suddenly brought back to the normal condition
-of the race he will die.</p>
-
-<p class='c010'>Immunity to the poison of venomous snakes can also be
-acquired by slowly increasing the amount given to an animal.
-It is possible to make a person so immune to the poison of
-venomous snakes that he would become, in a sense, adapted
-to live amongst them without danger to himself. It is to be
-noted, moreover, that this result could be reached only by
-quite artificial means, for, under natural conditions it is inconceivable
-that the nicely graded series of doses of increasing
-strength necessary to bring about the immunity could ever be
-acquired. Hence we find here a case of response in an adaptive
-direction that could not have been the outcome of experience
-in the past. It is important to emphasize this capacity of
-organisms to adapt themselves to certain conditions entirely
-new to them.</p>
-
-<p class='c010'>These cases lead at once to cases of immunity to certain
-bacterial diseases. An animal may become immune to a particular
-disease in several ways. First, by having the disease
-itself, which renders it immune for a longer or a shorter
-period afterwards; or, second, by having a mild form of the
-disease as in the case of smallpox, where immunity is brought
-about by vaccination, <i>i.e.</i> by giving the individual a mild
-form of smallpox; or, third, by introducing into the blood
-an antidote, in the form, for example, of antitoxin, which has
-been made by another animal itself immune to the disease.
-The first two classes of immunity may be looked upon as
-adaptations which are of the highest importance to the organism;
-the last case can scarcely be looked upon as an
-adaptive process, since the injurious effect of the poison may
-as well be neutralized outside of the body by mixing it with the
-antitoxin. We may suppose, then, that in the body a similar
-process goes on, so that the animal itself takes no active part
-in the result.</p>
-
-<p class='c010'>When we consider that there are a number of bacterial
-<span class='pageno' id='Page_15'>15</span>diseases, in each of which a different poison is made by the
-bacteria, we cannot but ask ourselves if the animal really
-makes a counter-poison for each disease, or whether a single
-substance may not be manufactured that counteracts all
-alike? That the latter is not the case is shown by the fact
-that an animal made immune to one disease is not immune
-to others. When we recall that the animal has also the
-capacity to react in one way or another to a large number
-of organic and inorganic poisons, to which it or its ancestors
-can have had little or no previous experience, we may well
-marvel at this wonderful regulative power.</p>
-
-<p class='c010'>The healing of wounds, which takes place in all animals,
-forms another class of adaptive processes. The immense usefulness
-of this power is obvious when it is remembered how
-exposed most animals are to injuries. By repairing the
-injury the animal can better carry on its normal functions.
-Moreover, the presence of the wound would give injurious
-bacteria a ready means of entering the body. In fact, an
-intact skin is one of the best preventives to the entrance
-of bacteria.</p>
-
-<p class='c010'>Not only have most organisms the power of repairing
-injuries, but many animals have also the closely related
-power of regenerating new parts if the old ones are lost.
-If a crab loses its leg, a new one is regenerated. If a fresh-water
-worm (<i>Lumbriculus</i>) is cut into pieces, each piece makes
-a new head at its anterior end and a new tail at the posterior
-end. In this way as many new worms are produced as there
-are pieces. And while in a strict sense it cannot be claimed
-that this power of regeneration is of any use to the original
-worm, since the original worm, as such, no longer exists,
-yet since it has not died but has simply changed over into
-several new worms, the process is of use inasmuch as by this
-means the pieces can remain in existence.</p>
-
-<p class='c010'>We need not discuss here the relative importance to different
-animals of this power of regeneration, but it may be stated,
-<span class='pageno' id='Page_16'>16</span>that, while in some cases it may be necessary to replace the
-lost part if the animal is to remain in existence, as when
-a new head is formed on an earthworm after the old one
-was cut off, in other cases the replacement of the lost part
-appears to be of minor importance, as in the case of the
-leg of the crab. While we are not, for the moment, concerned
-with the relative importance of the different adaptations,
-this question is one of much importance in other
-connections and will be considered later.</p>
-
-<p class='c010'>The protective coloration of some animals, which is the
-direct result of a change in color of the animal in response
-to the surroundings, furnishes us with some most striking
-cases of adaptive coloration. A change of this sort has
-been recorded in a number of fishes, more especially in the
-flounders. The individuals found living on a dark background
-are darker than those living on a lighter background;
-and when the color of the background is changed it has
-been observed that the color of the fish also changes in the
-same direction. I have observed a change of this sort from
-dark to light, or from light to dark, in the common minnow
-(<i>Fundulus</i>) in accordance with a change of its background,
-and the same sort of change appears to take place in many
-other fishes.</p>
-
-<p class='c010'>The change from green to brown and from brown to green
-in certain tree frogs and in the lizard (<i>Anolis</i>), which is
-popularly supposed to take place according to whether the
-background is green or brown, is not after all, it appears,
-connected with the color of the background, but depends on
-certain other responses of the animals that have not yet been
-satisfactorily made out. If it be claimed that in summer
-the animal would generally be warm, and therefore, often
-green, and that this color would protect it at this time of
-year when the surroundings are green, and in winter
-brown, when this color is the prevailing one in temperate
-regions, then it might appear that the change is of use to
-<span class='pageno' id='Page_17'>17</span>the animal; but if it is true that the same change takes
-place in some of the lizards that live in the tropics, where
-the prevailing color is always green, it would appear that
-the result may have no direct relation with the surroundings.
-It has been shown in a number of well-authenticated cases
-that the pupæ of certain butterflies vary in color within
-certain limits in response to the color of the background.
-When the caterpillar fixes itself to some surface, and there
-throws off the outer skin, and acquires a new one, the color
-of the latter is influenced by the background. The result is a
-better protection to the pupa. The change is not brought
-about through the ocelli or eyes, but through the general surface
-of the skin, for the same change takes place when the
-eyes have been previously covered with a dark pigment.</p>
-
-<p class='c010'>The growth of plants toward the light may be looked
-upon as an adaptive process, since only in the light can they
-find the conditions necessary for their life. The extraordinary
-elongation of shoots and young plants when grown
-in the dark may also be considered an adaptation for finding
-the light, since in this way a plant, deeply embedded in the
-ground, may ultimately reach the surface. Thus while the
-actual process of elongation in the dark is not in itself of any
-use, yet under the ordinary conditions of its life, this response
-may be of great benefit to the plant.</p>
-
-<p class='c010'>The closing together of the leaves of some plants has been
-supposed to protect them from too rapid radiation of heat,
-and incidentally this purpose may be fulfilled; but since
-some tropical plants also close their leaves during the night,
-it can hardly be maintained that the closing has been
-acquired for this purpose. It has been suggested that the
-opening of certain flowers under certain conditions of light
-is connected with the visits of insects that bring about cross-fertilization.</p>
-
-<p class='c010'>The preceding examples will suffice to give a general
-idea of what is meant by adaptation in organisms. That
-<span class='pageno' id='Page_18'>18</span>the term includes a large number of phenomena of very
-different kinds is apparent. When we have examined these
-phenomena further we shall find, I think, that it will be necessary
-to put some of them into different categories and
-treat them differently. It is probably incorrect to suppose
-that all processes useful to the organism have been acquired
-in the same way, nevertheless, for the present the term
-adaptation is sufficiently general, even if vague, to cover
-these different groups of cases.</p>
-
-<p class='c010'>It may be asked, in what respects are these structures
-and processes of adaptation different from the ordinary structures
-and changes that go on in the organism? Why is the
-leg of the mole more of an adaptation than that of a dog?
-The one is of as much use as the other to its possessor.
-What reason can we give for citing the poison of the snake,
-and not mentioning in the same connection the other glands
-of the body? In fact, the poison gland of the snake is supposed
-to be a modified superior labial gland. Why, in short,
-are not the processes of digestion, excretion, secretion, the
-beating of the heart, the ordinary reflex acts of the nervous
-system, and the action of the sense-organs, as truly adaptations
-as the special cases that have been selected for illustration.
-The answer is simply that we are more impressed by
-those cases of adaptation that are more unusual, as when an
-animal departs in the use of certain structures from the rest
-of the group to which it belongs. For example, if all mammals
-lived underground, ourselves included, and the fore-legs
-or arms were used for burrowing, we should not think this
-unusual; but if we found an animal using all four legs to
-support the body and for purposes of progression, we
-should, most likely, think this was an excellent illustration of
-adaptation.</p>
-
-<p class='c010'>In other instances the condition is somewhat different.
-The color of certain animals may unquestionably be of use
-to them in concealing them from their enemies. In other
-<span class='pageno' id='Page_19'>19</span>cases the color may not serve this purpose, or any purpose
-at all. Thus while in the former case we speak of the color
-as an adaptation to the surroundings, in the latter we do not
-think of it as having any connection at all with the environment.
-Even in the same animal the color of different parts
-of the body may appear under this twofold relation. For
-example, the green color of the skin of the frog renders it
-less conspicuous amongst the green plants on the edge of
-the stream, but the brilliant orange and black pigment in the
-body-cavity cannot be regarded as of any use to the animal.</p>
-<h3 class='c014'><span class='sc'>Adaptations for the Good of the Species</span></h3>
-
-<p class='c015'>Aside from the class of adaptations that are for the good
-of the individual, there is another class connected solely
-with the preservation of the race. The organs for reproduction
-are the most important examples of this kind. These
-organs are of no use to the individual for maintaining its own
-existence, and, in fact, their presence may even be deleterious
-to the animal. The instincts connected with the use of these
-organs may lead inevitably to the death of the individual,
-as in the case of the California salmon, which, on entering
-fresh water in order to deposit its eggs, dies after performing
-this act.</p>
-
-<p class='c010'>The presence of the organs of reproduction in the individual
-is obviously connected with the propagation of other
-individuals. Indeed in many organisms the life of the
-individual appears to have for its purpose the continuation
-of the race. In a large number of animals the individual
-dies after it has deposited its eggs. The most striking case
-is that of the May-flies, whose life, as mature individuals, may
-last for only a few hours. The eggs are set free by the
-bursting of the abdomen, and the insect dies. The male
-bee also dies after union with the queen. In some annelids,
-the body is also said to burst when the eggs are set free;
-<span class='pageno' id='Page_20'>20</span>and in other forms those parts of the body containing the
-eggs break off, and, after setting free the eggs, die. These
-are extreme cases of what is seen in many animals, namely
-the replacement of the old individuals by a new generation;
-and while in general there is only a loose connection between
-the death of the individual and the consummation of its reproductive
-power, yet the two run a course so nearly parallel
-that several writers have attempted to explain this connection
-as one of racial adaptation.</p>
-
-<p class='c010'>It has also been pointed out that in those higher animals
-that take care of their young after birth, the life of the
-individual does not end with the period of birth of the young,
-but extends at least throughout the time necessary to care
-for the young. It has even been suggested that this lengthening
-of the life period has been acquired on account of its
-use to the species. When, however, as in the case of the vertebrates,
-the young are born at intervals either in great
-numbers at a birth, as in fishes and amphibia, or in lots of
-twos, threes, or fours, as in many birds and mammals, or
-even only one at a time, as in a few birds and in man, it
-will be evident that the relation cannot be so simple as
-has been supposed. It cannot be assumed in these forms that
-the end of the life of the individual is in any way connected
-with the ripening of the last eggs, for, on the contrary,
-hundreds, or even many thousands, of potential eggs may
-be present in the ovaries when the animal is overtaken by
-old age, and its power of reproduction lost.</p>
-
-<p class='c010'>In regard to several of the lower animals, we find, in a number
-of cases where there are accurate data, that the individual
-goes on year after year producing young. Whether
-they ever grow old, in the sense of losing their power of
-reproduction, has not been definitely determined, but there
-is, so far as I know, no evidence to show that such a process
-takes place, and these animals appear to have the power
-of reproducing themselves indefinitely.</p>
-
-<p class='c010'><span class='pageno' id='Page_21'>21</span>The phenomenon of old age (apart from its possible connection
-with the cessation of the power of reproduction),
-which leads to the death of the individual, has been looked
-upon by a few writers as an adaptation of the individual for
-the good of the species. It has been pointed out by these
-writers that the longer an individual lives, the more likely it
-is to become damaged, and if along with this its powers of
-reproduction diminish, as compared with younger individuals,
-then it stands in the way and takes food that might be used
-by other, younger individuals, that are better able to carry on
-the propagation of the race. It is assumed, therefore, that
-the life of the individual has been shortened for the benefit
-of the race. Whether such a thing is probable is a question
-that will also be discussed later. We are chiefly concerned
-here only in recording the different groups of phenomena
-that have been regarded by biologists as adaptations.</p>
-
-<p class='c010'>The so-called secondary sexual characters such as the
-brighter colors of the males, ornaments of different kinds,
-crests, color-pattern, tail feathers, etc., organs of offence and
-of defence used in fighting members of the same species,
-present a rather unique group of adaptations. These characters
-are supposed to be of use to the individual in conquering
-its rivals, or in attracting the females. They may be considered
-as useful to the individual in allowing it to propagate at
-the expense of its rivals, but whether the race is thereby
-benefited is a question that will be carefully considered later.</p>
-
-<p class='c010'>The colors of flowers, that is supposed to attract insects,
-have been already mentioned. The sweet fluid, or nectar,
-secreted by many flowers is sought by insects, which on entering
-the flowers bring about cross-fertilization. Thus while
-the nectar seems to be of no immediate service to the plant itself,
-it is useful to the species in bringing about the fertilization
-of the flowers. The odors of flowers also serve to attract
-insects, and their presence is one of the means by which insects
-find the flowers. This also is of advantage to the race.</p>
-<div>
-  <span class='pageno' id='Page_22'>22</span>
-  <h3 class='c014'><span class='sc'>Organs of Little Use to the Individual</span></h3>
-</div>
-
-<p class='c015'>In every organism there are parts of the body whose
-presence cannot be of vital importance to the individual.
-We may leave out of consideration the reproductive organs,
-since their presence, as has just been stated, is connected
-with the continuation of the race. The rudimentary organs,
-so-called, furnish many examples of structures whose presence
-may be of little or of no use to the individual; in fact,
-as in the case of the appendix in man, the organs may be a
-source of great danger to the individual. In this respect the
-organism is a structure not perfectly adapted to its conditions
-of life, since it contains within itself parts that are of little
-or of no use, which may even lead to its destruction, and may
-often expose it to unnecessary danger. Nevertheless such
-parts are surprisingly infrequent, and their presence is usually
-accounted for on the supposition that in the past these
-organs have been of use, and have only secondarily come to
-play an insignificant part in the functions of the organism.
-Another example of the same thing is found in the rudimentary
-eyes of animals living in the dark, such as the mole
-and several cave animals, fishes, amphibia, and insects.</p>
-
-<p class='c010'>There are still other organs, which cannot be looked upon
-as rudimentary, yet whose presence can scarcely be considered
-as essential to the life of the individual. It is with this
-class that we are here chiefly concerned. For instance, the
-electric organs in some of the rays and fish can hardly
-protect the animal from enemies, even when as highly developed
-as in the torpedo; and we do not know of any other
-essential service that they can perform. Whether the same
-may be also said of the phosphorescent organs of many
-animals is perhaps open in some cases to doubt, but there
-can be little question that the light produced by most of the
-small marine organisms, such as noctiluca, jellyfish, ctenophores,
-copepods, pyrosoma, etc., cannot be of use to these
-<span class='pageno' id='Page_23'>23</span>animals in protecting them from attack. In the case of certain
-bacteria it seems quite evident that the production of
-light can be of no use as such to them. The production of
-light may be only a sort of by-product of changes going on
-in the organism, and have no relation to outside conditions.
-In certain cases, as in the glowworm, it has been supposed
-that the display may serve to bring the sexes together; but
-since the phosphorescent organs are also present in the larval
-stages of the glowworm, and since even the egg itself is said
-to be phosphorescent, it is improbable, in these stages at least,
-that the presence of the light is of service to the organism.</p>
-
-<p class='c010'>It has been pointed out that the colors of certain animals
-may serve to conceal them and may be regarded as an
-adaptation; but it is also true that in many cases the color of
-the whole animal or the color of special parts can be of little
-if any direct use. While it is difficult to show that the
-wonderful patterns and magnificent coloration of many of the
-larger animals are not of service to the animal, however
-sceptical we may be on the subject, yet in the case of many
-microscopical forms that are equally brilliantly colored there
-can be little doubt that the coloration can be of no special
-service to them. If it be admitted that in these small forms
-the color and the color patterns are not protective, we should
-at least be on our guard in ascribing off-hand to larger forms
-a protective value in their coloration, unless there is actual
-proof that it serves some purpose.</p>
-
-<p class='c010'>We also see in other cases that the presence of color need
-not be connected with any use that it bears as such to the
-animal. For instance, the beautiful colors on the inside of
-the shells of many marine snails and of bivalve mollusks,
-can be of no use to the animal that makes the shell, because
-as long as the animal is alive this color cannot be seen from
-the outside. This being the case let us not jump too readily
-to the conclusion that when other shells are colored on the
-outer surface that this must be of use to the mollusk.</p>
-
-<p class='c010'><span class='pageno' id='Page_24'>24</span>In regard to the colors of plants, there are many cases of
-brilliant coloration, which so far as we can see can be of no
-service to the organism. In such forms as the lichens and
-the toadstools, many of which are brilliantly colored, it is
-very doubtful if the color, as such, is of any use to the plant.
-The splendid coloring of the leaves in the autumn is certainly
-of no service to the trees.</p>
-
-<p class='c010'>It should not pass unnoticed in this connection that the
-stems and the trunks of shrubs and of trees and also many
-kinds of fruits and nuts are sometimes highly colored. It
-is true that some of the latter have been supposed to owe
-their color to its usefulness in attracting birds and other
-animals which, feeding on the fruit, swallow the seeds, and
-these, passing through the digestive tract and falling to the
-ground, may germinate. The dissemination of the seeds of
-such plants is supposed to be brought about in this way; and
-since they may be widely disseminated it may be supposed
-that it is an advantage to the plant to have attracted the
-attention of the fruit-eating birds. On the other hand one
-of the most brilliantly colored seeds, the acorn, is too large
-to pass through the digestive tracts of birds, and is, in fact,
-ground to pieces in the gizzard, and in the case of several
-mammals that feed on the acorns, the acorn is crushed by
-the teeth. It would seem, therefore, that its coloration is
-injurious to it rather than the reverse, as it leads to its
-destruction. It has been suggested by Darwin that since
-the acorns are for a time stored up in the crop of the
-bird, the passenger pigeon for example, and since the birds
-may be caught by hawks and killed, the seeds in the crop
-thus become scattered. Consequently it may be, after all,
-of use to the oak to produce colored acorns that attract the
-attention of these pigeons. This suggestion seems too far-fetched
-to consider seriously. In the case of the horse-chestnut
-the rich brown color is equally conspicuous, but
-the nut is too large to be swallowed by any of the ordinary
-<span class='pageno' id='Page_25'>25</span>seed-feeding birds or mammals. Shall we try to account for
-its color on the grounds of the poisonous character of the
-seed? Has it been acquired as a warning to those animals
-that have eaten it once, and been made sick or have died in
-consequence? I confess to a personal repugnance to imaginative
-explanations of this sort, that have no facts of experience
-to support them.</p>
-<h3 class='c014'><span class='sc'>Changes in the Organism that are of No Use to the Individual or to the Race</span></h3>
-
-<p class='c015'>As an example of a change in the organism that is of no
-use to it may be cited the case of the turning white of the
-hair in old age in man and in several other mammals. The
-absorption of bone at the angle of the chin in man, is another
-case of a change of no immediate use to the individual. We
-also find in many other changes that accompany old age,
-processes going on that are of no use to the organism, and
-which may, in the end, be the cause of its death. Such
-changes, for instance, as the loss of the vigor of the muscles,
-and of the nervous system, the weakening of the heart, and
-partial failure of many of the organs to carry out their
-functions. These changes lead sooner or later to the death
-of the animal, in consequence of the breaking down of some
-one essential organ, or to disease getting an easier foothold
-in the body. We have already discussed the possible
-relation of death as an adaptation, but the changes just mentioned
-take place independently of their relation to the death
-of the organism as a whole, and show that some of the normal
-organic processes are not for the good of the individual
-or of the race. In fact, the perversions of some of the most
-deeply seated instincts of the species, as in infanticide, while
-the outcome of definite processes in the organism, are of
-obvious disadvantage to the individual, and the perversion of
-so deeply seated a process as the maternal instinct, leading
-<span class='pageno' id='Page_26'>26</span>to the destruction of the young, is manifestly disadvantageous
-to the race. As soon, however, as we enter the field of so-called
-abnormal developments, the adaptive relation of the
-organism to its environment is very obscure; and yet, as in
-the case of adaptation to poisons, we see that we cannot draw
-any sharp line between what we call normal and what we call
-abnormal development.</p>
-<h3 class='c014'><span class='sc'>Comparison with Inorganic Phenomena</span></h3>
-
-<p class='c015'>The preceding examples and discussion give some idea of
-what is meant by adaptation in living things. In what respects,
-it may be asked, do these adaptations differ from inorganic
-phenomena? The first group of inorganic bodies that challenges
-comparison are machines. These are so constructed
-that they may be said to accomplish a definite purpose, and
-the question arises whether this purpose can be profitably
-compared with the purposefulness of the structure and
-response of organisms. That the two cannot be profitably
-compared is seen at once, when we recall the fact that the
-activity of the machine is of no use to it, in the sense of
-preserving its integrity. The object of the machine is, in
-fact, to perform some useful purpose for the organism that
-built it, namely, for man. Furthermore, the activity of the
-machine only serves to wear it out, and, therefore, its actions
-do not assist in preserving its integrity as do some, at least,
-of the activities of an animal. It is true, of course, that in a
-mechanical sense every action of the organism leads also to a
-breaking down of its structure in the same way that a machine
-is also worn out by use; but the organism possesses another
-property that is absent in the machine, namely, the power of
-repairing the loss that it sustains.</p>
-
-<p class='c010'>One of the most characteristic features of the organism is
-its power of self-adjustment, or of regulation, by which it
-adapts itself to changes in the environment in such a way
-<span class='pageno' id='Page_27'>27</span>that its integrity is maintained. Most machines have no such
-regulative power, although, in a sense, the fly-wheel of an
-engine regulates the speed, and a water-bath, with a thermostat,
-regulates itself to a fixed temperature; but even this
-comparison lacks one of the essential features of the regulation
-seen in organisms, namely, in that the regulation does
-not protect the machine from injury. It may be claimed,
-however, that the safety valve of an engine does fulfil this
-purpose, since it may prevent the engine from exploding.
-Here, in fact, we do find better grounds for comparison, but,
-when we take into account the relation of the regulations in
-the organism to all the other properties of the organism,
-we see that this comparison is not very significant. The
-most essential difference between a machine and an organism
-is the power of reproduction possessed by the latter, which is
-absent in all machines. Here, however, we meet with a
-somewhat paradoxical relation, since the reproductive power
-of organisms cannot be looked upon as an adaptation for the
-continuation of the individual, but rather for the preservation
-of a series of individuals. Hence, in this respect also, we
-cannot profitably compare the individual with a machine, but
-if we make any comparison we should compare all the individuals
-that have come from a single one with a machine.
-In this sense the power of reproduction is a sort of racial
-regulation. A comparison of this sort is obviously empty of
-real significance.</p>
-
-<p class='c010'>The regenerative power of the organism, by means of
-which it may replace a lost part, or by means of which a
-piece may become a new whole, is also something not
-present in machines.</p>
-
-<p class='c010'>In using a machine for comparison we should not leave
-out of sight the fact that machines are themselves the work
-of organisms, and have been made for some purpose useful
-to the organism. They may perform the same purpose for
-which we would use our own hands, for they differ from
-<span class='pageno' id='Page_28'>28</span>parts of the body mainly in that they are made of different
-compounds having different properties, as the above comparisons
-have shown. But the regulations of the machine
-have been added to it by man on account of their usefulness
-to himself, and are not properties of the material of
-which the machine itself is composed. This shows, I think,
-the inappropriateness of making any comparison between
-these two entirely different things.</p>
-
-<p class='c010'>If, then, we find the comparison between machines and
-organisms unprofitable, can we find any other things in
-inorganic nature that can be better compared with the
-phenomenon of adaptation of the organism? The following
-phenomena have been made the subject of comparison from
-time to time. The bendings, which are gradually made by
-rivers often lead to a meeting of the loops, so that a direct,
-new communication is established, and the course of the
-river is straightened out. The water takes, therefore, a
-more direct course to the sea. It cannot be said, however,
-to be of any advantage to the river to straighten its course.
-Again, a glacier moulds itself to its bed, and gradually
-moves around obstacles to a lower level, but this adaptation
-of the glacier to the form of its surroundings cannot be
-said to be of advantage to the glacier. On the contrary,
-the glacier reaches so much the sooner a lower level where
-it is melted.</p>
-
-<p class='c010'>The unusual case of a solid being lighter than the liquid
-from which it forms, as seen in the case of ice, has been
-looked upon as a useful arrangement, since were the reverse
-the case all rivers and ponds would become solid in winter
-in cold climates, and the polar regions would become one
-solid block of ice. But no one will suppose for a moment
-that there is any relation between the anomalous condition
-of the lightness of ice, and its relation to the winter freezing
-of streams, ponds, etc. It has even been suggested that this
-property of ice was given to it in order that the animals
-<span class='pageno' id='Page_29'>29</span>living in the water might not be killed, which would be the
-case if the ice sank to the bottom, but such a method of
-interpreting physical phenomena would scarcely commend
-itself to a physicist.</p>
-
-<p class='c010'>The formation of a covering of oxide over the surface of
-a piece of iron delays the further process of oxidation, but
-who will imagine that this property of iron has been acquired
-in order to prevent the iron from being destroyed by
-oxygen?</p>
-
-<p class='c010'>If a piece is broken from a crystal, and the crystal is
-suspended in a saturated solution of the same substance,
-new material is deposited over its whole surface, and, as it
-grows larger, the broken side is completed and the crystal
-assumes its characteristic form. But of what advantage is
-it to the crystal whether it is complete or incomplete? In
-the case of an animal it is of some importance to be able
-to complete itself after injury, because it can then better
-obtain the food necessary to keep it alive, or it can better
-escape its enemies; but this is not the case with the crystal.</p>
-
-<p class='c010'>In conclusion, therefore, it is obvious that the adaptations
-of organisms are something peculiar to living things, and
-their obvious purpose is to maintain the integrity of the individual,
-or that of the species to which the individual
-belongs. We are, therefore, confronted with the question
-as to how this peculiarity has come to be associated with
-the material out of which living things are made. In subsequent
-chapters this will be fully discussed, but before we
-take up this topic, it will be necessary to reach some understanding
-in regard to the theory of evolution, for the whole
-subsequent issue will turn upon the question of the origin of
-the forms of animals and plants living at the present time.</p>
-
-<div class='pbb'>
- <hr class='pb c006' />
-</div>
-<div class='chapter'>
-  <span class='pageno' id='Page_30'>30</span>
-  <h2 class='c008'>CHAPTER II<br /> <br /><span class='c013'>THE THEORY OF EVOLUTION</span></h2>
-</div>
-<p class='c009'><span class='sc'>One</span> of the most important considerations in connection
-with the problem of adaptation is that in all animals and
-plants the individuals sooner or later perish and new generations
-take their places. Each new individual is formed, in
-most cases, by the union of two germ-cells derived one from
-each parent. As a result of this process of intermixing,
-carried on from generation to generation, all the individuals
-would tend to become alike, unless something else should
-come in to affect the result.</p>
-
-<p class='c010'>So far as our actual experience reaches, we find that the
-succeeding generations of individuals resemble each other.
-It is true that no two individuals are absolutely alike, but if a
-sufficiently large number are examined at a given time, they
-will show about the same variations in about the same proportionate
-numbers. Such a group of similar forms, repeating
-itself in each generation, is the unit of the systematists,
-and is called a species.</p>
-
-<p class='c010'>It has been said that within each species the individuals
-differ more or less from each other, but our experience
-teaches that in each generation the same kinds of variations
-occur, and, moreover, that from any one individual there may
-arise in the next generation any one of the characteristic
-variations. Certain limitations will have to be made in regard
-to this statement, but for the present it will suffice.
-The Law of Biogenesis states that each living thing arises
-from another living thing; that there is no life without antecedent
-life, <i>i.e.</i> spontaneous generation does not occur. The
-<span class='pageno' id='Page_31'>31</span>law is not concerned with the likeness or unlikeness of the different
-individuals that descend from each other. The theory
-of evolution includes the same idea, but in addition it has
-come to mean nowadays, that there have been changes, as
-the succeeding generations have arisen. The transmutation
-theory, and even the descent theory, have come to mean nearly
-the same thing as the theory of evolution. It is unfortunate
-that one of these terms cannot be used to signify simply the
-repetition, generation after generation, of groups of similar
-individuals. The theory of descent might be used to convey
-only this idea, but unfortunately it too has come to include
-also the idea of change. I shall attempt nevertheless to discriminate
-between the descent and the transmutation theory,
-and use the term <i>descent theory</i> when I do not wish to convey
-the idea of change, and <i>transmutation theory</i> when I do
-wish to emphasize this idea.</p>
-
-<p class='c010'>On the transmutation theory it is assumed that a group
-(species) may give rise to one or more groups of forms differing
-from their ancestors; the original group being now replaced
-by its new kinds of offspring, or the old and the new
-may remain in existence at the same time. This process
-repeating itself, each or some of the new groups giving rise in
-turn to one or more new species, there will be produced a larger
-group of species having certain similar characters which are
-due to their common descent. Such a group of species is
-called a genus. The resemblances of these species is
-accounted for by their common descent; but their differences
-must be due to those factors that have caused them to depart
-from the original type. We may now proceed to consider
-the evidence on which this idea of transmutation rests.</p>
-<div>
-  <span class='pageno' id='Page_32'>32</span>
-  <h3 class='c014'><span class='sc'>Evidence in Favor of the Transmutation Theory</span></h3>
-</div>
-
-<div class='nf-center-c0'>
-<div class='nf-center c000'>
-    <div><span class='c016'>EVIDENCE FROM CLASSIFICATION AND FROM COMPARATIVE ANATOMY</span></div>
-  </div>
-</div>
-
-<p class='c010'>It does not require any special study to see that there are
-certain groups of animals and of plants that are more like
-each other than they are like the members of any other group.
-It is obvious to every one that the group known as mammals
-has a combination of characters not found in any other
-group; such, for instance, as a covering of hair, mammary
-glands that furnish milk to the young, and a number of other
-less distinctive features. These and other common characteristics
-lead us to put the mammals into a single class. The
-birds, again, have certain common characters such as feathers,
-a beak without teeth, the development of a shell around the
-egg, etc., and on account of these resemblances we put them
-into another class. Everywhere in the animal and plant
-kingdoms we find large groups of similar forms, such as the
-butterflies, the beetles, the annelidan worms, the corals, the
-snails, the starfishes, etc.</p>
-
-<p class='c010'>Within each of these groups we find smaller groups, in
-each of which there are again forms more like each other
-than like those of other groups. We may call these smaller
-groups families. Within the families we find smaller groups,
-that are more like each other than like any other groups in
-the same family, and these we put into genera. Within the
-genus we find smaller groups following the same rule, and
-these are the species. Here we seem to have reached a limit
-in many cases, for we do not always find within the species
-groups of individuals more like each other than like other
-groups. Although we find certain differences between the
-individuals of a species, yet the differences are often inconstant
-in the sense that amongst the descendants of any individual
-there may appear any one of the other variations.
-If this were the whole truth, it would seem that we had here
-<span class='pageno' id='Page_33'>33</span>reached the limits of classification, the species being the
-unit. This, however, is far from being the case, for, in
-many species we find smaller groups, often confined to
-special localities. These groups are called varieties.</p>
-
-<p class='c010'>In some cases it appears, especially in plants, these
-smaller groups of varieties resemble in many ways the
-groups of species in other forms, since they breed true to
-their kind, even under changed conditions. They have been
-recognized as “smaller species” by a number of botanists.</p>
-
-<p class='c010'>In this connection a point must be brought up that has
-played an important rôle in all discussion as to what limits
-can be set to a species. As a rule it is found that two distinct
-species cannot be made to cross with each other, <i>i.e.</i>
-the eggs of an individual of one species cannot be fertilized
-by spermatozoa derived from individuals of another species;
-or, at least, if fertilization takes place the embryo does not
-develop. In some cases, however, it has been found possible
-to cross-fertilize two distinct species, although the offspring
-is itself more or less infertile. Even this distinction,
-however, does not hold absolutely, for, in a few cases, the
-offspring of the cross is fertile. It cannot be maintained,
-therefore, that this test of infertility between species invariably
-holds, although in a negative sense the test may apply,
-for if two different forms are infertile, <i>inter se</i>, the result
-shows that they are distinct species. If they cross they may
-or may not be good species, and some other test must be
-used to decide their relation.</p>
-
-<p class='c010'>We should always keep in mind the fact that the individual
-is the only reality with which we have to deal, and that the
-arrangement of these into species, genera, families, etc., is
-only a scheme invented by man for purposes of classification.
-Thus there is no such thing in nature as a species, except as
-a concept of a group of forms more or less alike. In nature
-there are no genera, families, orders, etc. These are inventions
-of man for purposes of classification.</p>
-
-<p class='c010'><span class='pageno' id='Page_34'>34</span>Having discovered that it is possible to arrange animals
-and plants in groups within groups, the question arises as to
-the meaning of this relation. Have these facts any other
-significance than that of a classification of geometric figures,
-or of crystals according to the relations of their axes, or of
-bodies as to whether they are solids, liquids, or gases, or even
-whether they are red, white, or blue?</p>
-
-<p class='c010'>If we accept the transmutation view, we can offer an
-explanation of the grouping of living things. According to
-the transmutation theory, the grouping of living things is due
-to their common descent, and the greater or less extent to
-which the different forms have diverged from each other. It
-is the belief in this principle that makes the classification of
-the biologist appear to be of a different order from that in
-any other science; and it is this principle that appears to give
-us an insight into a large number of phenomena.</p>
-
-<p class='c010'>For example, if, as assumed in the theory, a group of
-individuals (species) breaks up into two groups, each of these
-may be supposed to inherit a large number of common characteristics
-from their ancestors. These characters are, of
-course, the resemblances, and from them we conclude that
-the species are related and, therefore, we put them into the
-same genus. The differences, as has been said, between the
-species must be explained in some other way; but the principle
-of classification with which we are here concerned is
-based simply on the resemblances, and takes no account of
-the differences between species.</p>
-
-<p class='c010'>In this argument it has been tacitly assumed that the
-transformation of one species into another, or into more
-than one, takes place by adding one or more new characters
-to those already present, or by changing over a few characters
-without altering others. But when we come to examine
-any two species whatsoever, we find that they differ, not only
-in one or in a few characters, but in a large number of points;
-perhaps in every single character. It is true that sometimes
-<span class='pageno' id='Page_35'>35</span>the differences are so small that it is difficult to distinguish
-between two forms, but even in such cases the differences,
-although small, may be as numerous as when they are more
-conspicuous. If, then, this is what we really find when we
-carefully examine species of animals or of plants, what is
-meant when we claim that our classification is based on the
-characters common to all of the forms that have descended
-from the same ancestor? We shall find, if we press this
-point that, in one sense, there is no absolute basis of this sort
-for our classification, and that we have an unreal system.</p>
-
-<p class='c010'>If this is admitted, does our boasted system of classification,
-based as it is on the principle of descent, give us anything
-fundamentally different from an artificial classification? A
-few illustrations may make clearer the discussion that follows.
-If, for example, we take a definition of the group of vertebrates
-we read: “The group of craniate vertebrates includes
-those animals known as Fishes, Amphibians, Reptiles, Birds,
-and Mammals; or in other words, Vertebrates with a skull, a
-highly complex brain, a heart of three or four chambers, and
-red blood corpuscles.” If we attempt to analyze this definition,
-we find it stated that the skull is a characteristic of all
-vertebrates, but if we ask what this thing is that is called
-skull, we find not only that it is something different in different
-groups, being cartilaginous in sharks, and composed
-of bones in mammals, but that it is not even identical in
-any two species of vertebrates. If we try to define it as a
-case of harder material around the brain, then it is not
-something peculiar to the vertebrates, since the brain of the
-squid is also encased in a cartilaginous skull. What has been
-said of the skull may be said in substance of the brain, of the
-heart, and even of the red blood corpuscles.</p>
-
-<p class='c010'>If we select another group, we find that the birds present
-a sharply defined class with very definite characters. The
-definition of the group runs as follows: “Birds are characterized
-by the presence of feathers, their fore-limbs are
-<span class='pageno' id='Page_36'>36</span>used for flight, the breast-bone is large and serves for the
-attachment of the muscles that move the wings; outgrowths
-from the lungs extend throughout the body and even into the
-bones and serve as air sacs which make the body more buoyant.
-Only one aortic arch is present, the right, and the right
-ovary and oviduct are not developed. The eyes are large
-and well developed. Teeth are absent. We have here a series
-of strongly marked characteristics such as distinguish hardly
-any other class. Moreover, the organization of existing birds
-is, in its essential features, singularly uniform; the entire
-class presenting less diversity of structure than many orders
-of Fishes, Amphibians, and Reptiles.”<a id='r1' /><a href='#f1' class='c017'><sup>[1]</sup></a> The feathers are
-the most unique features of birds, and are not found in any
-other group of the animal kingdom; moreover the plan on
-which they are formed is essentially the same throughout the
-group, yet in no two species are the feathers identical, but
-differ not only in form and proportions, but even in the character
-of the barbs and hooks for holding the vane together.
-The modification of the fore-limbs for flight is another characteristic
-feature; yet in some birds, as the ostrich and kiwi,
-although the wing has the same general plan as in other
-birds, it is not used for flight. In the latter it is so small that
-it does not project beyond the feathers, and in some birds, as
-in the penguins, the wings are used only as organs for swimming.</p>
-
-<div class='footnote c018' id='f1'>
-<p class='c019'><span class='label'><a href='#r1'>1</a>.&nbsp;&nbsp;</span>Parker and Haswell: “Text Book of Zoology.”</p>
-</div>
-
-<p class='c010'>In spite of these differences we have no difficulty in
-recognizing throughout the group of birds a similarity of
-plan or structure, modified though it be in a thousand
-different ways.</p>
-
-<p class='c010'>Enough has been said to illustrate what is meant by the
-similarities of organisms on which we base our system of
-classification. When we conclude from the statement that
-all vertebrates have a skull that they owe this to a common
-descent, we do not mean that a particular structure has been
-<span class='pageno' id='Page_37'>37</span>handed down as a sort of entailed heirloom, but that the
-descendants have followed the same plan of structure as that
-of their ancestors, and have the brain enclosed in a covering
-of harder material, although this material may not have
-exactly the same form, or be made of the same substance in
-all cases. Furthermore while we may recognize that the
-cartilaginous skull of the shark is simpler in structure than
-that of the cartilaginous-bony skull of the frog, and that
-the skull of the frog is simpler than that of the rabbit,
-yet we should not be justified in stating, except in a
-metaphorical sense, that something has been added to the
-skull of the shark to make that of the frog, and something
-to the latter to make that of the rabbit. On the contrary,
-while something may have been added, and the plan
-made more complicated, the skull has also been changed
-throughout in every single part.</p>
-
-<p class='c010'>There is another point of some importance to be taken
-into account in this connection; namely, that each new
-generation begins life as a single cell or egg. The egg
-does not contain any preformed adult structures that it
-hands down unaltered, but it is so constructed that, under
-constant conditions, the same, or nearly the same, kind of
-structure is produced. Should something affect the egg,
-we can imagine that it might form a new combination on
-the same general plan as that of the old, yet one that differed
-from the original in every detail of its structure. It is this
-idea, I believe, that lies at the base of the transmutation
-theory. On some such assumption as this, and on this
-alone, can we bring the theory of transmutation into harmony
-with the facts of observation.</p>
-
-<p class='c010'>What has been said in regard to individuals as a whole
-may be repeated also in respect to the study of the single
-organs. Selecting any one group of the animal or plant
-kingdom, we find the same organ, or the same combination
-of organs present in whole groups of forms. We can often
-<span class='pageno' id='Page_38'>38</span>arrange these organs in definite series passing from the
-simple to the complex, or, in case of degeneration, in the
-reverse order. However convenient it may be to study
-the structure of organisms from this point of view, the artificiality
-of the procedure will be obvious, since here also the
-organs of any two species do not differ from each other in
-only one point, but in many, perhaps in all. Therefore to
-arrange or to compare them according to any one scheme
-gives only an incomplete idea of their structure. We should
-apply here the same point of view that we used above in
-forming a conception of the meaning of the zoological and
-botanical systems. We must admit that our scheme is only
-an ideal, which corresponds to nothing real in nature, but
-is an abstraction based on the results of our experience.
-It might be a pleasing fancy to imagine that this ideal
-scheme corresponds to the plan of structure or of organization
-that is in every egg, and furnishes the basis for all the
-variations that have come or may come into existence; but
-we should find no justification whatsoever for believing that
-our fiction corresponds to any such real thing.</p>
-
-<p class='c010'>To sum up the discussion: we find that the resemblances
-of animals and plants can be accounted for on the transmutation
-theory, not in the way commonly implied, but in a somewhat
-different sense. We have found that the resemblances
-between the different members of a group are only of a
-very general sort, and the structures are not identically the
-same in any two species—in fact, perhaps in no two individuals.
-This conclusion, however, does not stand in contradiction
-to the transmutation hypothesis, because, since
-each individual begins as an egg which is not a replica of
-the original adult from which it is derived, there can be no
-identity, but at most a very close similarity. Admitting, then,
-that our scheme is an ideal one, we can claim, nevertheless,
-that on this basis the facts of classification find a legitimate
-explanation in the transmutation theory.</p>
-<div>
-  <span class='pageno' id='Page_39'>39</span>
-  <h3 class='c014'>THE GEOLOGICAL EVIDENCE</h3>
-</div>
-
-<p class='c015'>On the theory of descent, as well as on the theory of
-transmutation, the ancestors of all present forms are supposed
-to have lived at some time in the past on the surface
-of the earth. If, therefore, their remains should have been
-preserved, we should expect on the descent theory to find
-some, at least, of these remains to be like present forms,
-while on the transmutation theory we should expect to find
-most, if not all, of the ancestral forms to be different from
-the present ones.</p>
-
-<p class='c010'>The evidence shows that fossil forms are practically all
-different from living forms, and the older they are the
-greater the difference from present forms. In general,
-therefore, it may be said that the evidence is in favor of the
-transmutation theory. It can scarcely be claimed that the
-evidence is absolutely conclusive, however probable it may
-appear, for the problem is complicated in a number of ways.</p>
-
-<p class='c010'>In the first place, there is convincing evidence that some
-forms have been entirely exterminated. Other groups have
-very few living representatives, as is the case in the group
-containing nautilus, and in that of the crinoids. It is therefore
-always possible that a given fossil form may represent
-an extinct line, and may be only indirectly connected with
-forms alive at the present time. Again the historical record
-is so broken and incomplete in all but a few cases that its
-interpretation is largely a question of probability. We can
-easily conceive that it would be only in very exceptional
-cases that successive generations of the same form would be
-buried one above the other, so that we should find the
-series unbroken. This is evident not only because the conditions
-that were at one time favorable for the preservation
-of organic remains might not be favorable at another time,
-but also because if the conditions remained the same the
-organisms themselves might also remain unchanged. A new
-<span class='pageno' id='Page_40'>40</span>form, in fact, would be, <i>ex hypothese</i>, better suited to live
-in a different environment, and consequently we should not
-expect always to find its remains in the same place as that
-occupied by the parent species. This possibility of migration
-of new forms into a new locality makes the interpretation
-of the geological record extremely hazardous.</p>
-
-<p class='c010'>Nevertheless, if the evolution of the entire animal and
-plant kingdoms had taken place within the period between
-the first deposits of stratified rocks and the present time, we
-might still have expected to find, despite the imperfections
-of the record, sufficient evidence to show how the present
-groups have arisen, and how they are related to one another.
-But, unfortunately, at the period when the history of the
-rocks begins, nearly all the large groups of animals were
-in existence, and some of them, indeed, as the trilobites
-and the brachiopods, appear to have reached the zenith of
-their development.</p>
-
-<p class='c010'>On the other hand, the subdivisions of the group of vertebrates
-have evolved during the period known to us. It is
-true that the group was already formed when our knowledge
-of it begins, but, from the fishes onwards, the history of the
-vertebrates is recorded in the rocks. The highest group of
-all, the mammals, has arisen within relatively modern times.
-The correctness of the transmutation theory could be as well
-established by a single group of geological remains as by the
-entire animal kingdom. Let us, therefore, examine how far
-the theory is substantiated by the paleontological record of the
-vertebrates. We find that the earliest vertebrates were fishes,
-and these were followed successively by the amphibians,
-reptiles, birds, and mammals, one of the last species of all
-to appear being man himself. There can be little doubt that
-this series, with certain limitations to be spoken of in a moment,
-represents a progressive series beginning with the simpler
-forms and ending with the more complicated. Even did we
-not know this geological sequence we would conclude, from
-<span class='pageno' id='Page_41'>41</span>the anatomical evidence alone, that the progression had been
-in some such order as the geological record shows. The
-limitation referred to above is this: that while the mammals
-arose later than the birds, we need not suppose that the
-mammals arose from the birds, and not even perhaps from
-the reptiles, or at least not from reptiles like those living
-at the present day. The mammals may in fact, as some
-anatomists believe, have come direct from amphibian-like
-forms. If this is the case, we find the amphibians giving rise
-on one hand to reptiles and these to birds, and on the other
-hand to mammals.</p>
-
-<p class='c010'>This case illustrates how careful we should be in interpreting
-the record, since two or more separate branches or orders
-may arise independently from the same lower group. If the
-mammals arose from the amphibians later than did the reptiles,
-it would be easy to make the mistake, if the record was
-incomplete at this stage, of supposing that the mammals had
-come directly from the reptiles.</p>
-
-<p class='c010'>That the birds arose as an offshoot from reptile-like forms
-is not only probable on anatomical grounds, but the geological
-record has furnished us with forms like archæopteryx,
-which in many ways appears to stand midway between
-the reptiles and birds. This fossil, archæopteryx, has a bird-like
-form with feathered wings, and at the same time has a
-beak with reptilian teeth, and a long, feathered tail with a
-core of vertebræ.</p>
-
-<p class='c010'>From another point of view we see how difficult may be
-the interpretation of the geological record, when we recall
-that throughout the entire period of evolution of the vertebrates
-the fishes, amphibians, reptiles, and birds remained still
-in existence, although they, or some of them, may have at
-one time given origin to new forms. In fact, all these groups
-are alive and in a flourishing condition at the present time.
-The fact illustrates another point of importance, namely, that
-we must not infer that because a group gives rise to a higher
-<span class='pageno' id='Page_42'>42</span>one, that it itself goes out of existence, being exterminated
-by the new form. There may be in fact no relation whatsoever
-between the birth of a new group and the extermination
-of an old one.</p>
-
-<p class='c010'>On the transmutation theory we should expect to find not
-only a sequence of forms, beginning with the simplest and
-culminating with the more complex, but also, in the beginning
-of each new group, forms more or less intermediate in
-structure. It is claimed by all paleontologists that such
-forms are really found. For example, transitional forms
-between the fishes and the amphibia are found in the group
-of dipnoans, or lung-fishes, a few of which have survived to
-the present day. There are many fossil forms that have
-characters between those of amphibians and reptiles, which
-if not the immediate ancestors of the reptiles, yet show
-that at the time when this group is supposed to have
-arisen intermediate forms were in existence. The famous
-archæopteryx remains have been already referred to above,
-and it appears in this case that we have not only an intermediate
-form, but possibly a transitional one. In the group
-of mammals we find that the first forms to appear were the
-marsupials, which are undoubtedly primitive members of the
-group.</p>
-
-<p class='c010'>The most convincing evidence of transmutation is found in
-certain series of forms that appear quite complete. The
-evolution of the horse series is the most often cited. As this
-case will be discussed a little later, we need not go into it
-fully here. It will suffice to point out that a continuous
-series of forms has been found, that connect the living
-horses having a single toe through three-toed, with the five-toed
-horses. Moreover, and this is important, this series
-shows a transformation not only in one set of structures, but
-in all other structures. The fossil horses with three toes are
-found in the higher geological layers, and those with more
-toes in the deeper layers progressively. In some cases, at
-<span class='pageno' id='Page_43'>43</span>least, the fossils have been found in the same part of the
-world, so that there is less risk of arranging them arbitrarily
-in a series to fit in with the theory.</p>
-<h3 class='c014'>EVIDENCE FROM DIRECT OBSERVATION AND EXPERIMENT</h3>
-
-<p class='c015'>Within the period of human history we do not know of a
-single instance of the transformation of one species into
-another one, if we apply the most rigid and extreme tests
-used to distinguish wild species from each other.<a id='r2' /><a href='#f2' class='c017'><sup>[2]</sup></a> It may
-be claimed that the theory of descent is lacking, therefore,
-in the most essential feature that it needs to place the
-theory on a scientific basis. This must be admitted. On
-the other hand, the absence of direct observation is not
-fatal to the hypothesis, for several reasons. In the first
-place, it is only within the last few hundred years that
-an accurate record of wild animals and plants has been kept,
-so that we do not know except for this period whether any
-new species have appeared. Again, the chance of observing
-the change might not be very great, especially if the change
-were sudden. We would simply find a new species, and
-could not state where it had come from. If, on the other
-hand, the change were very slow, it might extend over so
-many years that the period would be beyond the life of an
-individual man. In only a few cases has it been possible
-to compare ancient pictures of animals and plants with their
-prototypes living at the present time, and it has turned out
-in all cases that they are the same. But these have been
-almost entirely domesticated forms, where, even if a change
-had been found, it might have been ascribed to other factors.
-In other cases, as in the mummified remains of a few
-Egyptian wild animals (which have also been found to be
-exactly like the same animals living at the present day),
-<span class='pageno' id='Page_44'>44</span>it was pointed out by Geoffroy Saint-Hilaire that, since the
-conditions of the Egyptian climate are the same to-day as
-they were two thousand years ago, there is no reason to
-expect any change would have taken place. But waiving
-this assumption, we should not forget that the theory of evolution
-does not postulate that a change must take place
-in the course of time, but only that it may take place
-sometimes.</p>
-
-<div class='footnote c018' id='f2'>
-<p class='c019'><span class='label'><a href='#r2'>2</a>.&nbsp;&nbsp;</span>The transformation of “smaller species,”
-described by De Vries, will be described in a later
-chapter.</p>
-</div>
-
-<p class='c010'>The position that we have here taken in regard to the
-lack of evidence as to the transformation of species is, perhaps,
-extreme, for, as will be shown in some detail in later
-chapters, there is abundant evidence proving that species
-have been seen to change greatly when the conditions surrounding
-them have been changed; but never, as has been
-stated, so far, or rather in such a way, that an actual new
-species that is infertile with the original form has been produced.
-Whether, after all, these changes due to a change
-in the environment are of the kind that makes new species,
-is also a question to be discussed later.</p>
-
-<p class='c010'>The experimental evidence, in favor of the transformation
-of species, relates almost entirely to domesticated forms, and
-in this case the conscious agency of man seems, in some cases,
-to have played an important part; but here, even with the
-aid of the factor of isolation, it cannot be claimed that a
-single new species has been produced, although great
-changes in form have been effected. It is clear, therefore,
-that we must, at present, rely on other data, less satisfactory
-in all respects, to establish the probability of the theory
-of transformation.</p>
-<h3 class='c014'>MODERN CRITICISM OF THE THEORY OF EVOLUTION</h3>
-
-<p class='c015'>Throughout the whole of the nineteenth century a steady
-fire of criticism was directed against the theory of evolution;
-the names of Cuvier and of Louis Agassiz stand out preëminent
-<span class='pageno' id='Page_45'>45</span>in this connection, yet the theory has claimed an ever
-increasing number of adherents, until at the present time it
-is rare to find a biologist who does not accept in one form or
-another the general principle involved in the theory. The
-storm of criticism aroused by the publication of Darwin’s
-“Origin of Species,” was directed more against the doctrine
-of evolution than against Darwin’s argument for natural selection.
-The ground has been gone over so often that there
-would be little interest in going over it again. It will be more
-profitable to turn our attention to the latest attack on the
-theory from the ranks of the zoologists themselves.</p>
-
-<p class='c010'>Fleischmann, in his recent book, “Die Descendenztheorie,”
-has made a new assault on the theory of evolution from the
-three standpoints of paleontology, comparative anatomy, and
-embryology. His general method is to try to show that the
-recognized leaders in these different branches of biology
-have been led to express essentially different views on
-the same questions, or rather have compromised the doctrine
-by the examples they have given to illustrate it.
-Fleischmann is fond of bringing together the antiquated
-and generally exaggerated views of writers like Haeckel,
-and contrasting them with more recent views on the same
-subject, without making sufficient allowances for the advances
-in knowledge that have taken place. He selects
-from each field a few specific examples, by means of
-which he illustrates the weakness, and even, as he believes,
-the falsity of the deductions drawn for the particular
-case. For example, the plan of structure of the
-vertebrates is dealt with in the following way: In this
-group the limbs, consisting typically of a pair of fore-legs
-and a pair of hind-legs, appear under the form of
-cylindrical outgrowths of the body. In the salamander,
-in the turtle, in the dog, the cylindrical legs, supporting
-the body and serving to support it above the ground, are
-used also for progression. The general purpose to which
-<span class='pageno' id='Page_46'>46</span>the limbs are put as organs of locomotion has not interfered
-with an astonishing number of varieties of structure,
-adapted to different conditions of existence, such as
-the short legs used for creeping in salamanders, lizards,
-turtles, crocodiles; the long and thin legs of good runners,
-as the hoofed animals; the mobile legs of the apes used for
-climbing; and the parachute legs of some squirrels used for
-soaring. Even more striking is the great variety of hands
-and feet, as seen in the flat, hairy foot of the bear; the
-fore-foot of the armadillos, carrying long, sickle-shaped
-claws; the digging foot of the mole; the plump foot of
-the elephant, ending in a broad, flat pad with nails around
-the border, and without division into fingers; the hand of
-man and of the apes ending with fine and delicate fingers
-for grasping. To have discovered a general plan of structure
-running through such a great variety of forms was
-proclaimed a triumph of anatomical study.<a id='r3' /><a href='#f3' class='c017'><sup>[3]</sup></a></p>
-
-<div class='footnote c018' id='f3'>
-<p class='c019'><span class='label'><a href='#r3'>3</a>.&nbsp;&nbsp;</span>This paragraph is a free translation of Fleischmann’s text.</p>
-</div>
-
-<p class='c010'>A study of the bony structure of the limb shows that typically
-it consists of a single proximal bone (the humerus in
-the upper arm, the femur in the thigh), followed by two
-bones running parallel to each other (the radius and ulna in
-the arm and the tibia and fibula in the shank); these are
-succeeded in the arm by the two series of carpal bones, and
-in the leg by the two series of tarsal bones, and these are
-followed in each by five longer bones (the metacarpals and
-metatarsals), and these again by the series of long bones
-that lie in the fingers and toes. Despite the manifold variety
-of forms, Fleischmann admits that both the hind- and the
-fore-limbs are constructed on the same plan throughout the
-vertebrates. Even forms like the camel, in which there are
-fewer terminal bones, may be brought into the same category
-by supposing a reduction of the bones to have taken place,
-so that three of the digits have been lost. In the leg of
-the pig and of the reindeer, even a greater reduction may
-<span class='pageno' id='Page_47'>47</span>be supposed to have taken place. Fleischmann points out
-that these facts were supposed to be in full harmony with
-the theory of descent.</p>
-
-<p class='c010'>The analysis of the origin of the foot of the horse gave
-even better evidence, it was claimed, in favor of the theory.
-The foot consists of a single series of bones corresponding
-to the middle finger and toe. When, as sometimes happens,
-individual horses are found in which in addition to the single
-middle finger two smaller lateral fingers with small hoofs
-appear, the followers of the descent theory rejoiced to be able
-to bring this forward as a confirmation of their doctrine.
-The occurrence was explained as a sporadic return to an
-ancestral form. The naïve exposition of the laws of inheritance
-that were supposed to control such phenomena
-was accepted without question. And when finally a large
-number of fossil remains were found by paleontologists,—remains
-showing a gradual increase in the middle finger,
-and a decrease in size of the lateral fingers,—it was supposed
-that the proof was complete; and anatomists even
-went so far as to hold that the original ancestor of the
-horse was a five-fingered animal.</p>
-
-<p class='c010'>This same law of type of structure was found to extend to
-the entire vertebrate series, and the only plausible explanation
-appeared to be that adopted by Darwin and his followers,
-namely, that the resemblance is the result of the
-blood-relationship of the different forms. But a simple comparison
-of the skeleton of the limbs if carried out without
-theoretical prejudice would show, Fleischmann thinks, that
-there is only a common style, or plan of structure, for the
-vertebrates. This anatomical result has about the same
-value as the knowledge of the different styles of historical
-architecture—that, for instance, all large churches of the
-Gothic period have certain general principles in common.
-The believers in the theory of descent have, however, he
-thinks, gone beyond the facts, and have concluded that the
-<span class='pageno' id='Page_48'>48</span>common plan in animals is the consequence of a common
-descent. “I cannot see the necessity for such a conclusion,
-and I certainly should unhesitatingly deny that the common
-plan of the Gothic churches depended on a common architect.
-The illustration is, however, not perfect, because the
-influence of the mediæval school of stone-cutters on its wandering
-apprentices is well known.”</p>
-
-<p class='c010'>Fleischmann adds that if the descent theory is true we
-should expect to find that if a common plan of structure is
-present in one set of organs, as the limbs, it should be present
-in all other organs as well, but he does not add that this
-is generally the case.</p>
-
-<p class='c010'>The weakness of Fleischmann’s argument is so apparent
-that we need not attempt an elaborate refutation. When he
-says there is no absolute proof that the common plan of
-structure must be the result of blood-relationship, he is not
-bringing a fatal argument against the theory of descent, for
-no one but an enthusiast sees anything more in the explanation
-than a very probable theory that appears to account for
-the facts. To demand an absolute proof for the theory is to
-ask for more than any reasonable advocate of the descent
-theory claims for it. As I have tried to show in the preceding
-pages, the evidence in favor of the theory of descent
-is not absolutely demonstrative, but the theory is the most
-satisfactory one that has as yet been advanced to account
-for the facts. Fleischmann’s reference to the common plan
-of structure of the Gothic churches is not very fortunate for
-his purpose, since he admits himself that this may be the
-result of a common tradition handed down from man to man,
-a sort of continuity that is not very dissimilar in principle from
-that implied in the descent theory; in the latter the continuity
-of substance taking the place of the tradition in the other.
-Had the plan for each, or even for many of the churches,
-originated independently in the mind of each architect, then
-the similarity in style would have to be accounted for by a
-<span class='pageno' id='Page_49'>49</span>different sort of principle from that involved in the theory
-of descent; but as a matter of fact the historical evidence
-makes it probable that similar types of architecture are
-largely the result of imitation and tradition. Certain variations
-may have been added by each architect, but it is just
-the similarity of type or plan that is generally supposed to
-be the outcome of a common tradition.</p>
-
-<p class='c010'>Fleischmann’s attempt in the following chapter to belittle
-Gegenbaur’s theory of the origin of the five-fingered type of
-hand from a fin, like that of a fish, need not detain us, since
-this theory is obviously only a special application which like
-any other may be wrong, without in the least injuring the
-general principle of descent. That all phylogenetic questions
-are hazardous and difficult is only too obvious to any one
-familiar with the literature of the last thirty years.</p>
-
-<p class='c010'>Fleischmann devotes a long chapter to the geological evidences
-in connection with the evolution of the horse, and
-attempts to throw ridicule on the conclusions of the paleontologists
-by emphasizing the differences of opinion that have
-been advanced in regard to the descent of this form. After
-pointing out that the horse, and its few living relatives, the
-ass and the zebra, are unique in the mammalian series in
-possessing a single digit, he shows that by the discovery of
-the fossil horses the group has been simply enlarged, and
-now includes horses with one, three, and five toes. The
-discovery of the fossil forms was interpreted by the advocates
-of the descent theory as a demonstration of the theory. The
-series was arranged by paleontologists so that the five-toed
-form came first, then those with three and one toe, the
-last represented by the living horses. But the matter was
-not so simple, Fleischmann points out, as it appeared to
-be to the earlier writers, for example to Haeckel, Huxley,
-Leidy, Cope, Marsh. Different authors came to express
-different opinions in regard to the genealogical connection
-between the fossil forms. Several writers have tried to show
-<span class='pageno' id='Page_50'>50</span>that the present genus, Equus, has not had a single line of
-descent, but have supposed that the European horses and
-the original American horses had different lines of ancestry,
-which may have united only far back in the genus Epihippus.
-Fleischmann points out that the arrangement of the series
-is open to the criticism that it is arbitrary, and that we could
-equally well make up an analogous series beginning with the
-five-fingered hand of man, then that of the dog with the
-thumb incompletely developed, then the four-fingered hind-foot
-of the pig without a big toe and with a weak second and
-fifth digit, then the foot of the camel with only two toes,
-and lastly the foot of the horse with only one toe. It sounds
-strange that Fleischmann should make such a trivial reply as
-this, and deliberately ignore the all-important evidence with
-which he is, of course, as is every zoologist, perfectly conversant.
-Not only are there a hundred other points of
-agreement in the horse series, but also the geological
-sequence of the strata, in which some at least of the series
-have been found, shows that the arrangement is not arbitrary,
-as he implies.</p>
-
-<p class='c010'>Fleischmann then proceeds to point out that when the
-evidence from other parts of the anatomy is taken into
-account, it becomes evident that all the known fossil remains
-of horses cannot be arranged in a single line, but
-that there are at least three families or groups recognizable.
-Many of these forms are known only from fragments of their
-skeletons—a few teeth, for instance, in the case of Merohippus,
-which on this evidence alone has been placed at
-the uniting point of two series. At present about eight different
-species of living horses are recognized by zoologists,
-and paleontological evidence shows only that many other
-species have been in existence, and that even three- and one-toed
-forms lived together at the same time.</p>
-
-<p class='c010'>Fleischmann also enters a protest against the ordinary
-arrangement of the fossil genera Eo-, Oro-, Meso-, Merohippus
-<span class='pageno' id='Page_51'>51</span>in a series, for these names stand not for single species,
-but for groups containing no less than six species under
-Protohippus, fourteen under Equus, twelve under Mesohippus,
-and twenty under Hipparion. Fleischmann concludes: “The
-descent of the horses has not been made out with the precision
-of an accurate proof, and it will require a great deal of work
-before we get an exact and thorough knowledge of the fossil
-forms. What a striking contrast is found on examination between
-the actual facts and the crude hopes of the apostles
-of the descent theory!...”</p>
-
-<p class='c010'>In so far as this criticism of Fleischmann’s applies to the
-difficulties of determining the past history of the horse, it may
-be granted that he has scored a point against those who have
-pretended that the evidence is simple and conclusive; but we
-should not fail to remember that this difficulty has been felt
-by paleontologists themselves, who have been the first to call
-attention to the complexity of the problem, and to the difficulties
-of finding out the actual ancestors of the living
-representative of the series. And while we may admit that
-the early enthusiasts exaggerated, unintentionally, the importance
-of the few forms known to them, and went too far
-in supposing that they had found the actual series of ancestors
-of living horses, yet we need not let this blind us to the
-importance of the facts themselves. Despite the fact that it
-may be difficult and, perhaps, in most cases, impossible, to
-arrange the fossil forms in their relations to one another and
-to living forms, yet on an unprejudiced view it will be clear,
-I think, that so far as the evidence goes it is in full harmony
-with the theory of descent. This is especially evident if we
-turn our attention to a part of the subject that is almost
-entirely ignored by Fleischmann, and yet is of fundamental
-importance in judging of the result. The series of forms
-beginning with the five-toed horses and ending with those
-having a single toe has not been brought together haphazard,
-as Fleischmann’s comparison might lead one to suppose, but
-<span class='pageno' id='Page_52'>52</span>the five-fingered forms are those from the older rocks, and
-the three-toed forms from more recent layers. The value
-of this kind of evidence might have been open to greater
-doubt had the series been made up of forms found scattered
-over the whole world, for it is well known how difficult it is
-to compare in point of time the rocks of different continents.
-But in certain parts of the world, especially in North America,
-series of fossil horses have been found in sedimentary deposits
-that appear to be perfectly continuous. This series,
-by itself, and without regard to the point as to whether in
-other parts of the world other series may exist, shows exactly
-those results which the theory of descent postulates, and we
-find here, in all probability, a direct line of descent. While it
-may be freely admitted that no such series can demonstrate
-the theory of descent with absolute certainty, yet it would be
-folly to disregard evidence as clear as this.</p>
-
-<p class='c010'>In regard to the other point raised by Fleischmann
-concerning the large number of species of fossil horses that
-have existed in past times, it is obvious that while this greatly
-increases the difficulty of the paleontologist it is not an
-objection to the descent theory. In fact, our experience with
-living species would lead us to expect that many types have
-been represented at each geological period by a number of
-related species that may have inhabited the same country. On
-the descent theory, one species only in each geological period
-could have been in the line of descent of the present species
-of horse. The difficulty of determining which species (if
-there were several living in a given epoch) is the ancestor
-of the horse is increased, but this is not in itself an objection
-to the theory.</p>
-
-<p class='c010'>The descent of birds from flying reptiles is used by
-Fleischmann as another point of attack on the transmutation
-theory. The theory postulates that the birds have come
-from ancestors whose fore-legs have been changed into
-highly specialized wings. The long vertebrated tail of the
-<span class='pageno' id='Page_53'>53</span>ancestral form is supposed to have become very short, and
-long feathers to have grown out from its stump which act
-as a rudder during flight. Flying reptiles with winged fore-legs
-and a long vertebrated tail have been actually found as
-fossil remains, as seen in the pterodactyls and in the famous
-archæopteryx. The latter, which is generally regarded either
-as the immediate ancestor of living birds, or at least as a
-closely similar form, possessed a fore-leg having three fingers
-ending in claws, and feathers on the forearm similar to those
-of modern birds. It had a long tail, like that of a lizard, but
-with well-developed feathers along its sides. It had pointed
-teeth in the horn-covered jaws. Fleischmann proceeds to point
-out that the resemblance of the hand of archæopteryx to
-that of the reptiles is not very close, for two fingers are
-absent as in modern birds. The typical form of the foot is
-that of the bird, and is not the simple reptilian type of structure.
-Feathers and not scales cover the body, and give no
-clew as to how the feathers of birds have arisen. He concludes,
-therefore, that archæopteryx, having many true bird-like
-characters, such as feathers, union of bones in the foot,
-etc., has other characters not possessed by living birds,
-namely, a long, vertebrated tail, a flat breastbone, biconcave
-vertebræ, etc. Therefore, it cannot be regarded as an intermediate
-form. Fleischmann does not point out that it is just
-these characters that would be postulated on the descent
-theory for the ancestor of the birds, if the latter arose from
-reptiles. Even if it should turn out that archæopteryx is
-not the immediate forefather of living birds, yet the discovery
-that a form really existed intermediate in many
-characters between the reptiles and the birds is a gain for
-the transmutation theory. It is from a group having such
-characters that the theory postulates that the birds have been
-evolved, and to have discovered a member of such a group
-speaks directly and unmistakably in favor of the probability
-of the transmutation theory.</p>
-
-<p class='c010'><span class='pageno' id='Page_54'>54</span>Fleischmann again fails to point out that the geological
-period in which the remains of archæopteryx were found,
-is the one just before that in which the modern group of
-birds appeared, and, therefore, exactly the one in which the
-theory demands the presence of intermediate forms. This
-fact adds important evidence to the view that looks upon
-archæopteryx as a form belonging to a group from which
-living birds have arisen. That a number of recent paleontologists
-believe archæopteryx to belong to the group of
-birds, rather than to the reptiles, or to an intermediate group,
-does not in the least lessen its importance, as Fleischmann
-pretends it does, as a form possessing a number of reptilian
-characters, such as the transmutation theory postulates for
-the early ancestors of the birds.</p>
-
-<p class='c010'>The origin of the mammalian phylum serves as the text
-for another attack on the transmutation theory. Fleischmann
-points out that the discovery of the monotremes, including
-the forms ornithorhynchus and echidna, was hailed at first as
-a demonstration of the supposed descent of the mammals from
-a reptilian ancestor. The special points of resemblance between
-ornithorhynchus and reptiles and birds are the complete
-fusion of the skull bones, the great development of
-the vertebræ of the neck region, certain similarities in the
-shoulder girdle, the paired oviducts opening independently
-into the last part of the digestive tract (cloaca), and the
-presence of a parchment-like shell around the large, yolk-bearing
-egg. These are all points of resemblance to reptiles
-and birds, and were interpreted as intermediate stages between
-the latter groups and the group of mammals. In
-addition to these intermediate characters, ornithorhynchus
-possesses some distinctive, mammalian features—mammary
-glands and hair, for instance. Fleischmann takes the ground,
-in this case, that there are so many points of difference between
-the monotremes and the higher mammals, that it is
-impossible to see how from forms like these the higher
-<span class='pageno' id='Page_55'>55</span>groups could have arisen, and that ornithorhynchus cannot
-be placed as an intermediate form, a link between saurians
-and mammals, as the followers of the transmutation theory
-maintain. He shows, giving citations, that anatomists themselves
-are by no means in accord as to the exact position of
-ornithorhynchus in relation to the higher forms.</p>
-
-<p class='c010'>In reply to this criticism, the same answer made above for
-archæopteryx may be repeated here, namely, that because certain
-optimists have declared the monotremes to be connecting
-forms, it does not follow that the descent theory is untrue, and
-not even that these forms do not give support to the theory,
-if in a less direct way. I doubt if any living zoologist regards
-either ornithorhynchus or echidna as the ancestral form from
-which the mammals have arisen. But on the other hand it
-may be well not to forget that these two forms possess many
-characters intermediate between those of mammals and reptiles,
-and it is from a group having such intermediate characters
-that we should expect the mammals to have arisen. These
-forms show, if they show nothing else, that it is possible for a
-species to combine some of the characters of the reptiles with
-those of the mammals; and the transmutation theory does no
-more than postulate the existence at one time of such a group,
-the different species of which may have differed in a number
-of points from the two existing genera of monotremes.</p>
-
-<p class='c010'>The origin of lung-bearing vertebrates from fishlike ancestors,
-in which the swim-bladder has been changed into lungs,
-has been pointed to by the advocates of the transmutation
-theory as receiving confirmation in the existence of animals
-like those in the group of dipnoan fishes. In these animals
-both gills and a swim-bladder, that can be used as a lung, are
-present; and through some such intermediate forms it is
-generally supposed that the lung-bearing animals have arisen.
-Fleischmann argues, however, that, on account of certain
-trivial differences in the position of the duct of the swim-bladder
-in living species, the supposed comparison is not to
-<span class='pageno' id='Page_56'>56</span>the point; but the issue thus raised is too unimportant to
-merit further discussion. Leaving aside also some even more
-doubtful criticisms which are made by Fleischmann, and
-which might be added to indefinitely without doing more
-than showing the credulity of some of the more ardent
-followers of the transmutation theory, or else the uncertainty
-of some of the special applications of the theory, let us pass
-to Fleischmann’s criticism of the problem of development.<a id='r4' /><a href='#f4' class='c017'><sup>[4]</sup></a></p>
-
-<div class='footnote c018' id='f4'>
-<p class='c019'><span class='label'><a href='#r4'>4</a>.&nbsp;&nbsp;</span>The long argument of Fleischmann in regard to the origin of the fresh-water
-snails, as illustrated by the planorbis series, and also the origin of the
-nautiloid group, has been recently dealt with fully by Plate, and, therefore, need
-not be considered here.</p>
-</div>
-
-<p class='c010'>With fine scorn Fleischmann points to the crudity of the
-ideas of Oken and of Haeckel in regard to the embryology
-(or the ontogeny) repeating the ancestral history (or the
-phylogeny). We may consider briefly (since we devote the
-next chapter almost entirely to the same topic) the exceptions
-to this supposed recapitulation, which Fleischmann has
-brought together. The young of beetles, flies, and butterflies
-creep out of the egg as small worm-like forms of apparently
-simple organization. They have a long body, composed
-of a series of rings; the head is small and lacks the feelers,
-and often the faceted eyes. The wings are absent, and the
-legs are short. At first sight the larva appears to resemble a
-worm, and this led Oken to conclude that the insects appear
-first in the form of their ancestors, the segmented worms. If
-we examine the structure of the larva more carefully, we shall
-find that there are a great many differences between it and
-the segmented worms; and that even the youngest larva is
-indeed a typical insect. The tracheæ, so characteristic of the
-group of insects, are present, the structure of the digestive
-tract with its Malpighian tubes, the form of the heart, the
-structure of the head, as well as the blastema of the reproductive
-organs, show in the youngest larva the type of the
-insects. In other words the body of the caterpillar is formed
-on exactly the same fundamental plan as that of the butterfly.</p>
-
-<p class='c010'><span class='pageno' id='Page_57'>57</span>In regard to the larval forms of other groups we find the
-same relations, as, for example, in the amphibians. The young
-of salamanders, toads, and frogs leave the egg not in the
-completed form, but as small tadpoles adapted to life in the
-water. A certain resemblance to fish cannot be denied.
-They possess a broad tail, gills (rich in blood vessels) on
-each side of the neck, and limbs are absent for a long time.
-These are characters similar to those of fish, but a more careful
-anatomical examination destroys the apparent resemblance.
-The superficial resemblances are due to adaptation to the
-same external conditions.</p>
-
-<p class='c010'>Fleischmann ridicules the idea that the young chick
-resembles at any stage an adult, ancestral animal; the presence
-of an open digestive tract shows how absurd such an
-idea is. The obvious contradiction is explained away by
-embryologists, by supposing that the ancestral adult stages
-have been crowded together in order to shorten the period of
-development; and that, in addition, larval characters and provisional
-organs have appeared in the embryo itself, which
-confuse and crowd out the ancestral stages.</p>
-
-<p class='c010'>In regard to the presence of gill-slits in the embryo of
-the higher vertebrates, in the chick, and in man, for example,
-Fleischmann says: “I cannot see how it can be shown by
-exact proof that the gill-slits of the embryos of the higher
-vertebrates that remain small and finally disappear could
-once have had the power of growing into functional slits.”
-With this trite comment the subject is dismissed.</p>
-
-<p class='c010'>On the whole, Fleischmann’s attack cannot be regarded as
-having seriously weakened the theory of evolution. He has
-done, nevertheless, good service in recalling the fact that,
-however probable the theory may appear, the evidence is
-indirect and exact proof is still wanting. Moreover, as I
-shall attempt to point out in the next chapter, we are far
-from having arrived at a satisfactory idea of how the process
-has really taken place.</p>
-
-<div class='pbb'>
- <hr class='pb c006' />
-</div>
-<div class='chapter'>
-  <span class='pageno' id='Page_58'>58</span>
-  <h2 class='c008'>CHAPTER III<br /> <br /><span class='c013'>THE THEORY OF EVOLUTION (<i>Continued</i>)</span></h2>
-</div>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div><span class='c020'><span class='sc'>The Evidence from Embryology</span></span></div>
-    <div class='c000'><span class='c013'>THE RECAPITULATION THEORY</span></div>
-  </div>
-</div>
-
-<p class='c009'><span class='sc'>At</span> the close of the eighteenth, and more definitely at the
-beginning of the nineteenth, century a number of naturalists
-called attention to the remarkable resemblance between the
-embryos of higher animals and the adult forms of lower
-animals. This idea was destined to play an important rôle
-as one of the most convincing proofs of the theory of evolution,
-and it is interesting to examine, in the first place, the
-evidence that suggested to these earlier writers the theory
-that the embryos of the higher forms pass through the adult
-stages of the lower animals.</p>
-
-<p class='c010'>The first definite reference<a id='r5' /><a href='#f5' class='c017'><sup>[5]</sup></a> to the recapitulation view that
-I have been able to find is that of Kielmeyer in 1793, which
-was inspired, he says, by the resemblance of the tadpole of
-the frog to an adult fish.<a id='r6' /><a href='#f6' class='c017'><sup>[6]</sup></a> This suggested that the embryo
-of higher forms corresponds to the adult stages of lower
-ones. He adds that man and birds are in their first stages
-plantlike.</p>
-
-<div class='footnote c018' id='f5'>
-<p class='c019'><span class='label'><a href='#r5'>5</a>.&nbsp;&nbsp;</span>The earlier references of a few embryologists are too vague to have any bearing
-on the subject.</p>
-</div>
-
-<div class='footnote c018' id='f6'>
-<p class='c019'><span class='label'><a href='#r6'>6</a>.&nbsp;&nbsp;</span>Autenrieth in 1797 makes the briefest possible reference to some such principle
-in speaking of the way in which the nose of the embryo closes.</p>
-</div>
-
-<p class='c010'>Oken in 1805 gave the following fantastic account of this
-relation: “Each animal ‘metamorphoses itself’ through all
-animal forms. The frog appears first under the form of a
-mollusk in order to pass from this stage to a higher one.
-<span class='pageno' id='Page_59'>59</span>The tadpole stage is a true snail; it has gills which hang
-free at the sides of the body as is the case in <i>Unio pictorum</i>.
-It has even a byssus, as in Mytilus, in order to cling to the
-grass. The tail is nothing else than the foot of the snail.
-The metamorphosis of an insect is a repetition of the whole
-class, scolopendra, oniscus, julus, spider, crab.”</p>
-
-<p class='c010'>Walther, in 1808, said: “The human fœtus passes through
-its metamorphosis in the cavity of the uterus in such a way
-that it repeats all classes of animals, but, remaining permanently
-in none, develops more and more into the innate
-human form. First the embryo has the form of a worm.
-It reaches the insect stage just before its metamorphosis.
-The origin of the liver, the appearance of the different secretions,
-etc., show clearly an advance from the class of the
-worm into that of the mollusk.”</p>
-
-<p class='c010'>Meckel first in 1808, again in 1811, and more fully in 1821
-made much more definite comparisons between the embryos
-of higher forms and the adult stages of lower groups. He
-held that the embryo of higher forms, before reaching its complete
-development, passes through many stages that correspond
-to those at which the lower animals appear to be
-checked through their whole life. In fact the embryos of
-higher animals, the mammals, and especially man, correspond
-in the form of their organs, in their number, position, and
-proportionate size to those of the animals standing below
-them. The skin is at first, and for a considerable period of
-embryonic life, soft, smooth, hairless, as in the zoophytes,
-medusæ, many worms, mollusks, fishes, and even in the
-lower amphibians. Then comes a period in which it becomes
-thicker and hairy, when it corresponds to the skin of the
-higher animals. It should be especially noted here, that the
-fœtus of the negro is more hairy than that of the European.</p>
-
-<p class='c010'>The muscular system of the embryo, owing to its lack of
-union in the ventral wall, corresponds to the muscles of the
-shelled, headless mollusks, whose mantle is open in the same
-<span class='pageno' id='Page_60'>60</span>region. Meckel compares the bones of the higher vertebrates
-with the simpler bones of the lower forms, and even
-with the cartilages of the cephalopod. He points out that in
-the early human embryo the nerve cord extends the whole
-length of the spinal canal. He compares the simple heart of
-the embryo with that of worms, and a later stage, when two
-chambers are present, with that of the gasteropod mollusk.
-The circulation of the blood in the placenta recalls, he says,
-the circulation in the skin of the lower animals. The lobulated
-form of the kidney in the human embryo is compared
-with the adult condition in the fishes and amphibians. The
-internal position of the reproductive organs in the higher
-mammals recalls the permanent position of these organs in
-the lower animals. The posterior end of the body of the
-human embryo extends backwards as a tail which later disappears.</p>
-
-<p class='c010'>Some of these comparisons of Meckel sound very absurd
-to us nowadays, especially his comparison between the embryos
-of the higher vertebrates, and the adults of worms,
-crustaceans, spiders, snails, bivalve mollusks, cephalopods, etc.
-On the other hand, many of these comparisons are the same
-as those that are to be found in modern text-books on embryology;
-and we may do well to ask ourselves whether these
-may not sound equally absurd a hundred years hence. Why
-do some of Meckel’s comparisons seem so naïve, while others
-have a distinctly modern flavor? In a word, can we justify
-the present belief of some embryologists that the embryos
-of higher forms repeat the adult stages of lower members
-of the same group? It is important to observe that up to
-this time the comparison had always been made between
-the embryo of the higher form and the adult forms of
-existing lower animals. The theory of evolution had, so
-far, had no influence on the interpretation that was later
-given to this resemblance.</p>
-
-<p class='c010'>Von Baer opposed the theory of recapitulation that had
-<span class='pageno' id='Page_61'>61</span>become current when he wrote in 1828. According to Von
-Baer, the more nearly related two animals are, or rather the
-more nearly similar two forms are (since Von Baer did not
-accept the idea of evolution), the more nearly alike is their
-development, and so much longer in their development do
-they follow in the same path. For example two similar
-species of pigeons will follow the same method of development
-up to almost the last stage of their formation. The
-embryos of these two forms will be practically identical
-until each produces the special characters of its own
-species. On the other hand two animals belonging to
-different families of the same phylum will have only the
-earlier stages in common. Thus, a bird and a mammal
-will have the first stages similar, or identical, and then
-diverge, the mammal adding the higher characters of its
-group. The resemblance is between corresponding embryonic
-stages and not between the embryo of the mammal
-and the adult form of a lower group.</p>
-
-<p class='c010'>Von Baer was also careful to compare embryos of the
-same phylum with each other, and states explicitly that
-there are no grounds for comparison between embryos of
-different groups.<a id='r7' /><a href='#f7' class='c017'><sup>[7]</sup></a></p>
-
-<div class='footnote c018' id='f7'>
-<p class='c019'><span class='label'><a href='#r7'>7</a>.&nbsp;&nbsp;</span>In one place Von Baer raises the question whether the egg may not be a
-form common to all the phyla.</p>
-</div>
-
-<p class='c010'>We shall return again to Von Baer’s interpretation and
-then discuss its value from our present point of view.</p>
-
-<p class='c010'>Despite the different interpretation that Von Baer gave
-to this doctrine of resemblance the older view of recapitulation
-continued to dominate the thoughts of embryologists
-throughout the whole of the nineteenth century.</p>
-
-<p class='c010'>Louis Agassiz, in the Lowell Lectures of 1848, proposed
-for the first time the theory that the embryo of higher
-forms resembled not so much lower adult animals living
-at the present time, as those that lived in past times.
-Since Agassiz himself did not accept the theory of evolution,
-<span class='pageno' id='Page_62'>62</span>the interpretation that he gave to the recapitulation
-theory did not have the importance that it was destined
-to have when the animals that lived in the past came to
-be looked upon as the ancestors of existing animals.<a id='r8' /><a href='#f8' class='c017'><sup>[8]</sup></a> But
-with the acceptation of the theory of evolution, which was
-largely the outcome of the publication of Darwin’s “Origin
-of Species” in 1859, this new interpretation immediately
-blossomed forth. In fact, it became almost a part of the
-new theory to believe that the embryo of higher forms
-recapitulated the series of ancestral adult forms through
-which the species had passed. The one addition of any
-importance to the theory that was added by the Darwinian
-school was that the history of the past, as exemplified by
-the embryonic development, is often falsified.</p>
-
-<div class='footnote c018' id='f8'>
-<p class='c019'><span class='label'><a href='#r8'>8</a>.&nbsp;&nbsp;</span>Carl Vogt in 1842 suggested that fossil species, in their historical succession,
-pass through changes similar to those which the embryos of living forms
-undergo.</p>
-</div>
-
-<p class='c010'>Let us return once more to the facts and see which of
-them are regarded at present as demanding an explanation.
-These facts are not very numerous and yet sufficiently apparent
-to attract attention at once when known.</p>
-
-<p class='c010'>The most interesting case, and the one that has most often
-attracted attention, is the occurrence of gill-clefts in the
-embryos of reptiles, birds, and mammals. These appear
-on each side of the neck in the very early embryo. Each
-is formed by a vertical pouch, that grows out from the wall
-of the pharynx until it meets the skin, and, fusing with the
-latter, the walls of the pouch separate, and a cleft is formed.
-This vertical cleft, placing the cavity of the pharynx in communication
-with the outside, is the gill-slit. Similar openings
-in adult fishes put the pharynx in communication with the
-exterior, so that water taken through the mouth passes out
-at the sides of the neck between the gill filaments that border
-the gill-slits. In this way the blood is aerated. The number
-of gill-slits that are found in the embryos of different groups
-<span class='pageno' id='Page_63'>63</span>of higher vertebrates, and the number that open to the exterior
-are variable; but the number of gill-openings that are
-present in the adults of lower vertebrates is also variable.
-No one who has studied the method of development of the
-gill-slits in the lower and higher vertebrates will doubt for a
-moment that some kind of relation must subsist between
-these structures.</p>
-
-<p class='c010'>In the lowest adult form of the vertebrates, amphioxus,
-the gill-system is used largely as a sieve for procuring food,
-partly also, perhaps, for respiration. In the sharks, bony
-fishes, and lower amphibians, water is taken in through the
-mouth, and passes through the gill-slits to the exterior.
-As it goes through the slits it passes over the gills, that
-stand like fringes on the sides of the slits. The blood that
-passes in large quantities through the gills is aerated in
-this way. In the embryos of the higher vertebrates the
-gill-slits may appear even before the mouth has opened,
-but in no case is there a passage of water through the
-gill-slits, nor is the blood aerated in the gill-region, although
-it passes through this part on its way from the heart to
-the dorsal side of the digestive tract. It is quite certain
-that the gill-system of the embryo performs no respiratory
-function.<a id='r9' /><a href='#f9' class='c017'><sup>[9]</sup></a></p>
-
-<div class='footnote c018' id='f9'>
-<p class='c019'><span class='label'><a href='#r9'>9</a>.&nbsp;&nbsp;</span>This statement is not intended to prejudice the question as to whether the
-presence of the gill-slits and arches may be essential to the formation of other
-organs.</p>
-</div>
-
-<p class='c010'>In the higher amphibians, the frogs for example, we find
-an interesting transition. The young embryo, when it
-emerges from the egg-membranes, bears three pairs of
-external gills that project from the gill-arches into the surrounding
-water. Later these are absorbed, and a new
-system of internal gills, like those of fishes, develops on
-the gill-arches. These are used throughout the tadpole
-stage for respiratory purposes. When the tadpole is about
-to leave the water to become a frog, the internal gills are
-<span class='pageno' id='Page_64'>64</span>also absorbed and the gill-clefts close. Lungs then develop
-which become the permanent organs of respiration.</p>
-
-<p class='c010'>There are two points to be noticed in this connection.
-First, the external gills, which are the first to develop, do not
-seem to correspond to any permanent adult stage of a lower
-group. Second, the transition from the tadpole to the frog
-can only be used by way of analogy of what is supposed
-to have taken place ancestrally in the reptiles, birds, and
-mammals, since no one will maintain that the frogs represent
-a group transitional between the amphibians and the higher
-forms. However, since the salamanders also have gills and
-gill-slits in the young stages, and lose them when they leave
-the water to become adult land forms, this group will better
-serve to illustrate how the gill-system has been lost in the
-higher forms. Not that in this case either, need we suppose
-that the forms living to-day represent ancestral, transitional
-forms, but only that they indicate how such a remarkable
-change from a gill-breathing form, living in the water,
-might become transformed into a lung-breathing land form.
-Such a change is supposed to have taken place when the
-ancestors of the reptiles and the mammals left the water
-to take up their abode on the land.</p>
-
-<p class='c010'>The point to which I wish to draw especial attention in
-this connection is that in the higher forms the gill-slits appear
-at a very early stage; in fact, as early in the mammal
-as in the salamander or the fish, so that if we suppose
-their appearance in the mammal is a repetition of the
-adult amphibian stage, then, since this stage appears as early
-in the development of the mammal as in the amphibians
-themselves, the conclusion is somewhat paradoxical.</p>
-
-<p class='c010'>The history of the notochord in the vertebrate series gives
-an interesting parallel. In amphioxus it is a tough and firm
-cord that extends from end to end of the body. On each
-side of it lie the plates of muscles. It appears at a very
-early stage of development as a fold of the upper wall of
-<span class='pageno' id='Page_65'>65</span>the digestive tract. In the cartilaginous fishes the notochord
-also appears at a very early stage, and also from the dorsal
-wall of the digestive tract. In later embryonic stages it
-becomes surrounded by a cartilaginous sheath, or tube,
-which then segments into blocks, the vertebræ. The notochord
-becomes partially obliterated as the centra of the
-vertebræ are formed, but traces of it are present even in
-adult stages. In the lower amphibians the notochord arises
-also at an early stage over and perhaps, in part, from the
-dorsal wall of the digestive tract. It is later almost entirely
-obliterated by the development of the vertebræ. These
-vertebræ first appear as a membraneous tube which breaks
-up into cartilaginous blocks, and these are the structures
-around and in which the bone develops to form the permanent
-vertebræ.</p>
-
-<p class='c010'>In higher forms, reptiles, birds, and mammals, the notochord
-also appears at the very beginning of the development,
-but it is not certain that we can call the material out
-of which it forms the dorsal wall of the archenteron (the
-amphibians giving, perhaps, intermediate stages). It becomes
-surrounded by continuous tissue which breaks up into
-blocks, and these become the bases of the vertebræ. The
-notochord becomes so nearly obliterated in later stages that
-only the barest traces of it are left either in the spaces
-between, or in, the vertebræ.</p>
-
-<p class='c010'>In this series we see the higher forms passing through
-stages similar at first to those through which the lower forms
-pass; and it is especially worthy of note that the embryo
-mammal begins to produce its notochord at the very beginning
-of its development, at a stage, in fact, so far as comparison
-is possible, as early as that at which the notochord of
-amphioxus develops.</p>
-
-<p class='c010'>The development of the skull gives a somewhat similar
-case. The skulls of sharks and skates are entirely cartilaginous
-and imperfectly enclose the brain. The ganoids
-<span class='pageno' id='Page_66'>66</span>have added to the cartilaginous skull certain plates in the
-dermal layer of the skin. In the higher forms we find the
-skull composed of two sets of bones, one set developing from
-the cartilage of the first-formed cranium, and the other having
-a more superficial origin; the latter are called the membrane
-bones, and are supposed to correspond to the dermal plates
-of the ganoids.</p>
-
-<p class='c010'>In the development of the kidneys, or nephridia, we find,
-perhaps, another parallel, although, owing to recent discoveries,
-we must be very cautious in our interpretation. As
-yet, nothing corresponding to the nephridia of amphioxus has
-been discovered in the other vertebrates. Our comparison
-must begin, therefore, higher up in the series. In the sharks
-and bony fishes the nephridia lie at the anterior end of the
-body-cavity. In the amphibia there is present in the
-young tadpole a pair of nephridial organs, the head-kidneys,
-also in the anterior end of the body-cavity. Later these are
-replaced by another organ, the permanent mid-kidney, that
-develops behind the head-kidney. In reptiles, birds, and
-mammals a third nephridial organ, the hind-kidney, develops
-later than and posterior to the mid-kidney, and becomes the
-permanent organ of excretion. Thus in the development of
-the nephridial system in the higher forms we find the same
-sequence, more or less, that is found in the series of adult
-forms mentioned above. The anterior end of the kidney
-develops first, then the middle part, and then the most posterior.
-The anterior part disappears in the amphibians, the
-anterior and the middle parts in the birds and mammals, so
-that in the latter groups the permanent kidney is the hind-kidney
-alone.</p>
-
-<p class='c010'>The formation of the heart is supposed to offer certain
-parallels. Amphioxus is without a definite heart, but there is
-a ventral blood vessel beneath the pharynx, which sends blood
-to the gill-system. This blood vessel corresponds in position
-to the heart of other vertebrates. In sharks we find a thick-walled
-<span class='pageno' id='Page_67'>67</span>muscular tube below the pharynx; the blood enters at
-its posterior end, flows forward and out at the anterior end
-into a blood vessel that sends smaller vessels up through the
-gill-arches to the dorsal side.</p>
-
-<p class='c010'>In the amphibia the heart is a tube, so twisted on itself that
-the original posterior end is carried forward to the anterior
-end, and this part, the auricle, is divided lengthwise by a
-partition into a right and a left side. In the reptiles the
-ventricle is also partially separated into two chambers, completely
-so in the crocodiles. In birds and mammals the
-auricular and ventricular septa are complete in the adult, and
-the ventral aorta that carries the blood forward from the
-heart is completely divided into two vessels, one of which now
-carries blood to the lungs. When we examine the development
-of the heart of a mammal, or of a bird, we find something
-like a parallel series of stages, apparently resembling
-conditions found in the different groups just described. The
-heart is, at first, a straight tube, it then bends on itself, and a
-constriction separates the auricular part from the ventricular,
-and another the ventricular from the ventral aorta. Vertical
-longitudinal partitions then arise, one of which separates the
-auricle into two parts, and another the ventricle into two
-parts, and a third divides the primitive aorta into two parts.
-In the early stages all the blood passes from the single
-ventral aorta through the gill-arches to the dorsal side, and it
-is only after the appearance of the lung-system that the gill-system
-is largely obliterated.</p>
-
-<p class='c010'>We find here, then, a sort of parallel, provided we do not
-inquire too particularly into details. This comparison may be
-justified, at least so far that the circulation is at first through
-the arches and is later partially replaced by the double circulation,
-the systemic and the pulmonary.</p>
-
-<p class='c010'>A few other cases may also be added. The proverbial
-absence of teeth in birds applies only to the adult condition,
-for, as first shown by Geoffroy Saint-Hilaire, four thickenings,
-<span class='pageno' id='Page_68'>68</span>or ridges, develop in the mouth of the embryo; two in the
-upper, two in the lower, jaw. These ridges appear to correspond
-to those of reptiles and mammals, from which the teeth
-develop. It may be said, therefore, that the rudiments of
-teeth appear in the embryo of the bird. This might be interpreted
-to mean that the embryo repeats the ancestral reptilian
-stage, or, perhaps, the ancestral avian stage that had teeth in
-the beak; but since only the beginnings of teeth appear, and
-not the fully formed structures, this interpretation would
-clearly overshoot the mark.</p>
-
-<p class='c010'>The embryo of the baleen whale has teeth that do not
-break through the gums and are later absorbed. Since the
-ancestors of this whale probably had teeth, as have other
-whales at the present time, the appearance of teeth in the
-embryo has been interpreted as a repetition of the original
-condition. Some of the ant-eaters are also toothless, but
-teeth appear in the embryo and are lost later. In the ruminants
-that lack teeth in the front part of the upper jaw, <i>e.g.</i>
-the cow and the sheep, teeth develop in the embryo which
-are subsequently lost.</p>
-
-<p class='c010'>One interpretation of these facts is that the ancestral
-adult condition is repeated by the embryo, but as I have
-pointed out above in the cases of the teeth in whales, since
-the teeth do not reach the adult form, and do not even break
-through the gums in some forms, it is obviously stretching
-a point to claim that an adult condition is repeated. Moreover,
-in the case of the birds only the dental ridges appear,
-and it is manifestly absurd to claim in this case that the
-ancestral adult condition of the reptiles is repeated.</p>
-
-<p class='c010'>That a supposed ancestral stage may be entirely lost in
-the embryo of higher forms is beautifully shown in the development
-of some of the snakes. The snakes are probably
-derived from lizardlike ancestors, which had four legs, yet
-in the development the rudiments of legs do not appear, and
-this is the more surprising since a few snakes have small
-<span class='pageno' id='Page_69'>69</span>rudimentary legs. In these, of course, the rudiments of legs
-must appear in the embryo, but in the legless forms even the
-beginnings of the legs have been lost, or at any rate very
-nearly so.</p>
-
-<p class='c010'>Outside the group of vertebrates there are also many
-cases that have been interpreted as embryonic repetitions
-of ancestral stages, but a brief examination will suffice to
-show that many of these cases are doubtful, and others little
-less than fanciful. A few illustrations will serve our purpose.
-The most interesting case is that given by the history
-of the nauplius theory.</p>
-
-<p class='c010'>The free-living larva of the lower crustaceans—water-fleas,
-barnacles, copepods, ostracods—emerges from the egg
-as a small, flattened oval form with three pairs of appendages.
-This larva, known as the nauplius, occurs also in
-some of the higher crustaceans, not often, it is true, as a free
-form, as in penæus, but as an embryonic stage. The occurrence
-of this six-legged form throughout the group was
-interpreted by the propounders of the nauplius theory as
-evidence sufficient to establish the view that it represented
-the ancestor of the whole group of Crustacea, which ancestor
-is, therefore, repeated as an embryonic form. This hypothesis
-was accepted by a large number of eminent embryologists.
-The history of the collapse of the theory is instructive.</p>
-
-<p class='c010'>It had also been found in one of the groups of higher
-crustaceans, the decapods, containing the crayfish, lobster,
-and crabs, that another characteristic larval form was
-repeated in many cases. This larva is known as the zoëa.
-It has a body made up of a fused head and thorax carrying
-seven pairs of appendages and of a segmented abdomen of
-six segments. The same kind of evidence that justified
-the formulation of the nauplius theory would lead us to infer
-that the zoëa is the ancestor of the decapods. The later
-development of the zoëa shows, however, that it cannot
-be such an ancestral form, for, in order to reach the
-<span class='pageno' id='Page_70'>70</span>full number of segments characteristic of the decapods,
-new segments are intercalated between the cephalothorax
-and abdomen. In fact, in many zoëas this intercalated
-region is already in existence in a rudimentary condition,
-and small appendages may even be present. A study of the
-comparative anatomy of the crustaceans leaves no grounds
-for supposing that the decapods with their twenty-one segments
-have been evolved from a thirteen-segmented form
-like the zoëa by the intercalation of eight segments in the
-middle of the body. It follows, if this be admitted, and
-it is generally admitted now, that the zoëa does not represent
-an original ancestral form at all, but a highly modified
-new form, as new, perhaps, as the group of decapods itself.
-We are forced to conclude, then, that the presence of a larval
-form throughout an entire group cannot be accepted as evidence
-that it represents an ancestral stage. We can account
-for the presence of the zoëa, however, by making a single
-supposition, namely, that the ancestor from which the group
-of decapod has evolved had a larva like the zoëa, and that
-this larval form has been handed down to all of the descendants.</p>
-
-<p class='c010'>The fate of the zoëa theory cast a shadow over the
-nauplius theory, since the two rested on the same sort of
-evidence. The outcome was, in fact, that the nauplius
-theory was also abandoned, and this was seen to be the
-more necessary, since a study of the internal anatomy of the
-lowest group of crustaceans, the phyllopods, showed that they
-have probably come directly from many segmented, annelidian
-ancestors. The presence of the nauplius is now generally
-accounted for by supposing that it was a larval form
-of the ancestor from which the group of crustaceans arose.</p>
-
-<p class='c010'>The most extreme, and in many ways the most uncritical,
-application of the recapitulation theory was that made by
-Haeckel, more especially his attempt to reduce all the higher
-animals to an ancestral double-walled sac with an opening
-<span class='pageno' id='Page_71'>71</span>at one end,—the gastræa. He dignified the recapitulation
-theory with an appellation of his own, “The Biogenetic
-Law.” Haeckel’s fanciful and extreme application of the
-older recapitulation theory has probably done more to bring
-the theory into disrepute amongst embryologists than the
-criticisms of the opponents of the theory.</p>
-
-<p class='c010'>In one of the recognized masterpieces of embryological
-literature, His’s “Unsere Körperform,” we find the strongest
-protest that has yet been made against the Haeckelian
-pretension that the phylogenetic history is the “cause” of
-the ontogenetic series. His writes: “In the entire series of
-forms which a developing organism runs through, each form
-is the necessary antecedent step of the following. If the
-embryo is to reach the complicated end-forms, it must pass,
-step by step, through the simpler ones. Each step of the
-series is the physiological consequence of the preceding
-stage and the necessary condition for the following. Jumps,
-or short cuts, of the developmental process, are unknown in
-the physiological process of development. If embryonic
-forms are the inevitable precedents of the mature forms,
-because the more complicated forms must pass through the
-simpler ones, we can understand the fact that paleontological
-forms are so often like the embryonic forms of to-day.
-The paleontological forms are embryonal, because they have
-remained at the lower stage of development, and the present
-embryos must pass also through lower stages in order to
-reach the higher. But it is by no means necessary for the
-later, higher forms to pass through embryonal forms because
-their ancestors have once existed in this condition. To take
-a special case, suppose in the course of generations a species
-has increased its length of life gradually from one, two, three
-years to eighty years. The last animal would have had
-ancestors that lived for one year, two years, three years, etc.,
-up to eighty years. But who would claim that because the
-final eighty-year species must pass necessarily through one,
-<span class='pageno' id='Page_72'>72</span>two, three years, etc., that it does so because its ancestors
-lived one year, two years, three years, etc.? The descent
-theory is correct so far as it maintains that older, simpler
-forms have been the forefathers of later complicated forms.
-In this case the resemblance of the older, simpler forms to
-the embryos of later forms is explained without assuming
-any law of inheritance whatsoever. The same resemblance
-between the older and simpler adult forms, and the present
-embryonic forms would even remain intelligible were there no
-relation at all between them.”</p>
-
-<p class='c010'>Interesting and important as is this idea of His, it will not,
-I think, be considered by most embryologists as giving an
-adequate explanation of many facts that we now possess. It
-expresses, no doubt, a part of the truth but not the whole
-truth.</p>
-
-<p class='c010'>We come now to a consideration of certain recently
-ascertained facts that put, as I shall try to show, the whole
-question of embryonic repetition in a new light.</p>
-
-<p class='c010'>A minute and accurate study of the early stages of
-division or cleavage of the egg of annelids has shown a
-remarkable agreement throughout the group. The work of
-E. B. Wilson on nereis, and on a number of other forms, as
-well as the subsequent work of Mead, Child, and Treadwell
-on other annelids, has shown resemblances in a large number
-of details, involving some very complicated processes.<a id='r10' /><a href='#f10' class='c017'><sup>[10]</sup></a></p>
-
-<div class='footnote c018' id='f10'>
-<p class='c019'><span class='label'><a href='#r10'>10</a>.&nbsp;&nbsp;</span>On the other hand it should not pass unnoticed that Eisigh as shown in one
-form (in which, however, the eggs are under special conditions being closely
-packed together) that the usual type of cleavage is altered.</p>
-</div>
-
-<p class='c010'>Not only is the same method of cleavage found in most
-annelids, but the same identical form of division is also present
-in many of the mollusks, as shown especially by the work
-of Conklin, Lillie, and Holmes. This resemblance has been
-discussed at some length by those who have worked out these
-results in the two groups. The general conclusion reached
-by them is that the only possible interpretation of the
-<span class='pageno' id='Page_73'>73</span>phenomenon is that some sort of genetic connection must
-exist between the different forms; and while not explicitly
-stated, yet there is not much doubt that some at least of
-these authors have had in mind the view that the annelids
-and mollusks are descended from common ancestors whose
-eggs segmented as do those of most of the mollusks and
-annelids of the present day. This conclusion is, I believe, of
-more far-reaching importance than has been supposed, and
-may furnish the key that will unlock the whole question of
-the resemblance of embryos to supposed ancestral forms.
-It is a most fortunate circumstance that in the case of this
-cell lineage the facts are of such a kind as to preclude the
-possibility that the stages in common could ever have been
-ancestral adult stages. If this be granted then only two
-interpretations are possible: the results are due either to a
-coincidence, or to a common embryonic form that is repeated
-in the embryo of many of the descendants. That the similarity
-is not due to a coincidence is made probable from the
-number and the complexities of the cleavage stages.</p>
-
-<p class='c010'>I believe that we can extend this same interpretation to
-all other cases of embryonic resemblance. It will explain
-the occurrence of gill-slits in the embryo of the bird, and the
-presence of a notochord in the higher forms in exactly the
-same way as the cleavage stages are explained. But how,
-it may be asked, can we explain the apparent resemblance
-between the embryo of the higher form and the adult of
-lower groups. The answer is that this resemblance is deceptive,
-and in so far as there is a resemblance it depends
-on the resemblance of the adult of the lower form to its own
-embryonic stages with which we can really make a comparison.
-The gill-slits of the embryo of the chick are to be compared,
-not with those of the adult fish, but with those of the
-embryo of the fish. It is a significant fact, in this connection,
-that the gill-slits appear as early in the embryo of the fish as
-they do in the bird! The notochord of the embryo bird is
-<span class='pageno' id='Page_74'>74</span>comparable with that of the embryo of amphioxus, and not
-with the persistent notochord in the adult amphioxus. Here
-also it is of the first importance to find that the notochord
-appears both in the embryo bird and in amphioxus at the very
-beginning of the development. The embryo bird is not fishlike
-except in so far as there are certain organs in the embryo
-fish that are retained in the adult form. The embryo bird
-bears the same relation to the embryo fish that the early
-segmentation stages of the mollusk bear to the early segmentation
-stages of the annelid. There are certain obvious
-resemblances between this view and that of Von Baer, but
-there are also some fundamental differences between the two
-conceptions.</p>
-
-<p class='c010'>Von Baer thought that within each group the embryonic
-development is the same up to a certain point. He supposed
-that the characters of the group are the first to appear, then
-those of the order, class, family, genus, and, finally, of the
-species. He supposed that two similar species would follow
-the same method of development until the very last stage was
-reached, when each would then add the final touches that
-give the individual its specific character. We may call this
-the theory of embryonic parallelism. Here there is an important
-difference between my view and that of Von Baer, for I
-should not expect to find the two embryos of any two species
-identical at any stage of their development, but at most there
-might exist a close resemblance between them.</p>
-
-<p class='c010'>Von Baer’s statement appears to be erroneous from a modern
-point of view in the following respects. We know that in
-certain large groups some forms develop in a very different way
-from that followed by other members of the group, as shown
-by the cephalopods, for instance, in the group of mollusks.
-Again, it is entirely arbitrary to assume that the group-characters
-are the first to appear, and then successively
-those of the order, family, genus, species. Finally, as has
-been said above, we do not find the early embryos of a
-<span class='pageno' id='Page_75'>75</span>group identical; for with a sufficient knowledge of the development
-it is always possible to distinguish between the embryos
-of different species, as well as between the adults, only
-it is more difficult to do so, because the embryonic forms are
-simpler. The most fundamental difference between the view
-of Von Baer and modern views is due to our acceptation of
-the theory of evolution which seems to make it possible to
-get a deeper insight into the meaning of the repetition, that
-carries us far ahead of Von Baer’s position. For with the
-acceptance of this doctrine we have an interpretation of how
-it is possible for the embryonic stages of most members of a
-group to have the same form, although they are not identical.
-There has been a continuous, although divergent, stream
-of living material, carrying along with it the substance out of
-which the similar embryonic forms are made. As the stream
-of embryonic material divided into different paths it has also
-changed many of the details, sometimes even all; but nevertheless
-it has often retained the same general method of
-development that is associated with its particular composition.
-We find the likeness, in the sense of similarity of plan, accounted
-for by the inheritance of the same sort of substance;
-the differences in the development must be accounted for in
-some other way.</p>
-
-<p class='c010'>Among modern writers Hurst alone has advanced a view
-that is similar in several respects to that which I have here
-defended. It may be well to give his statement, since it
-brings out certain points of resemblance with, as well as certain
-differences from, my own view.<a id='r11' /><a href='#f11' class='c017'><sup>[11]</sup></a> He says: “Direct
-observation has shown that, when an animal species <i>varies</i>
-(<i>i.e.</i> <i>becomes</i> unlike what it was before) in adult structure,
-those stages in the development which are nearest the adult
-undergo a similar, but usually smaller, change. This is shown
-in domestic species by the observations of Darwin, and the
-<span class='pageno' id='Page_76'>76</span>result is in exact harmony with the well-known law of Von
-Baer, which refers to natural species, both nearly related and
-widely dissimilar. Von Baer’s observations as well as Darwin’s,
-and as well as those of every student who has ever
-compared the embryos of two vertebrate species, may be
-summarized as follows:—</p>
-
-<div class='footnote c018' id='f11'>
-<p class='c019'><span class='label'><a href='#r11'>11</a>.&nbsp;&nbsp;</span>Hurst, C. H., “Biological Theories, III,” “The Recapitulation Theory,”
-<i>Natural Science</i>, Vol. ii., 1893.</p>
-</div>
-
-<p class='c010'>“Animals which, though related, are very similar in the
-adult state, resemble each other more closely in early stages
-of development, often, indeed, so closely as to be indistinguishable
-in those early stages. As development proceeds
-<i>in such species</i>, the differences between the two embryos compared
-become more and more pronounced.” On this point,
-which is an essential one, I cannot agree with Hurst; for I
-do not think that the facts show that the early stages of two
-related forms are necessarily more and more alike the farther
-back we go. The resemblance that is sometimes so striking in
-the earlier stages is due to the fewer points there are for
-comparison, and to the less development of the parts then
-present. Hurst continues: “If similar comparisons could be
-instituted between the ancestral species and its much modified
-descendants, there is no reason for doubting that a similar
-result would be reached. This, indeed, has been done in the
-case of some breeds of pigeons, which we have excellent
-reasons for believing to be descended from <i>Columba livia</i>.
-True, <i>C. livia</i> is not a very remote ancestor, but I do not
-think that will vitiate the argument. Let me quote Darwin
-verbatim: ‘As we have conclusive evidence that the breeds
-of the pigeon are descended from a single wild species, I
-have compared the young within twelve hours after being
-hatched; I have carefully measured the proportions (but will
-not here give the details) of the beak, width of mouth, length
-of nostril, and of eyelid, size of feet, and length of leg in
-the wild, parent species, in pouters, fantails, runts, barbs,
-dragons, carriers, and tumblers. Now some of these birds
-when mature differ in so extraordinary a manner in the
-<span class='pageno' id='Page_77'>77</span>length and form of the beak, and in other characters, that
-they would certainly have been ranked as distinct genera
-if found in a state of nature. But when the nestling birds
-of these several breeds were placed in a row, though most of
-them could just be distinguished, the proportional differences
-in the above specified points were incomparably less than in
-the full-grown birds. Some characteristic points of difference—for
-instance, that of the width of the mouth—could
-hardly be detected in the young. But there was one remarkable
-exception to this rule, for the young of the short-faced
-tumbler differed from the young of the wild-rock pigeon,
-and of the other breeds in almost exactly the same proportions
-as in the adult state.’”</p>
-
-<p class='c010'>Hurst concludes that: “The more the adult structure
-comes to be unlike the adult structure of the ancestors, the
-more do the late stages of development undergo a modification
-of the same kind. This is not mere dogma, but it is a
-simple paraphrase of Von Baer’s law. It is proved true not
-only by the observations of Von Baer and of Darwin, already
-referred to, but by the direct observation of every one who
-takes the trouble to compare the embryos of any two vertebrates,
-provided only he will be content to see what actually
-lies before him and not the phantasms which the recapitulation
-theory may have printed on his imagination.”</p>
-
-<p class='c010'>The growth of the antlers of stags is cited by Hurst in
-order to illustrate that what has been interpreted as a recapitulation
-may have a different interpretation. “Each
-stag develops a new pair of antlers in each successive year,
-and each pair of antlers is larger than the pair produced in
-the previous year. This yearly increase in the size of the
-antlers has been put forward as an example of an ontogenetic
-record of past evolution. I, however, deny that it is such a
-record.”</p>
-
-<p class='c010'>“The series of ancestors may have possessed larger antlers
-in each generation than in the generation before it. It is not
-<span class='pageno' id='Page_78'>78</span>an occasional accidental parallelism between the ontogeny
-and the phylogeny which I deny, but the causal relation
-between the two. Had the ancestors had larger antlers than
-the existing ones, there is no justification for the assumption
-that existing stags would acquire antlers of which each pair,
-in later years, would be smaller than those of the previous
-year.”</p>
-
-<p class='c010'>Hurst concludes: “There are many breeds of hornless
-sheep, but they do not bear large horns in early years and
-then shed them. If a rudiment ever appears in the embryo
-of such sheep, its growth is very early arrested.” The case
-of the appendix in man might have been cited here as
-a case in point. It is supposed to have been larger in the
-ancestors of man, but we do not find it appearing full size in
-the embryo and later becoming rudimentary. The preceding
-statements will show that, while Hurst’s view is similar in some
-respects to my own, yet it differs in one fundamental respect
-from it, and in this regard he approaches more nearly to the
-theory of Von Baer.</p>
-
-<p class='c010'>Hertwig has recently raised some new points of issue in
-regard to the recapitulation theory, and since he may appear
-to have penetrated farther than most other embryologists of
-the present time, it will be necessary to examine his view
-somewhat carefully. He speaks of the germ-cell (egg, or
-spermatozoön) as a species-cell, because it contains, in its
-finer organization, the essential features of the species to
-which it belongs. There are as many of these kinds of cells
-as there are different kinds of animals and plants. Since the
-bodies of the higher animals have developed from these
-species-cells, so the latter must have passed in their phylogeny
-through a corresponding development from a simple to a
-more and more complex cell-structure. “Our doctrine is,
-that the species-cell, even as the adult, many-celled representative
-of the species, has passed through a progressive, and,
-indeed, in general a corresponding development in the course
-<span class='pageno' id='Page_79'>79</span>of phylogeny. This view appears to stand in contradiction to
-the biogenetic law. According to the formula that Haeckel
-has maintained, the germ development is an epitome of the
-genealogy; or the ontogeny is a recapitulation of the
-phylogeny; or, more fully, the series of forms through which
-the individual organism passes during its development from
-the egg-cell to the finished condition is a short, compressed
-repetition of the longer series of forms which the forefathers
-of the same organism, or the stem-form of the species, has
-passed through, from the earliest appearance of organisms to
-the present time.” “Haeckel admits that the parallel may
-be obliterated, since much may be absent in the ontogeny
-that formerly existed in the phylogeny. If the ontogeny were
-complete, we could trace the whole ancestry.” Hertwig states
-further, that “The theory of biogenesis<a id='r12' /><a href='#f12' class='c017'><sup>[12]</sup></a> makes it necessary
-to change Haeckel’s expression of the biogenetic law, so that
-a contradiction contained in it may be removed. We must
-drop the expression ‘repetition of the form of extinct forefathers,’
-and put in its place the repetition of forms which
-are necessary for organic development, and lead from the
-simple to the complex. This conception may be illustrated
-by the egg-cell.”</p>
-
-<div class='footnote c018' id='f12'>
-<p class='c019'><span class='label'><a href='#r12'>12</a>.&nbsp;&nbsp;</span>This term, by which Hertwig designates a particular view of his own, has
-been already preoccupied in a much wider sense by Huxley to mean that all life
-comes from preëxisting life. Hertwig means by the theory of biogenesis that as
-the egg develops there is a constant interchange between itself and its surroundings.</p>
-</div>
-
-<p class='c010'>Since each organism begins its life as an egg we must not
-suppose that the primitive conditions of the time, when only
-single-celled amœbas existed on our planet, are repeated.
-The egg-cell of a living mammal is not, according to Hertwig’s
-hypothesis, an indifferent structure without much specialization
-like an amœba, but is an extraordinarily complex
-end-product of a long historical process, which the organized
-substance has passed through. If the egg of a mammal
-is different from that of a reptile, or of an amphibian,
-<span class='pageno' id='Page_80'>80</span>because in its organization it contains the basis of a mammal,
-just so much more must it be different from the hypothetical
-one-celled amœba, which has no other characteristics than
-those that go to make up an amœba. Expressed more generally,
-the developmental process in the many-celled organisms
-begins, not where it began in primitive times, but as the
-representation of the highest point which the organization
-has at present reached. The development commences with
-the egg, because it is the elemental and fundamental form in
-which organic life is represented in connection with the
-reproductive process, and also because it contains in itself the
-properties of the species in its primordia.</p>
-
-<p class='c010'>“The egg-cell of the present time, and its one-celled predecessor
-in the phylogenetic history, the amœba, are only
-comparable in so far as they fall under the common definition
-of the cell, but beyond this they are extraordinarily different
-from each other.”</p>
-
-<p class='c010'>“The phyletic series must be divided into two different kinds
-of processes:—First. The evolution of the species-cell, which
-is a steady advance from a simple to a complex organization.
-Second. The periodically repeated development of the many-celled
-individual out of the single cell, representative of the
-species (or the individual ontogeny), which in general follows
-the same rules as the preceding ontogeny, but is each time
-somewhat modified according to the amount to which the
-species-cell has itself been changed in the phylogeny.
-Similar restricting and explanatory additions to the biogenetic
-law, like those stated here for the one-celled stage, must be
-made in other directions. Undoubtedly there exists in a
-certain sense a parallel between the phylogenetic, and the
-ontogenetic, development.</p>
-
-<p class='c010'>“On the basis of the general developmental hypothesis on
-which we stand, all forms which in the chain of ancestors
-were end-products of the individual development are now
-passed through by their descendants as embryonic stages, and
-<span class='pageno' id='Page_81'>81</span>so in a certain degree are recapitulated. We also admit that
-the embryonic forms of higher animals have many points of
-comparison with the mature forms of related groups standing
-lower in the system.</p>
-
-<p class='c010'>“Nevertheless, a deeper insight into the conditions relating
-to these resemblances shows that there are very important
-differences that should not be overlooked. Three
-points need to be mentioned: 1. The cell-material which in
-the ancestral chain gives the basis for each ontogenetic process
-is each time a different material as far as concerns its finer
-organization and primordia. Indeed, the differences become
-greater the farther apart the links of the original chain
-become. This thought may be formulated in another way:
-The same ontogenetic stages that repeat themselves periodically
-in the course of the phylogeny always contain at bottom
-a somewhat different cell-material. From this the second rule
-follows as a consequence. 2. Between the mature end-form
-of an ancestor and the corresponding embryonic form of a
-widely remote descendant (let us say between the phylogenetic
-gastræa and the embryonic gastrula stage of a living
-mammal, according to the terminology of Haeckel) there
-exists an important difference, namely, that the latter is supplied
-with numerous primordia which are absent in the other,
-and which force it to proceed to the realization of its developmental
-process. The gastrula, therefore, as the bearer of
-important latent forces, is an entirely different thing from the
-gastræa, which has already reached the goal of its development.
-3. In the third place, at each stage of the ontogeny outer and
-inner factors are at work, in fact even more intensely than
-in the fully formed organism. Each smallest change that acts
-anew in this way at the beginning of the ontogeny can start
-an impulse leading to more extensive changes in later stages.
-Thus the presence of yolk and its method of distribution in
-the egg alone suffice to bring about important changes in
-the cleavage, and in the formation of the germ-layers, the
-<span class='pageno' id='Page_82'>82</span>blastula, and gastrula stages,” etc. “Moreover, the embryo
-may adapt itself to special conditions of embryonic life, and
-produce organs of an ephemeral nature like the amnion,
-chorion, and placenta.”</p>
-
-<p class='c010'>“A comparison of ontogenetic with antecedent phylogenetic
-stages must always keep in view the fact that the
-action of external and internal factors has brought about
-considerable changes in the ontogenetic system, and, indeed,
-in a generally advancing direction, so that in reality a later
-condition can never correspond to a preceding one.”</p>
-
-<p class='c010'>Hertwig sums up his conclusion in the statement that
-ontogenetic stages give us, therefore, a greatly changed
-picture of the phylogenetic series of adult ancestors. “The
-two correspond not according to their actual contents but
-only as to their form.” Hertwig also repeats His’s idea, that
-the reason that certain kinds of form repeat themselves in
-the development of animals with a great constancy depends
-principally on this, that they supply the necessary conditions
-under which alone the following higher stage of the ontogeny
-can be formed. The development, for instance, begins with
-the division of the egg, because this is the only way that a
-one-celled condition can give rise to a many-celled form.
-Again, the organs can be formed only when groups of cells
-have made a closer union with one another. Thus the gastrula
-must begin with the antecedent blastula, etc. Definite forms
-are, despite all modifying influences, held to firmly, because
-by their presence the complicated end-stages can be reached
-in the simplest and most suitable way.</p>
-
-<p class='c010'>Thus Hertwig adopts here a little from one doctrine and
-there a little from another, and between his attempt to reinstate
-the old biogenetic law of Haeckel, and to adopt a more modern
-point of view, he brings together a rather curious collection of
-statements which are not any too well coördinated. Take,
-for example, his description of the relation between Haeckel’s
-gastræa and the embryonic gastrula stage. The latter he
-<span class='pageno' id='Page_83'>83</span>maintains is a repetition of the other, but only in form, not in
-actual contents. And in another connection we are told that
-the cause of this repetition is that the gastrula is the simplest
-way in which the later stages can be reached, and, therefore,
-it has been retained. It seems to me that Hertwig has undertaken
-an unnecessary and impossible task when he attempts
-to adjust the old recapitulation theory to more modern
-standards. His statement that the egg is entirely different
-from its amœba prototype is, of course, only the view generally
-held by all embryologists. His mystical statement that the
-embryonic form <i>repeats the ancestral adult stage in its form,
-but not in its contents</i>, will scarcely recommend itself as a
-model of clear thinking. Can we be asked to believe for
-instance that a young chick repeats the ancestral adult fish
-form but not the contents of the fish?</p>
-
-<p class='c010'>In conclusion, then, it seems to me that <i>the idea that adult
-ancestral stages have been pushed back into the embryo, and
-that the embryo recapitulates in part these ancestral adult
-stages is in principle false</i>. The resemblance between the
-embryos of higher forms and the adults of lower forms is
-due, as I have tried to show, to the presence in the embryos
-of the lower groups of certain organs that remain in the
-adult forms of this group. It is only the embryonic stages of
-the two groups that we are justified in comparing; and their
-resemblances are explained on the assumption that there
-has been an ancestral adult form having these embryonic
-stages in its development and these stages have been handed
-down to the divergent lines of its descendants.</p>
-
-<p class='c010'>Since we have come to associate with the name of the
-recapitulation theory the idea of the recurrence of an ancestral
-adult form, it may be better to find a substitute for this
-term. I suggest, therefore, for the view, that the embryos
-of the higher group repeat the modified form of the embryos
-of the lower groups, the term, the theory of embryonic
-repetition, or, more briefly, the repetition theory.</p>
-<div>
-  <span class='pageno' id='Page_84'>84</span>
-  <h3 class='c014'><span class='sc'>Conclusions</span></h3>
-</div>
-
-<p class='c015'>In the light of the preceding discussion concerning the
-evidence in favor of the transmutation theory, we may now
-proceed to sum up our general conclusions, and at the same
-time discuss some further possibilities in regard to the
-descent theory.</p>
-
-<p class='c010'>The most widely accepted view in regard to the theory of
-organic evolution is that which looks upon the resemblances
-between the members of a group as due to their common
-descent from one original species that has broken up, as it
-were, into a number of new forms. Strictly applied, this
-means that all the vertebrates have come from one original
-species, all the mollusks from another, the echinoderms from
-a third, etc. Even farther back there may have been a common
-ancestral species for any two of the large groups, as,
-for example, the annelids and the mollusks; and if the relationship
-of all the many-celled forms be looked upon as
-probable, then they too have originated from one ancestral
-species.</p>
-
-<p class='c010'>Many zoologists appear to hesitate to apply strictly this
-fundamental idea contained in the transmutation theory, because,
-perhaps, they feel that it does not fit in with their general
-experience of living forms. Yet there can be no doubt
-that it is the primary conception of the transmutation
-theory. This is, however, not the whole question, for we
-must further consider the number of individuals of a species
-that are involved.</p>
-
-<p class='c010'>In some species there are smaller groups of individuals
-that are more like one another than like other individuals of
-the same species. Such groups are called varieties, and are
-often associated with certain localities, or with a special
-environment. In the latter case they are called local varieties.
-Some of these appear to breed true, not only when
-kept under the same conditions, but even when transferred
-<span class='pageno' id='Page_85'>85</span>to a new environment. Others change with the environment.
-It is not improbable that the varieties are of a different
-kind in these two cases, as shown by their different
-behavior when put under new and different surroundings.
-The variety that owes its peculiarities, not to the immediate
-environment, but to some internal condition independent of
-the surroundings, is recognized by some biologists as a
-smaller species. Such species appear to be commoner in
-plants than in animals, although it is possible that this only
-means that more cases have been found by the botanists,
-owing to the greater ease with which plants can be handled.
-These smaller species, in contradistinction to the ordinary
-Linnæan species, differ from the latter in the smaller amount
-of differences between the groups, and probably also in that
-they freely interbreed, and leave fertile descendants; but
-whether this is only on account of the smaller differences
-between them than between larger species, or because of
-some more fundamental difference in the kind of variation
-that gives rise to these two kinds of groups, we do not know.</p>
-
-<p class='c010'>These smaller species, or constant varieties, as we may call
-them, may be looked upon as incipient Linnæan species,
-which, by further variations of the same, or of other sorts,
-may end by giving rise to true species. A genus composed
-of several species might be formed in this way, and then, if
-each species again broke up into a number of new groups,
-each such group would now be recognized as a genus, and
-the group of genera would form a family, etc. The process
-continuing, a whole class, or order, or even phylum, might be
-the result of this process that began in a single species.</p>
-
-<p class='c010'>But we must look still farther, and inquire whether the
-start was made from a single individual, that began to vary,
-or from a number of individuals, or even from all the individuals,
-of a species. If we suppose the result to depend
-on some external cause that affects all the individuals of a
-species alike, then it might appear that the species, or at
-<span class='pageno' id='Page_86'>86</span>least as many individuals of a species as are affected, will
-give the starting-point for the new group. But if the new
-variation arises not directly as a response to some change in
-the surroundings, then it might appear in one or in a few
-individuals at a time. Let us consider what the results
-might be under these two heads.</p>
-
-<p class='c010'>If amongst the descendants of a single individual a new
-form or a number of new forms were to arise, then, if they
-represented only a variety, they would cross with the other
-forms like the parent species; and, under these conditions, it
-is generally assumed that the new variety would be swamped.
-If, however, the new forms have the value of new species,
-then, <i>ex hypothese</i>, they are no longer fertile with the original
-forms, and might perpetuate themselves by self-fertilization,
-as would be possible in some of the higher plants, and in
-those animals that are bisexual. But as a rule even bisexual
-forms are not self-fertilized, and, therefore, unless a number
-of offspring arose from the same form the chance of propagation
-would be small.</p>
-
-<p class='c010'>If, however, a number of new forms appeared at the same
-time and left a number of descendants, then the probability
-that the new group might perpetuate itself is greater, and the
-chance that such a group would arise is in proportion to the
-number of individuals that varied in the same direction simultaneously.
-In this case the new species has not come from
-a single individual or even from a pair of individuals, but from
-a number of individuals that have varied more or less in the
-same direction.</p>
-
-<p class='c010'>This point of view puts the descent theory in a somewhat
-unforeseen light, for we cannot assume in such a case that the
-similarities of the members of even the same species are due
-to direct descent from an original ancestor, because there are
-supposed to have been a number of ancestors that have
-all changed in the same direction. The question is further
-complicated by the fact that the new individuals begin to
-<span class='pageno' id='Page_87'>87</span>interbreed, so that their descendants come to have, after a
-time, the common blood, so to speak, of all the new forms.
-If with each union there is a blending of the substances of
-the individuals, there will result in the end a common substance
-representing the commingled racial germ-plasm.</p>
-
-<p class='c010'>A new starting-point is then reached, and new species
-may continue to be formed out of this homogeneous material.
-Thus, in a sense, we have reached a position
-which, although it appears at first quite different from
-the ordinary view, yet, after all, gives us the same standpoint
-as that assumed by the transmutation theory; for, while
-the latter assumes that the resemblances of the members
-of a group are due to descent from the same original
-form, and often by implication from a single individual,
-we have here reached the conclusion that it is only a
-common, commingled germ-plasm that is the common inheritance.</p>
-
-<p class='c010'>When we examine almost any group of living animals or
-plants, whether they are low or high in organization, we
-find that it is composed of a great many different species,
-and so far as geology gives any answer, we find that this
-must have been true in the past also. Why, then, do we
-suppose that all the members of the higher groups have
-come from a single original species or variety? Why may
-not all, or many, of the similar species of the lower group
-have changed into the species of the higher group,—species
-for species? If this happened, the resemblance of the new
-species of the group could be accounted for on the supposition
-that their ancestors were also like one another. The
-likeness would not be due, then, to a common descent, and
-it would be false to attempt to explain their likeness as due to
-a common inheritance. But before going farther, it may be
-well to inquire to what the resemblances of the individuals of
-the original species were due; for, if they have come from an
-older group that has given rise to divergent lines of descent,
-<span class='pageno' id='Page_88'>88</span>then we are only removing the explanation one step farther
-back. If this original group has come from numerous species
-of a still older group, and this, in turn, from an older one
-still, then we must go back to the first forms of life that appeared
-on the globe, and suppose that the individuals of these
-primitive forms are the originals of the species that we find
-living to-day. For instance, it is thinkable that each species
-of vertebrate arose from a single group of the earliest forms
-of life that appeared on the surface of the earth. If this
-were the case, there must have been as many different kinds
-of species of the original group as there are species alive at
-the present time, and throughout all the past. This view finds
-no support from our knowledge of fossil remains, and, although
-it may be admitted that this knowledge is very incomplete,
-yet, if the process of evolution had taken place as
-sketched out above, we should expect, at least, to have found
-some traces of it amongst fossil forms. Since this question
-is an historical one, we can, at best, only expect to decide
-which of all the possible suggestions is the more probable.</p>
-
-<p class='c010'>We conclude, then, that it is more probable that the vertebrates,
-the mollusks, the insects, the crustaceans, the annelids,
-the cœlenterates, and the sponges, etc., have come each from
-a single original species. Their resemblances are due to a
-common inheritance from a common ancestral species. Even
-if it be probable that at the time when the group of vertebrates
-arose from a single species, there were in existence
-other closely related species, yet we must suppose, if we
-adhere to our point of view, that these other related species
-have had nothing to do with the group of vertebrates, but that
-they have died out. Moreover, we must suppose that each
-order, each class of vertebrate, has come from a single original
-species; each family has had a similar origin, as well as
-each genus, but, of course, at different periods of time. Let
-us not shrink from carrying this principle to its most extreme
-point, for, unless the principle is absolutely true, then our
-<span class='pageno' id='Page_89'>89</span>much boasted explanation of the resemblances of forms in
-the same group will be thrown into hopeless confusion.</p>
-
-<p class='c010'>Let us ask another question in this connection. If a single
-species gave rise to a group of new species that represented
-the first vertebrates, they would have formed the first genus;
-and if the descendants of these diverged again so that new
-genera were formed, then a group which we should call a
-family would have been formed.</p>
-
-<p class='c010'>As the divergence went on, an <i>order</i> would be developed,
-and then a <i>class</i>, and then a <i>phylum</i>. The common characters
-possessed by the members of this phylum would have
-been present in the original species that began to diverge.
-Hence, we find the definition of the phylum containing only
-those points that are the features possessed by all of the descendants,
-and in the same way we should try to construct
-the definition of each of the subordinate groups. This is the
-ideal of the principle of classification based on the theory of
-descent with divergence. If we admit the possibility of the
-other view that I have mentioned above, or of any other of
-the numerous possibilities that will readily suggest themselves,
-then we must be prepared to give up some of the
-most attractive features of the explanation of resemblance
-as due to descent.</p>
-
-<p class='c010'>That all biologists believe strictly in divergent descent, to
-the exclusion of any other processes, is not the case. And,
-as I have said before, since we are dealing with an historical
-question, it would be very unwise, in our present ignorance
-on many points, to pretend that we have any direct proof of
-the explanation that we find generally given to account for
-the resemblances of the species of a group to each other.
-At most we can claim that it is the simplest point of view,
-and that most biologists believe it to be also the most probable.
-It has been suggested that, in some cases, the new
-forms that arise from two or more species run a parallel
-course. If the original forms from which they came were
-<span class='pageno' id='Page_90'>90</span>very much alike, it would soon be impossible to say what
-the parentage of a particular form was; that is, to which of
-the two original forms it belonged. It has also been suggested
-that even a convergence has at times taken place, so
-that the descendants of different species have become more
-alike than the original forms, <i>at least in some one or more respects</i>.
-This last limitation is the saving clause, for species
-differ in so many points that, even when they converge in a
-few, it is unlikely that they will do so in all, and, therefore,
-the deception may be discovered by the acute observer. One
-famous paleontologist has gone so far even as to suppose that
-a species may change its generic characters, so that it goes
-over bodily into a new genus without losing its specific characters.
-If such things do occur, then our classifications may
-well be the laughing-stock of Nature.</p>
-
-<div class='pbb'>
- <hr class='pb c006' />
-</div>
-<div class='chapter'>
-  <span class='pageno' id='Page_91'>91</span>
-  <h2 class='c008'>CHAPTER IV<br /> <br /><span class='c013'>DARWIN’S THEORIES OF ARTIFICIAL AND OF NATURAL SELECTION</span></h2>
-</div>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div><span class='c013'><span class='sc'>The Principle of Selection</span></span></div>
-  </div>
-</div>
-
-<p class='c009'><span class='sc'>Darwin’s</span> theory of natural selection is preëminently a theory
-of adaptation. It appears, in fact, better suited to explain
-this phenomenon than that of the “origin of species.” Darwin
-prepared his reader for the ideas contained in the theory
-of natural selection by a brief consideration of the results of
-artificial selection; and since the key to the situation is, I
-believe, to be found in just this supposed resemblance, we
-cannot do better than examine the theories in the order followed
-by Darwin himself.</p>
-
-<p class='c010'>One of the means by which the artificial races of animals
-and plants have been formed by man is selection. The
-breeder picks out individuals having a certain peculiarity, and
-allows them to breed together. He hopes to find among
-the offspring, not only individuals like the parent forms, but
-also some that have the special peculiarity even more strongly
-developed. If such are found, they are isolated and allowed
-to breed, and in the next generation it is hoped to find one or
-more new individuals that show still more developed the
-special character that is sought. This process, repeated
-through a number of generations, is supposed to have led to
-the formation of many of our various forms of domesticated
-animals and plants.</p>
-
-<p class='c010'>This heaping up as a result of the union of similar individuals
-cannot for a moment be supposed to be the outcome of
-the addition of the two variations to each other. Such an
-<span class='pageno' id='Page_92'>92</span>idea is counter to all the most familiar facts of inheritance.
-For instance, when two similar forms unite, we do not find
-that the young show all the characters of the mother plus all
-those of the father, <i>i.e.</i> each peculiarity that is the same in
-both, increased twofold. On the contrary, the young are in
-the vast majority of cases not essentially different from either
-parent.</p>
-
-<p class='c010'>A more thorough examination of the facts shows that the
-problem is by no means so simple as the preceding general
-statement might lead one to suppose, for our experience
-shows that it is not always possible to increase all variations
-by selection, and, furthermore, there is very soon found a
-limit, even in favorable cases, to the extent to which the process
-can be carried. The most important point appears to be
-the nature of the variations themselves which may arise from
-different causes, and which have different values in relation
-to the possibility of their continuation.</p>
-
-<p class='c010'>We may begin, therefore, by following Darwin in his analysis
-of variation, as given in the opening chapter of the “Origin
-of Species.” He thinks that the great amount of
-variation shown by domesticated animals and plants is due,
-in the first place, to the new conditions of life to which they
-are exposed, and also to the lack of uniformity of these conditions.
-Darwin thinks, also, that there is some probability
-that this variability is due, in part, to an excess of food. “It
-seems clear that organic beings must be exposed during several
-generations to new conditions to cause any great amount
-of variation, and that when the organization has once begun
-to vary, it generally continues varying for many generations.
-No case is on record of a variable organism ceasing to vary
-under cultivation. Our oldest cultivated plants, such as
-wheat, still yield new varieties; our oldest domesticated animals
-are still capable of rapid improvement or modification.”
-In this statement of Darwin, full of significance, we must
-be careful to notice that he does not mean to imply, when he
-<span class='pageno' id='Page_93'>93</span>states that an organism that has once begun to vary continues
-to vary for many generations, that this continuous
-variation is always in the same direction, but only that
-new combinations, scattering in all directions, continue to
-appear.</p>
-
-<p class='c010'>The nature of the organism seemed to Darwin to be a more
-important factor in the origin of new variations than the
-external conditions, “for nearly similar variations sometimes
-arise under, as far as we can judge, dissimilar conditions;
-and, on the other hand, dissimilar variations arise under conditions
-which appear to be nearly uniform.” The following
-statement is important in connection with the origin of
-“definite” variations. “Each of the endless variations which
-we see in the plumage of our fowls must have had some
-efficient cause; and if the same causes were to act uniformly
-during a long series of generations on many individuals, all
-probably would be modified in the same direction.” Here
-we find an explicit statement in regard to the accumulation of
-variation in a given direction as the result of an external
-agent, but Darwin hastens to add: “Indefinite variability is a
-much more common result of changed conditions than definite
-variability, and has probably played a more important part in
-the formation of our domestic races. We see indefinite variability
-in the endless slight peculiarities which distinguish the
-individuals of the same species, and which cannot be accounted
-for by inheritance from either parent or from some more
-remote ancestor. Even strongly marked differences occasionally
-appear in the young of the same litter, and in seedlings
-from the same seed capsule. At long intervals of time,
-out of millions of individuals reared in the same country and
-fed on nearly the same food, deviations of structure so strongly
-pronounced as to deserve to be called monstrosities arise;
-but monstrosities cannot be separated by any distinct line
-from slighter variations.”</p>
-
-<p class='c010'>Another cause of variation, Darwin believes, is in the inherited
-<span class='pageno' id='Page_94'>94</span>effect of “habit and of the use and disuse of parts,”
-or what is generally known as the Lamarckian factor of
-heredity. Darwin believes that changes in the body of the
-parent, that are the result of the use or of the disuse of a part,
-may be transmitted to the descendants, and cites a number
-of cases which he credits to this process. As we shall deal
-more fully with this topic in another chapter, we may treat it
-here quite briefly. As an example of the inheritance of disuse,
-Darwin gives the following case: “I find in the domestic
-duck that the bones of the wing weigh less and the bones
-of the leg more in proportion to the whole skeleton than do
-the same bones in the wild duck, and this change may be
-safely attributed to the domestic duck flying much less and
-walking more than its wild parents.” The great and inherited
-development of the udders of cows and of goats in
-countries where they are habitually milked, in comparison
-with these organs in other countries, is given as another
-instance of the effect of use. “Not one of our domestic
-animals can be named that in some country has not drooping
-ears, and the view has been suggested that the drooping is
-due to the disuse of the muscles of the ears from the animals
-being seldom much alarmed.”</p>
-
-<p class='c010'>It need scarcely be pointed out here, that, in the first case
-given, those ducks would have been most likely to remain in
-confinement that had less well-developed wings, and hence
-at the start artificial selection may have served to bring
-about the result. The great development of the udders of
-cows and of goats is obviously connected with the greater
-milk-giving qualities of these animals, which may have been
-selected for this purpose.</p>
-
-<p class='c010'>Another “law” of variation recognized by Darwin is what
-is called correlated variation. For example, it has been
-found that cats which are entirely white and have blue eyes
-are generally deaf, and this is stated to be confined to the
-males. The teeth of hairless dogs are imperfect; pigeons
-<span class='pageno' id='Page_95'>95</span>with feathered feet have skin between the outer toes, and
-those with short beaks have small feet, and <i>vice versa</i>.</p>
-
-<p class='c010'>Another source of variation is that of reversion, or the
-reappearance in the offspring of characters once possessed
-by the ancestors. Finally, Darwin thinks that a source of
-variation is to be found in modifications due to the influence
-of a previous union with another male, or, as it is generally
-called, telegony. As an example Darwin cites the famous
-case of Lord Morton’s mare. “A nearly purely bred Arabian
-chestnut mare bore a hybrid to a quagga. She subsequently
-produced two colts by a black Arabian horse. These
-colts were partially dun-colored and were striped on the legs
-more plainly than the real hybrid or even than the quagga.”<a id='r13' /><a href='#f13' class='c017'><sup>[13]</sup></a>
-This case, however, is not above suspicion, since it is well
-known that stripes often appear on young horses, and the
-careful analysis made later by Ewart, as well as his other
-experiments on the possibility of the transmission of influences
-of this sort, puts the whole matter in a very dubious
-light.</p>
-
-<p class='c010'>These citations show that Darwin recognized quite a number
-of sources of variation, and, although he freely admits that
-“our ignorance of the laws of variation is profound,” yet
-some at least of these sources of variation are very questionable.
-Be this as it may, it is important to emphasize that
-Darwin recognized two main sources of variation,—one of
-which is the indefinite, or fluctuating, variability that appears
-constantly in domesticated animals and plants, and the other,
-definite variability, or a change in a definite direction, that can
-often be traced to the direct action of the environment on
-the parent or on its reproductive cells. It is the former,
-<i>i.e.</i> the fluctuating variability, that, according to Darwin, has
-been used by the breeder to produce most of our domestic
-races. In regard to the other source of variation, the
-definite kind, we must analyze the facts more closely.</p>
-
-<div class='footnote c018' id='f13'>
-<p class='c019'><span class='label'><a href='#r13'>13</a>.&nbsp;&nbsp;</span>“Animals and Plants under Domestication,” Chap. IX.</p>
-</div>
-
-<p class='c010'><span class='pageno' id='Page_96'>96</span>A definite change in the surroundings might bring about
-a definite change in the next generation, because the new condition
-acts either on the developing organism, or on the egg
-itself from which the individual develops. The distinction
-may be one of importance, for, if the new condition only
-effects the developing organism directly, then, when the influence
-is removed, there should be a return to the former
-condition; but if the egg itself is affected, so that it is
-fundamentally changed, then the effect might persist even if
-the animal were returned to its former environment. More
-important still is Darwin’s recognition of the cumulative
-effect in a given direction of external influences, for a new
-variation, that was slight at first, might, through prolonged
-action, continue to become more developed without any other
-processes affecting the organism.</p>
-
-<p class='c010'>From the Darwinian point of view, however, the all-important
-source for the origin of new forms is the fluctuating
-variation, which is made use of both in the process of artificial
-and of natural selection. We may now proceed to
-inquire how this is supposed to take place.</p>
-
-<p class='c010'>It has been stated that, by means of artificial selection,
-Darwin believes the breeder has produced the greater number
-of domesticated animals and plants. The most important
-question is what sort of variations he has made use of in
-order to produce his result. Has he made use of the
-fluctuating variations, or of the definite ones? It is difficult,
-if not impossible, to answer this question in most
-cases, because the breeder does not always distinguish between
-the two. There can be little question, however, that
-he may sometimes have made use of the definite kinds,
-whether these are the outcome of external or of internal
-influences. The question has been seriously raised only in
-recent years, and we are still uncertain how far we can accumulate
-and fix a variation that is of the fluctuating kind. In
-a few cases it has been found that the upper limit is soon
-<span class='pageno' id='Page_97'>97</span>reached, as shown by De Vries’s experiments with clover,
-and it is always possible that a definite variation of the
-right sort may arise at any stage of the process. If this
-should occur, then a new standard is introduced from which,
-as from a new base, variations fluctuating in the desired
-direction may be selected.</p>
-
-<p class='c010'>This question, before all others, ought to be settled before
-we begin to speculate further as to what selection is able
-to accomplish.</p>
-
-<p class='c010'>Darwin’s theory is often stated in such a general way
-that it would be applicable to either sort of variation; but
-if definite variation can go on accumulating without selection,
-then possibly we could account for evolution without
-supposing any other process to intervene. Under these
-circumstances all that could be claimed for selection would
-be the destruction of those variations incapable of living,
-or of competing with other forms. Hence the process of
-selection would have an entirely negative value.</p>
-
-<p class='c010'>The way in which domesticated animals and plants have
-originated is explained by Darwin in the following significant
-passage:—</p>
-
-<p class='c010'>“Let us now briefly consider the steps by which domestic
-races have been produced, either from one or from several
-allied species. Some effect may be attributed to the direct
-and definite action of the external conditions of life, and
-some to habit; but he would be a bold man who would
-account by such agencies for the differences between a dray-
-and race-horse, a greyhound and bloodhound, a carrier and
-tumbler pigeon. One of the most remarkable features in
-our domesticated races is that we see in them adaptation,
-not indeed to the animal’s or plant’s own good, but to man’s
-use or fancy. Some variations useful to him have probably
-arisen suddenly, or by one step; many botanists, for instance,
-believe that the fuller’s-teasel, with its hooks, which cannot
-be rivalled by any mechanical contrivance, is only a variety
-<span class='pageno' id='Page_98'>98</span>of the wild Dipsacus; and this amount of change may have
-suddenly arisen in a seedling. So it has probably been with
-the turnspit dog; and this is known to have been the case
-with the ancon sheep. But when we compare the dray-horse
-and race-horse, the dromedary and camel, the various
-breeds of sheep fitted either for cultivated land or mountain
-pasture, with the wool of one breed good for one purpose,
-and that of another breed for another purpose; when we
-compare the many breeds of dogs, each good for man in
-different ways; when we compare the game-cock, so pertinacious
-in battle, with other breeds so little quarrelsome, with
-‘everlasting layers’ which never desire to sit, and with the
-bantam so small and elegant; when we compare the host
-of agricultural, culinary, orchard, and flower-garden races
-of plants, most useful to man at different seasons and for
-different purposes, or so beautiful in his eyes, we must, I
-think, look further than to mere variability. We cannot
-suppose that all the breeds were suddenly produced as perfect
-and as useful as we now see them; indeed, in many
-cases, we know that this has not been their history. The
-key is man’s power of accumulative selection: nature gives
-successive variations; man adds them up in certain directions
-useful to him. In this sense he may be said to have
-made for himself useful breeds.”</p>
-
-<p class='c010'>Darwin also gives the following striking examples, which
-make probable the view that domestic forms have really
-been made by man selecting those variations that are useful
-to him:—</p>
-
-<p class='c010'>“In regard to plants, there is another means of observing
-the accumulated effects of selection—namely, by comparing
-the diversity of flowers in the different varieties of the same
-species in the flower-garden; the diversity of leaves, pods,
-or tubers, or whatever part is valued, in the kitchen-garden,
-in comparison with the flowers of the same varieties; and
-the diversity of fruit of the same species in the orchard, in
-<span class='pageno' id='Page_99'>99</span>comparison with the leaves and flowers of the same set of
-varieties. See how different the leaves of the cabbage are,
-and how extremely alike the flowers; how unlike the flowers
-of the heartsease are, and how alike the leaves; how much
-the fruit of the different kinds of gooseberries differ in size,
-color, shape, and hairiness, and yet the flowers present very
-slight differences. It is not that the varieties which differ
-largely in some one point do not differ at all in other points;
-this is hardly ever,—I speak after careful observation,—perhaps
-never, the case. The law of correlated variation, the
-importance of which should never be overlooked, will insure
-some differences; but, as a general rule, it cannot be doubted
-that the continued selection of slight variations, either in the
-leaves, the flowers, or the fruit, will produce races differing
-from each other chiefly in these characters.”</p>
-
-<p class='c010'>Exception may perhaps be taken to the concluding sentence,
-for, interesting as the facts here recorded certainly
-are, it does not necessarily follow that all domestic products
-have arisen “by the continued selection of slight variations,”
-however probable the conclusion may appear. Darwin also
-believes that a process of “unconscious selection” has given
-even more important “results than methodical selection.” By
-unconscious selection is meant the outcome of “every one
-trying to possess and breed from best individual animals.”
-“Thus a man who intends keeping pointers naturally tries
-to get as good dogs as he can, and afterwards breeds from
-his own best dogs, but he has no wish, or expectation of permanently
-altering the breed. Nevertheless we may infer
-that this process, continued during centuries, would improve
-and modify any breed.... There is reason to believe that
-the King Charles spaniel has been unconsciously modified
-to a large extent since the time of that monarch.”</p>
-
-<p class='c010'>The enormous length of time required to produce new
-species by the selection of fluctuating variations is everywhere
-admitted by Darwin; nowhere perhaps more strikingly
-<span class='pageno' id='Page_100'>100</span>than in the following statement: “If it has taken centuries or
-thousands of years to improve or modify most of our plants
-up to their present standard of usefulness to man, we can
-understand how it is that neither Australia, the Cape of
-Good Hope, nor any other region inhabited by quite uncivilized
-man has afforded us a single plant worth culture. It is
-not that these countries, so rich in species, do not by a
-strange chance possess the aboriginal stocks of any useful
-plants, but that the native plants have not been improved by
-continued selection up to a standard of perfection comparable
-with that acquired by the plants in countries anciently
-civilized.”</p>
-
-<p class='c010'>In reply to this, it may be said that if the selection of
-fluctuating variations leads to an accumulation in the given
-direction, it is not apparent why it should take thousands of
-years to produce a new race, or require such a high degree
-of skill as Darwin supposes the breeder to possess.</p>
-
-<p class='c010'>The conditions favorable to artificial selection are, according
-to Darwin: 1. The possession of a large number of individuals,
-for in this way the chance of the desired variation
-appearing is increased. 2. Prevention of intercrossing, such
-as results when the land is enclosed, so that new forms may
-be kept apart. 3. Changed conditions, as introducing variability.
-4. The intercrossing of aboriginally distinct species.
-5. The intercrossing of new breeds, “but the importance
-of intercrossing has been much exaggerated.” 6. In plants
-propagation of bud variations by means of cuttings. The
-chapter concludes with the statement, “Over all these
-causes of Change, the accumulative action of Selection,
-whether applied methodically and quickly, or unconsciously
-and slowly, but more efficiently, seems to have been the predominant
-Power.”</p>
-
-<p class='c010'>Variability, Darwin says, is governed by many unknown
-laws, and the final result is “infinitely complex.” If this is
-so, we may at least hesitate before we accept the statement
-<span class='pageno' id='Page_101'>101</span>that selection of fluctuating variations has been the only
-principle that has brought about these results. This is a
-most important point, for, as we shall see, the central question
-in the theory of natural selection has come to be whether
-by the accumulation of fluctuating variations a new species
-could ever be produced. If it be admitted that the evidence
-from artificial selection is far from convincing, in showing
-that selection of fluctuating variations could have been the
-main source, even in the formation of new races, we need
-not be prejudiced in favor of such a process, when we come
-to examine the formation of species in nature.</p>
-
-<p class='c010'>There are still other questions raised in this same chapter
-that demand serious consideration. Darwin writes as
-follows:—</p>
-
-<p class='c010'>“When we look to the hereditary varieties or races of our
-domestic animals and plants, and compare them with closely
-allied species, we generally perceive in each domestic race, as
-already remarked, less uniformity of character than in true
-species. Domestic races often have a somewhat monstrous
-character; by which I mean, that, although differing from
-each other, and from other species of the same genus, in
-several trifling respects, they often differ in an extreme degree
-in some one part, both when compared one with another,
-and more especially when compared with the species under
-nature to which they are nearest allied. With these exceptions
-(and with that of the perfect fertility of varieties when
-crossed,—a subject hereafter to be discussed), domestic
-races of the same species differ from each other in the same
-manner as do the closely allied species of the same genus in
-a state of nature, but the differences in most cases are less in
-degree. This must be admitted as true, for the domestic
-races of many animals and plants have been ranked by some
-competent judges as the descendants of aboriginally distinct
-species, and by other competent judges as mere varieties. If
-any well-marked distinction existed between a domestic race
-<span class='pageno' id='Page_102'>102</span>and a species, this source of doubt would not so perpetually
-recur.”</p>
-
-<p class='c010'>The point here raised in regard to the systematic value of
-the new forms is the question that first demands our attention.
-We must exclude all those cases in which several original
-species have been blended to make a new form, because the
-results are too complicated to make use of at present. The
-domesticated races of dogs appear to have had such a multiple
-origin, the origin of horses is in doubt; but the domesticated
-pigeons, ducks, rabbits, and fowls are supposed, by
-Darwin, to have come each from one original wild species.
-The great variety of the domestic pigeons gives perhaps the
-most striking illustration of changes that have taken place
-under domestication; and Darwin lays great stress on the
-evidence from this source.</p>
-
-<p class='c010'>It seems probable in this case, (1) that all the different
-races of pigeons have come from one original species; (2) that
-the structural differences are in some respects as great as those
-recognized by systematists as specifically distinct; (3) that the
-different races breed true to their kind; (4) that the result
-has been reached mainly by selecting and isolating variations
-that have appeared under domestication, and that probably
-some, at least, of these variations were fluctuating ones.</p>
-
-<p class='c010'>Does not this grant all that Darwin contends for? In one
-sense, yes; in another, no! The results appear to show that
-by artificial selection of some kind a group of new forms may
-be produced that in many respects resemble a natural family,
-or a genus; but if this is to be interpreted to mean that the
-result is the same as that by which natural groups have
-arisen, then I think that there are good reasons for dissenting
-from such a conclusion. Moreover, we must not grant too
-readily that the different races of pigeons have arisen by the
-selection of <i>fluctuating variations</i> alone, for this is not established
-with any great degree of probability by the evidence.</p>
-
-<p class='c010'>In regard to the first point we find that one of the most
-<span class='pageno' id='Page_103'>103</span>striking differences between species in nature is their infertility,
-and the infertility of their offspring when intercrossed.
-This is a very general rule, so far as we know. In regard to
-the different races of domesticated forms, the most significant
-fact is that, no matter how different they may be, they are
-perfectly fertile <i>inter se</i>. In this respect, as well as in others,
-there are important differences between domesticated races
-and wild species. The further difference, that has been
-pointed out by a number of writers, should also not pass
-unnoticed, namely, that the domestic forms differ from each
-other in the extreme development of some one character, and
-not in a large number of less conspicuous characters, as is the
-case in wild species.</p>
-
-<p class='c010'>These considerations show that, interesting and suggestive
-as are the facts of artificial selection, they fail to demonstrate
-the main point for which they are used by Darwin.
-With the most rigorous attention to the process of artificial
-selection, new species comparable in all respects to wild ones
-have not been formed, even in those cases in which the
-variation has been carried farthest (where the history of the
-forms is most completely known).</p>
-
-<p class='c010'>There is another point on which emphasis should be laid.
-If by selecting the most extreme forms in each generation
-and breeding from them the standard can be raised, it might
-appear that we could go on indefinitely in the same direction,
-and produce, for instance, pigeons with legs five metres long,
-and with necks of corresponding length. But experience has
-shown that this cannot be done. As Darwin frequently remarks,
-the breeder is entirely helpless until the desired variation
-appears. It seems possible, by selecting the more extreme
-of the fluctuating variations in each generation, that a higher
-plane of variation is established, and even that more extreme
-forms are likely to arise for a few generations; but, even if
-this is the case, a limit is soon reached beyond which it is
-impossible to go.</p>
-
-<p class='c010'><span class='pageno' id='Page_104'>104</span>The facts of observation show, that when a new variety
-appears its descendants are more likely, on the average, to
-produce proportionately more individuals that show the same
-variation, and some even that may go still farther in the same
-direction. If these latter are chosen to be the parents of the
-next generation, then once more the offspring may show the
-same advance; but little by little the advance slows down,
-until before very long it may cease altogether. Unless, then, a
-new kind of variation appears, or a new standard of variation
-develops of a different kind, the result of selection of fluctuating
-variations has reached its limit. Our experience seems,
-therefore, to teach us that selection of fluctuating variations
-leads us to only a certain point, and then stops in this direction.
-We get no evidence from the facts in favor of the
-view that the process, if carried on for a long time, could
-ever produce such great changes, or the kind of changes, as
-those seen in wild animals and plants.</p>
-<h3 class='c014'><span class='sc'>Variation and Competition in Nature</span></h3>
-
-<p class='c015'>Darwin rests his theory on the small individual variations
-which occur in nature, as the following quotation shows:—</p>
-
-<p class='c010'>“It may be doubted whether sudden and considerable
-deviations of structure such as we occasionally see in our
-domestic productions, more especially with plants, are ever
-permanently propagated in a state of nature. Almost every
-part of every organic being is so beautifully related to its
-complex conditions of life that it seems as improbable that
-any part should have been suddenly produced perfect, as that
-a complex machine should have been invented by man in a
-perfect state. Under domestication monstrosities sometimes
-occur which resemble normal structures in widely different
-animals. Thus pigs have occasionally been born with a sort
-of proboscis, and if any wild species of the same genus had
-naturally possessed a proboscis, it might have been argued
-<span class='pageno' id='Page_105'>105</span>that this had appeared as a monstrosity; but I have as yet
-failed to find, after diligent search, cases of monstrosities
-resembling normal structures in nearly allied forms, and
-these alone bear on the question. If monstrous forms of this
-kind ever do appear in a state of nature and are capable of
-reproduction (which is not always the case), as they occur
-rarely and singly, their preservation would depend on unusually
-favorable circumstances. They would, also, during the
-first and succeeding generations cross with the ordinary form,
-and thus their abnormal character would almost inevitably be
-lost.”</p>
-
-<p class='c010'>It is clear that Darwin does not think that the sudden and
-large variations that sometimes occur furnish the basis for
-natural selection, and the final statement in the last citation
-(which was added in later editions of the “Origin of Species”),
-to the effect that if such monstrous variations appeared as
-single or occasional variations they would be lost by intercrossing
-implies that, in general, single variations would likewise
-be lost unless they appeared in a sufficient number of individuals
-to maintain themselves against the swamping effects
-of intercrossing.</p>
-
-<p class='c010'>It is necessary to quote again, in order to show that, in
-some cases at least, Darwin believed selection plays little or
-no part in the origin and maintenance of certain peculiarities
-that are of no use to the species. “There is one point connected
-with individual differences, which is extremely perplexing:
-I refer to those genera which have been called
-protean or ‘polymorphic,’ in which the species present an
-inordinate amount of variation. With respect to many of
-these forms, hardly two naturalists agree, whether to rank
-them as species or as varieties. We may instance Rubus,
-Rosa, and Hieracium amongst plants, several genera of insects
-and of Brachiopod shells. In most polymorphic genera
-some of the species have fixed and definite characters. Genera
-which are polymorphic in one country seem to be, with
-<span class='pageno' id='Page_106'>106</span>a few exceptions, polymorphic in other countries, and likewise,
-judging from Brachiopod shells, at former periods of
-time. These facts are very perplexing, for they seem to show
-that this kind of variability is independent of the conditions
-of life. I am inclined to suspect that we see, at least in some
-of these polymorphic genera, variations which are of no
-service or disservice to the species, and which consequently
-have not been seized on by selection to act on and accumulate,
-in the same manner as man accumulates in any given direction
-individual differences in his domesticated productions.
-These individual differences generally affect what naturalists
-consider unimportant parts; but I could show by a long catalogue
-of facts, that parts which must be called important,
-whether viewed under a physiological or classificatory point
-of view, sometimes vary in the individuals of the same species.
-I am convinced that the most experienced naturalist would
-be surprised at the number of cases of variability, even in
-important parts of structure, which he could collect on good
-authority, as I have collected, during a course of years.”</p>
-
-<p class='c010'>After pointing out that naturalists have no definite standard
-to determine whether a group of individuals is a variety
-or a species, Darwin makes the highly important admissions
-contained in the following paragraph: “Hence, I look at individual
-differences, though of small interest to the systematist,
-as of the highest importance for us, as being the first steps
-toward such slight varieties as are barely thought worth recording
-in works on natural history. And I look at varieties
-which are in any degree more distinct and permanent, as
-steps toward more strongly marked and permanent varieties;
-and at the latter, as leading to subspecies, and then to species.
-The passage from one stage of difference to another may, in
-many cases, be the simple result of the nature of the organism
-and of the different physical conditions to which it has long
-been exposed; but with respect to the more important and
-adaptive characters, the passage from one stage of difference
-<span class='pageno' id='Page_107'>107</span>to another may be safely attributed to the cumulative action
-of natural selection, hereafter to be explained, and to the
-effects of the increased use or disuse of parts. A well-marked
-variety may therefore be called an incipient species;
-but whether this belief is justifiable must be judged by the
-weight of the various facts and considerations to be given
-throughout this work.”</p>
-
-<p class='c010'>In this paragraph attention should be called especially,
-first, to the statement in respect to the origin of varieties,
-which are said to arise through individual differences. It
-is not clear whether these differences are supposed to have
-appeared first in one, or in a few individuals, or in large
-numbers at the same time. Again, especial note should
-be made of the striking admission, that the passage from
-one stage to another may, in many cases, be the simple
-result of the nature of the organism and of the physical
-conditions surrounding it; but with respect to the more
-important and adaptive differences, natural selection “may
-safely” be supposed to have intervened. Is it to be wondered
-at that Darwin’s critics have sometimes accused him
-of playing fast and loose with the origin of varieties? And
-since this question is fundamental for the theory of natural
-selection, it is much to be regretted that Darwin leaves the
-matter in such a hazy condition. It may be said that, at
-the time when he wrote, he made the best of the evidence
-in regard to the origin of varieties. Be this as it may, a
-theory standing on no better foundations than this is not
-likely to be found satisfactory at the present time.</p>
-
-<p class='c010'>We come now to the most important chapters, the third
-and the fourth, of the “Origin of Species,” dealing with “the
-struggle for existence,” “natural selection,” or the “survival
-of the fittest.” Behind these fatal phrases, which have become
-almost household words, lurk many dangers for the unwary.</p>
-
-<p class='c010'>“It has been seen in the last chapter that amongst organic
-beings in a state of nature there is some individual variability:
-<span class='pageno' id='Page_108'>108</span>indeed I am not aware that this has ever been disputed. It
-is immaterial for us whether a multitude of doubtful forms be
-called species or subspecies or varieties; what rank, for instance,
-the two or three hundred doubtful forms of British
-plants are entitled to hold, if the existence of any well-marked
-varieties be admitted. But the mere existence of individual
-variability and of some few well-marked varieties, though
-necessary as the foundation for the work, helps us but little
-in understanding how species arise in nature. How have all
-those exquisite adaptions of one part of the organization to
-another part, and to the conditions of life, and of one organic
-being to another being, been perfected? We see these beautiful
-coadaptions most plainly in the woodpecker and the
-mistletoe; and only a little less plainly in the humblest
-parasite which clings to the hairs of a quadruped or feathers
-of a bird; in the structure of the beetle which dives through
-the water; in the plumed seed which is wafted by the
-gentlest breeze; in short, we see beautiful adaptions
-everywhere and in every part of the organic world.</p>
-
-<p class='c010'>“Again, it may be asked, how is it that varieties, which I
-have called incipient species, become ultimately converted
-into good and distinct species, which in most cases obviously
-differ from each other far more than do the varieties of the
-same species? How do those groups of species, which constitute
-what are called distinct genera, and which differ from
-each other more than do the species of the same genus, arise?
-All these results, as we shall more fully see in the next
-chapter, follow from the struggle for life. Owing to this
-struggle, variations, however slight and from whatever cause
-proceeding, if they be in any degree profitable to the individuals
-of a species, in their infinitely complex relations to other
-organic beings and to their physical conditions of life, will
-tend to the preservation of such individuals, and will generally
-be inherited by the offspring. The offspring, also, will
-thus have a better chance of surviving, for, of the many
-<span class='pageno' id='Page_109'>109</span>individuals of any species which are periodically born, but a
-small number can survive. I have called this principle, by
-which each slight variation, if useful, is preserved, by the
-term Natural Selection, in order to mark its relation to man’s
-power of selection. But the expression often used by Mr.
-Herbert Spencer of the Survival of the Fittest is more
-accurate, and is sometimes equally convenient. We have
-seen that man by selection can certainly produce great results,
-and can adapt organic beings to his own uses, through
-the accumulation of slight but useful variations, given to
-him by the hand of Nature. But Natural Selection, as we
-shall hereafter see, is a power incessantly ready for action,
-and is as immeasurably superior to man’s feeble efforts, as
-the works of Nature are to those of Art.”</p>
-
-<p class='c010'>Darwin gives the following explicit statement of the way
-in which he intends the term “struggle for existence” to be
-understood: “I should premise that I use this term in a
-large and metaphorical sense, including dependence of one
-being on another, and including (which is more important)
-not only the life of the individual, but success in leaving
-progeny. Two canine animals, in time of dearth, may be
-truly said to struggle with each other which shall get food
-and live. But a plant on the edge of a desert is said
-to struggle for life against the drought, though more
-properly it should be said to be dependent on the moisture.
-A plant which actually produces a thousand seeds of
-which only one on an average comes to maturity may be
-more truly said to struggle with the plants of the same and
-other kinds which already clothe the ground. The mistletoe
-is dependent on the apple, and a few other trees, but can
-only in a far-fetched sense be said to struggle with these
-trees, for if too many of these parasites grow on the same
-tree, it languishes and dies. But several seedling mistletoes,
-growing close together on the same branch, may more truly
-be said to struggle with each other. As the mistletoe is disseminated
-<span class='pageno' id='Page_110'>110</span>by birds, its existence depends on them, and it may
-metaphorically be said to struggle with other fruit-bearing
-plants, in tempting the birds to devour and thus disseminate
-its seeds. In these several senses, which pass into each other,
-I use for convenience’ sake the general term ‘Struggle for
-Existence.’”</p>
-
-<p class='c010'>A number of writers have objected to the general and
-often vague way in which Darwin makes use of this phrase;
-but it does not seem to me that this is a serious objection,
-provided we are on our guard as to what the outcome will
-be in each case. In each instance we must consider the
-question on its own merits, and if it is found convenient to
-have a sufficiently general and non-committal term, such as the
-“struggle for existence,” to include all cases, I see no serious
-objection to the use of such an expression, although it is
-true the outcome has been that it has become a catchword,
-that is used too often by those who have no knowledge of its
-contents.</p>
-
-<p class='c010'>Were it not that each animal and plant gives birth, on an
-average, to more than two offspring, the species would soon
-become exterminated by accidents, etc. We find in some of
-the lower animals, and in some of the higher plants, that
-thousands and even millions of eggs are produced by a
-single individual in the course of its life. A single nematode
-may lay sixty million eggs, and a tapeworm one thousand
-million. A starfish may produce about thirty-nine million
-eggs, a salmon may contain fifteen thousand, and a large shad
-as many as one hundred thousand. The queen of a termite
-nest is said to lay eighty thousand eggs a day.</p>
-
-<p class='c010'>In the higher vertebrates the number of young is considerably
-less, but since the young stages are passed within
-the body of the parent, proportionately more of them reach
-maturity, so that even in man the population may be doubled
-in twenty-five years, and in the elephant, slowest breeder of
-all animals, Darwin has calculated that, if it begins breeding
-<span class='pageno' id='Page_111'>111</span>when about thirty years old and goes on until ninety years,
-bringing forth six young in the interval, after 750 years
-there will be nearly nineteen million elephants alive which
-have descended from the first pair.</p>
-
-<p class='c010'>Obviously, then, if all the descendants of all the individuals
-of a species were to remain alive, the world would be over-crowded
-in a very short time, and the want of room would in
-itself lead to the destruction of countless individuals, if for
-no other reason than lack of food. We can easily carry out
-on a small scale an experiment that shows how the overstocking,
-resulting from favorable conditions, comes about, and how
-it checks itself. If we make a meat broth suitable for the
-life of a particular bacterium, and sow in the broth a very
-few individuals, we find in the course of several days the fluid
-swarming with the descendants of the original individuals.
-Thus it has been shown that, if we start with a few hundred
-bacteria, there will be five thousand after twenty-four hours,
-and twenty thousand, forty-eight hours later; and after four
-days they are beyond calculation.</p>
-
-<p class='c010'>Cohn found that a single bacterium produces two individuals
-in one hour, and four in two hours, and if they continue
-to multiply at this rate there will be produced at the end of
-three days 4,772 billions of descendants. If these are reduced
-to weight, they would weigh seventy-five hundred tons. Thus
-when the conditions are favorable, bacteria are able to increase
-at such an enormous rate that they could cover the
-surface of the earth in a very few days. The reason that
-they do not go on increasing at this rate is that they soon
-exhaust the food supply, and the rate of increase slows
-down, and will finally cease altogether. If the bacteria
-were dependent on a continuous supply of food, they would
-perish after the supply had been exhausted, so that the
-rapid rate of multiplication would serve only to bring
-the career of the organism to an untimely end. If the
-weaker individuals were to die first, the products of their disintegration
-<span class='pageno' id='Page_112'>112</span>might serve to nourish the stronger individuals;
-hunger coming on again, the next weakest might die; and the
-same process continuing, we might imagine that the bacteria
-were finally reduced to a single one which would then die in
-turn for lack of food. Like a starving shipload of men, reduced
-by hunger to cannibalism, the life of some and finally of
-the last individual might be prolonged in the hope of rescue,
-but if this did not arrive, the last and perhaps the strongest
-individual would perish. But this is not what we find occurring
-in these lower organisms, for, as a rule, they gradually
-cease to increase when the food supply becomes lessened, and
-their activities slow down. Finally, when the food is gone,
-they pass into a resting stage, in which condition they can
-remain dormant for a long time, even for years. If they
-should again find themselves in favorable surroundings,
-they become active, and begin once more their round of
-multiplication. We cannot follow the individuals in such a
-culture of bacteria, but there is nothing to be seen that
-suggests a struggle for existence, if this idea conveys the
-impression of the destruction of certain individuals by competition
-with others. In fact, the results are in some respects
-exactly the reverse. Millions of individuals are present at
-the time when the food supply becomes exhausted, and they
-all pass into a protected resting stage.</p>
-
-<p class='c010'>The enormous rate of increase in this case finds its counterpart
-in higher animals when the food supply, or the absence
-of enemies, allows a species to multiply at its maximum
-rate of increase. The introduction of rabbits into Australia
-was followed by an enormous increase in a few years, and the
-introduction of the English sparrow into the United States
-has had a similar result. But in no country can such a
-process continue beyond a certain point, because, in the first
-place, the scarcity of food will begin to keep the birth-rate
-down, and in the second place, the increase in numbers may
-lead to an increase in the number of its enemies, or even
-<span class='pageno' id='Page_113'>113</span>induce other forms to feed on it. Crowding will also give
-an opportunity for the spread of disease, which again may
-check the increase. Sooner or later a sort of ever shifting
-balance will be reached for each species, and after this, if the
-conditions remain the same, the number of individuals will
-keep approximately constant.</p>
-
-<p class='c010'>Darwin admits that the “causes which check the natural
-tendency of each species to increase are most obscure.” “We
-know not exactly what the checks are even in a single instance.”
-This admission may well put us on our guard
-against a too ready acceptation of a theory in which the whole
-issue turns on just this very point, namely, the nature of the
-checks to increase. Darwin gives the following general cases
-to show what some of the checks to increase are. He states
-that eggs and very young animals and seeds suffer more
-than the adults; that “the amount of food for each species of
-course gives the extreme limit to which each can increase;
-but very frequently it is not the obtaining food, but the serving
-as prey to other animals which determines the average numbers
-of a species. Thus, there seems to be little doubt that
-the stock of partridges, grouse, and hares on any large estate
-depends largely on the destruction of the vermin.” “On the
-other hand, in some cases, as with the elephant, none are destroyed
-by beasts of prey; for even the tiger in India most
-rarely dares to attack a young elephant protected by its
-dam.” “Climate plays an important part in determining
-the average number of a species, and periodical seasons of
-extreme cold or drought seem to be the most effective of all
-checks.” “The action of climate seems at first sight to be
-quite independent of the struggle for existence; but in so far
-as climate acts in reducing food, it brings on the most severe
-struggle between the individuals, whether of the same, or of
-distinct species which subsist on the same kind of food.”</p>
-
-<p class='c010'>We need not follow Darwin through his account of how
-complex are the relations of all animals and plants to one
-<span class='pageno' id='Page_114'>114</span>another in the struggle for existence, for, if true, it only
-goes to show more plainly how impossible it is to establish
-any safe scientific hypothesis, where the conditions are so
-complex and so impossible to estimate. To show that the
-young Scotch fir in an enclosed pasture is kept down by the
-browsing of the cattle, and in other parts of the world, Paraguay
-for instance, the number of cattle is determined by
-insects, and that the increase of these flies is <i>probably</i> habitually
-checked by other insects, leads to a bewilderingly complex
-set of conditions. We cannot do better than to quote
-Darwin’s conclusion: “Hence, if certain insectivorous birds
-were to decrease in Paraguay, the parasitic insects would
-probably increase; and this would lessen the number of the
-navel-frequenting flies—then cattle and horses would become
-feral, and this would certainly greatly alter (as indeed
-I have observed in parts of South America) the vegetation:
-this again would largely affect the insects; and this, as we
-have just seen in Staffordshire, the insectivorous birds, and
-so onwards in ever increasing circles of complexity. Not
-that under nature the relations will ever be as simple as this.
-Battle within battle must be continually recurring with varying
-success; and yet in the long run the forces are so nicely
-balanced, that the face of nature remains for long periods of
-time uniform, though assuredly the merest trifle would give
-the victory to one organic being over another. Nevertheless,
-so profound is our ignorance, and so high our presumption,
-that we marvel when we hear of the extinction of an organic
-being; and as we do not see the cause, we invoke cataclysms
-to desolate the world, or invent laws on the duration of the
-forms of life!”</p>
-
-<p class='c010'>The effect of the struggle for existence in determining <i>the
-distribution of species</i> is well illustrated in the following
-cases:—</p>
-
-<p class='c010'>“As the species of the same genus usually have, though
-by no means invariably, much similarity in habits and constitution,
-<span class='pageno' id='Page_115'>115</span>and always in structure, the struggle will generally
-be more severe between them, if they come into competition
-with each other, than between the species of distinct genera.
-We see this in the recent extension over parts of the United
-States of one species of swallow having caused the decrease
-of another species. The recent increase of the missel-thrush
-in parts of Scotland has caused the decrease of the song-thrush.
-How frequently we hear of one species of rat taking
-the place of another species under the most different climates!
-In Russia the small Asiatic cockroach has everywhere
-driven before it its great congener. In Australia the
-imported hive-bee is rapidly exterminating the small, stingless
-native bee. One species of charlock has been known to
-supplant another species; and so in other cases. We can
-dimly see why the competition should be most severe
-between allied forms, which fill nearly the same place in the
-economy of nature; but probably in no one case could we
-precisely say why one species has been victorious over
-another in the great battle of life.”</p>
-
-<p class='c010'>All this goes to show, if it really shows anything at all,
-that the distribution of a species is determined, in part, by
-its relation to other animals and plants—a truism that is
-recognized by every naturalist. The statement has no necessary
-bearing on the origin of new species through competition,
-as the incautious reader might infer. Not that I mean
-in any way to imply that Darwin intended to produce this
-effect on the reader; but Darwin is not always careful to
-discriminate as to the full bearing of the interesting illustrations
-with which his book so richly abounds.</p>
-
-<p class='c010'>At the end of his treatment of the subject, Darwin emphasizes
-once more how little we know about the subject of the
-struggle for existence.</p>
-
-<p class='c010'>“It is good thus to try in imagination to give to any one
-species an advantage over another. Probably in no single
-instance should we know what to do. This ought to convince
-<span class='pageno' id='Page_116'>116</span>us of our ignorance on the mutual relations of all
-organic beings; a conviction as necessary, as it is difficult,
-to acquire. All that we can do, is to keep steadily in mind
-that each organic being is striving to increase in a geometrical
-ratio; that each at some period of its life, during some
-season of the year, during each generation or at intervals,
-has to struggle for life and to suffer great destruction. When
-we reflect on this struggle, we may console ourselves with the
-full belief, that the war of nature is not incessant, that no
-fear is felt, that death is generally prompt, and that the vigorous,
-the healthy, and the happy survive and multiply.”</p>
-
-<p class='c010'>The kindliness of heart that prompted the concluding sentence
-may arouse our admiration for the humanity of the
-writer, but need not, therefore, dull our criticism of his theory.
-For whether no fear is felt, and whether death is prompt or
-slow, has no bearing on the question at issue—except as it
-prepares the gentle reader to accept the dreadful calamity of
-nature, pictured in this battle for existence, and make more
-contented with their lot “the vigorous, the healthy, and the
-happy.”</p>
-<h3 class='c014'><span class='sc'>The Theory of Natural Selection</span></h3>
-
-<p class='c015'>We have already anticipated, to some extent, Darwin’s
-conclusion in regard to the outcome of the competition of
-animals and plants. This result is supposed to lead to the
-survival of the fittest. The competition is carried out by
-nature, who is personified as selecting those forms for further
-experiments that have won in the struggle for existence.</p>
-
-<p class='c010'>“Can the principle of selection, which we have seen is so
-potent in the hands of man, apply under Nature? I think
-we shall see that it can act most efficiently. Let the endless
-number of slight variations and individual differences occurring
-in our domestic productions, and, in a lesser degree, in
-those under Nature, be borne in mind; as well as the strength
-of the hereditary tendency. Can it, then, be thought improbable,
-<span class='pageno' id='Page_117'>117</span>seeing that variations useful to man have undoubtedly
-occurred, that other variations useful in some way to
-each being in the great and complex battle for life, should
-occur in the course of many successive generations? If such
-do occur can we doubt (remembering how many more individuals
-are born than can possibly survive) that individuals
-having any advantage, however slight, over others, would
-have the best chance of surviving and of procreating their
-kind? On the other hand, we may feel sure that any variation
-in the least degree injurious would be rigidly destroyed.”</p>
-
-<p class='c010'>The process of natural selection is defined as follows,
-“The preservation of favorable individual differences and
-variations and the destruction of those that are injurious I
-have called Natural Selection or the Survival of the Fittest.”
-And immediately there follows the significant statement,
-that, “Variations neither useful nor injurious would not be
-affected by natural selection, and would be left either a
-fluctuating element, as perhaps we see in certain polymorphic
-species, or would ultimately become fixed, owing to the
-nature of the organism and the nature of the conditions.”
-It will be seen from this quotation, as well as from others
-already given, that Darwin leaves many structures outside
-of the pale of natural selection, and uses his theory to explain
-only those cases that are of sufficient use to be decisive
-in the life and death struggle of the individuals with each
-other and with the surrounding conditions.</p>
-
-<p class='c010'>Darwin states that we can best understand “the probable
-course of natural selection by taking the case of a country
-undergoing some slight physical change, for instance, of
-climate. The proportional numbers of its inhabitants will
-almost immediately undergo a change, and some species will
-probably become extinct. We may conclude, from what we
-have seen of the intimate and complex manner in which the
-inhabitants of each country are bound together, that any
-change in the numerical proportions of the inhabitants, independency
-<span class='pageno' id='Page_118'>118</span>of the change of climate itself, would seriously
-affect the others.... In such cases, slight modifications,
-which in any way favored the individuals of any species, by
-better adapting them to their altered conditions, would tend
-to be preserved; and natural selection would have free scope
-for the work of improvement.”</p>
-
-<p class='c010'>The first half of the first of these two quotations seems so
-plausible, that without further thought we may be tempted
-to give a ready assent to the second, yet the whole issue is
-contained in this statement. In the abstract, it undoubtedly
-appears true that any slightly useful modification might tend
-to be preserved. Whether it will, in reality, be preserved
-must depend on many things that should be taken into
-account. This question will come up later for further consideration;
-but it should be pointed out here, that, even
-assuming that one or more individuals happen to possess a
-favorable variation, it by no means follows that natural
-selection would have free scope for the work of improvement,
-because the question of the inheritance of this variation,
-and of its accumulation and building up through successive
-generations, must be determined before we can be expected
-to give assent to this argument, that appears so attractive
-when stated in an abstract and vague way.</p>
-
-<p class='c010'>Darwin again makes the statement that under the term
-<i>variation</i> it must never be forgotten that mere individual
-differences are meant. “As a man can produce a great
-result with his domestic animals and plants by adding up in
-any given direction individual differences, so could natural
-selection, but far more easily from having incomparably
-longer time for action.” Too much emphasis cannot be laid
-on the fact that Darwin believed that selection takes place
-amongst the small individual differences that we find in
-animals and plants. Some of his followers, as we shall see,
-are apt to put into the background this fundamental conception
-of Darwin’s view. His constant comparison between
-<span class='pageno' id='Page_119'>119</span>the results of artificial and natural selection leaves no room
-for doubt as to his meaning. Darwin himself seems, at
-times, not unconscious of the weakness of this comparison.
-He says: “How fleeting are the wishes and efforts of man!
-how short his time! and consequently how poor will be his
-results, compared with those accumulated by Nature during
-whole geological periods. Can we wonder then that Nature’s
-productions should be far ‘truer’ in character than man’s
-productions; that they should be infinitely better adapted to
-the most complex conditions of life, and should plainly bear
-the stamp of far higher workmanship?” We should not
-lose sight of the fact that even after the most rigorous selective
-process has been brought to bear on organisms, namely,
-by isolation under domestication, we do not apparently find
-ourselves gradually approaching nearer and nearer to the
-formation of new species, but we find, on the contrary, that
-we have produced something quite different. In the light of
-this truth, the relation between the two selective theories
-may appear quite different from the interpretation that Darwin
-gives of it. We may well doubt whether nature does
-select so much better than does man, and whether she has
-ever <i>made</i> new species in this way.</p>
-
-<p class='c010'>We come now to a point that touches the theory of natural
-selection in a very vital spot.</p>
-
-<p class='c010'>“It may be well here to remark that with all beings there
-must be much fortuitous destruction, which can have little or
-no influence on the course of natural selection. For instance,
-a vast number of eggs or seeds are annually devoured, and
-these could be modified through natural selection only if they
-varied in some manner which protected them from their
-enemies. Yet many of these eggs or seeds would perhaps, if
-not destroyed, have yielded individuals better adapted to their
-conditions of life than any of those which happened to survive.
-So again a vast number of mature animals and plants,
-whether or not they be the best adapted to their conditions,
-<span class='pageno' id='Page_120'>120</span>must be annually destroyed by accidental causes, which would
-not be in the least degree mitigated by certain changes of
-structure or constitution which would in other ways be beneficial
-to the species. But let the destruction of the adults
-be ever so heavy, if the number which can exist in any district
-be not wholly kept down by such causes,—or again
-let the destruction of eggs or seeds be so great that only a
-hundredth or a thousandth part are developed,—yet of those
-which do survive, the best adapted individuals, supposing
-that there is any variability in a favorable direction, will tend
-to propagate their kind in larger numbers than the less well
-adapted. If the numbers be wholly kept down by the causes
-just indicated, as will often have been the case, natural selection
-will be powerless in certain beneficial directions; but this
-is no valid objection to its efficiency at other times and in other
-ways; for we are far from having any reason to suppose
-that many species ever undergo modification and improvement
-at the same time in the same area.”</p>
-
-<p class='c010'>Some of the admissions made in this paragraph have an
-important bearing on the theory of natural selection. Far
-from supposing that fortuitous destruction would have no
-influence on the course of natural selection, it can be shown
-that it would have a most disastrous effect. In many cases
-the destruction comes in the form of a catastrophe to the
-individuals, so that small differences in structure, whether
-advantageous or not, are utterly unavailing. Our experience
-shows us that a destruction of this sort is going on around
-us all the time, and accounts in large part for the way in
-which the majority of animals and plants are destroyed.
-Unless, for example, a seed happen to fall on a place suitable
-for its growth, it will perish without respect to a slight advantage
-it may have over other seeds of its kind. Of the thousands
-of eggs laid by one starfish, chance alone will decide
-whether one or another embryo is destroyed by larger animals,
-or if they escape this danger, the majority of them may be
-<span class='pageno' id='Page_121'>121</span>carried out to sea, where it will not be of the least avail if
-one individual has a slight advantage over the others. Darwin
-admits this, but adds that, if only a thousandth part is
-developed, yet of those that do survive the best adapted
-individuals will tend to propagate their kind in larger numbers
-than the less well adapted. The argument is not, however,
-so simple as it appears to be on the surface. I pass
-over, for the present, the apparent inconsequence in this
-statement that the best adapted individuals will tend to propagate
-their kind in larger numbers. It is not by any means
-certain that this is the case. Darwin’s meaning is, however,
-fairly clear, and can be interpreted to mean this: after the
-fortuitous destruction has finished, there will be a further
-competition of the survivors amongst themselves and with
-the surrounding conditions. In this higher competition, which
-is less severe, small individual differences suffice to determine
-the survival of certain individuals. These are, therefore,
-selected.</p>
-
-<p class='c010'>In this argument it is assumed that a second competition
-takes place after the first destruction of individuals has occurred,
-and this presupposes that more individuals reach
-maturity than there is room for in the economy of nature.
-But we do not know to what extent this takes place. If only
-as many mature as can survive, then the second competition
-does not take place. If, on the other hand, fewer mature than
-there is room for, then again competition does not take place.
-And if at all times selection is not rigorously carried out,
-everything may be lost that has been so laboriously gained.
-We see then that the result that Darwin imagines would take
-place, can be carried out only when more individuals reach
-maturity than there is room for (if it is a case of competition
-with one another), or that escape their enemies (if it is a
-question of competition with other forms).</p>
-
-<p class='c010'>It is instructive to consider some of the examples that
-Darwin has given to illustrate how the process of natural
-<span class='pageno' id='Page_122'>122</span>selection is carried out. The first example is the imaginary
-case of a species of wolf, the individuals of which secure
-their prey sometimes by craft, sometimes by strength, and
-sometimes by fleetness. If the prey captured by the first
-two methods should fail, then all the wolves would be obliged
-to capture their food by fleetness, and consequently the fleetest
-alone would survive. “I can see no more reason to doubt
-that this would be the result than that man should improve
-the fleetness of his greyhounds.” But even if the fleetness
-of the race could be kept up in this way, it does not follow
-that a new species of wolf would be formed in consequence,
-as Darwin implies. His own comment on this illustration is,
-perhaps, the best criticism that can be made.</p>
-
-<p class='c010'>“It should be observed that, in the above illustration, I
-speak of the slimmest individual wolves, and not of any single
-strongly marked variation having been preserved. In former
-editions of this work I sometimes spoke as if this latter alternative
-had frequently occurred. I saw the great importance
-of individual differences, and this led me fully to discuss the
-results of unconscious selection by man, which depends on
-the preservation of all the more or less valuable individuals,
-and on the destruction of the worst. I saw, also, that the
-preservation in a state of nature of any occasional deviation
-of structure, such as a monstrosity, would be a rare event; and
-that, if at first preserved, it would generally be lost by subsequent
-intercrossing with ordinary individuals. Nevertheless,
-until reading an able and valuable article in the <i>North British
-Review</i> (1867), I did not appreciate how rarely single
-variations, whether slight or strongly marked, could be perpetuated.
-The author takes the case of a pair of animals,
-producing during their lifetime two hundred offspring, of
-which, from various causes of destruction, only two on an
-average survive to procreate their kind. This is rather
-an extreme estimate for most of the higher animals, but by
-no means so for many of the lower organisms. He then
-<span class='pageno' id='Page_123'>123</span>shows that if a single individual were born, which varied in
-some manner, giving it twice as good a chance of life as that
-of the other individuals, yet the chances would be strongly
-against its survival. Supposing it to survive and to breed,
-and that half its young inherited the favourable variation;
-still, as the reviewer goes on to show, the young would have
-only a slightly better chance of surviving and breeding; and
-this chance would go on decreasing in the succeeding generations.
-The justice of these remarks cannot, I think, be disputed.
-If, for instance, a bird of some kind could procure
-its food more easily by having its beak curved, and if one
-were born with its beak strongly curved, and which consequently
-flourished, nevertheless there would be a very poor
-chance of this one individual perpetuating its kind to the exclusion
-of the common form; but there can hardly be a
-doubt, judging by what we see taking place under domestication,
-that this result would follow from the preservation during
-many generations of a large number of individuals with
-more or less strongly curved beaks, and from the destruction
-of a still larger number with the straightest beaks.”</p>
-
-<p class='c010'>There then follows what, I believe, is one of the most significant
-admissions in the “Origin of Species”:—</p>
-
-<p class='c010'>“It should not, however, be overlooked that certain rather
-strongly marked variations, which no one would rank as mere
-individual differences, frequently recur owing to a similar
-organization being similarly acted on—of which fact numerous
-instances could be given with our domestic productions.
-In such cases, if the varying individual did not actually transmit
-to its offspring its newly acquired character, it would
-undoubtedly transmit to them, as long as the existing conditions
-remained the same, a still stronger tendency to vary in
-the same manner. There can also be little doubt that the
-tendency to vary in the same manner has often been so
-strong that all the individuals of the same species have been
-similarly modified without the aid of any form of selection.
-<span class='pageno' id='Page_124'>124</span>Or only a third, fifth, or tenth part of the individuals may
-have been thus affected, of which fact several instances could
-be given. Thus Graba estimates that about one-fifth of the
-guillemots in the Faroe Islands consist of a variety so well
-marked, that it was formerly ranked as a distinct species
-under the name of <i>Uria lacrymans</i>. In cases of this kind, if
-the variation were of a beneficial nature, the original form
-would soon be supplanted by the modified form, through the
-survival of the fittest.”</p>
-
-<p class='c010'>Do not the admissions in this paragraph almost amount to
-a withdrawal of much that has preceded in regard to the
-survival of fluctuating, individual differences? In the last
-edition, from which we have just quoted, Darwin, in response
-to the criticisms which his book met, inserted here and there
-statements that are in many ways in contradiction to the
-statements in the first edition, and yet the earlier statements
-have been allowed to stand for the most part.</p>
-
-<p class='c010'>The next example is also worthy of careful examination,
-since it appears to prove too much:—</p>
-
-<p class='c010'>“It may be worth while to give another and more complex
-illustration of the action of natural selection. Certain plants
-excrete sweet juice, apparently for the sake of eliminating
-something injurious from the sap: this is effected, for instance,
-by glands at the base of the stipules in some Leguminosæ,
-and at the backs of the leaves of the common laurel.
-This juice, though small in quantity, is greedily sought by
-insects; but their visits do not in any way benefit the plant.
-Now, let us suppose that the juice or nectar was excreted
-from the inside of the flowers of a certain number of plants
-of any species. Insects in seeking the nectar would get
-dusted with pollen, and would often transport it from one
-flower to another. The flowers of two distinct individuals of
-the same species would thus get crossed; the act of crossing,
-as can be fully proved, gives rise to vigorous seedlings,
-which consequently would have the best chance of flourishing
-<span class='pageno' id='Page_125'>125</span>and surviving. The plants which produced flowers with
-the largest glands or nectaries, excreting most nectar, would
-oftenest be visited by insects, and would oftenest be crossed;
-and so in the long run would gain the upper hand and form
-a local variety.”</p>
-
-<p class='c010'>The reader will notice that the sweet juice or nectar
-secreted by certain plants is supposed to have first appeared
-independently of the action of natural selection. Why then
-account for its presence in flowers as the outcome of an
-entirely different process? If the nectar is eagerly sought
-for by insects, without the plant benefiting in any way by
-their visitations, why give a different explanation of its origin
-in flowers where it is of benefit to the plant?</p>
-
-<p class='c010'>Darwin carries his illustration further: “When our plant,
-by the above process long continued, had been rendered
-highly attractive to insects, they would unintentionally, on
-their part, regularly carry pollen from flower to flower; and
-that they do this effectually, I could easily show by many
-striking facts. I will give only one, as likewise illustrating one
-step in the separation of the sexes of plants.... As soon
-as the plant had been rendered so highly attractive to insects
-that pollen was regularly carried from flower to flower, another
-process might commence. No naturalist doubts the advantage
-of what has been called the ‘physiological division of
-labour’; hence we may believe that it would be advantageous
-to a plant to produce stamens alone in one flower or on one
-whole plant, and pistils alone in another flower or on another
-plant. In plants under culture and placed under new conditions
-of life, sometimes the male organs and sometimes the
-female organs become more or less impotent; now if we
-suppose this to occur in ever so slight a degree under
-nature, then, as pollen is already carried regularly from
-flower to flower, and as a more complete separation of the
-sexes of our plant would be advantageous on the principle
-of the division of labour, individuals with this tendency
-<span class='pageno' id='Page_126'>126</span>more and more increased would be continually favoured or
-selected, until at last a complete separation of the sexes
-might be effected. It would take up too much space to
-show the various steps, through dimorphism and other
-means, by which the separation of the sexes in plants of
-various kinds is apparently now in progress; but I may add
-that some of the species of holly in North America are,
-according to Asa Gray, in an exactly intermediate condition,
-or, as he expresses it, are more or less diœciously
-polygamous.”</p>
-
-<p class='c010'>From this it will be seen that Darwin supposes that the
-separation of the sexes in some of the higher plants has been
-brought about by natural selection. Despite the supposed
-advantage of the so-called “division of labor,” one may, I
-venture to suggest, be sceptical as to whether the separation
-of the sexes can be explained in this way. The whole case is
-largely supposititious, since in most of the higher hermaphroditic
-plants and in nearly all hermaphroditic animals the
-sexual products ripen at different times in the same individual.
-Hence there is no basis for the assumption that
-unless the sexes are separated there will be self-fertilization.
-Shall we assume that this difference in time of ripening
-of the two kinds of sex-cells is also the outcome of natural
-selection, and that there has existed an earlier stage in all
-animals and plants, that now have different times for the
-ripening of their sexual elements, a time when these products
-ripened simultaneously? I doubt if even a Darwinian would
-give such loose rein to his fancy.</p>
-
-<p class='c010'>But this is not yet the whole story that Darwin has made
-out in this connection, for he continues:—</p>
-
-<p class='c010'>“Let us now turn to the nectar-feeding insects; we may
-suppose the plant, of which we have been slowly increasing
-the nectar by continued selection, to be a common plant; and
-that certain insects depended in main part on its nectar for
-food. I could give many facts showing how anxious bees
-<span class='pageno' id='Page_127'>127</span>are to save time: for instance, their habit of cutting holes
-and sucking the nectar at the bases of certain flowers, which
-with a very little more trouble, they can enter by the mouth.
-Bearing such facts in mind, it may be believed that under
-certain circumstances individual differences in the curvature
-or length of the proboscis, etc., too slight to be appreciated
-by us, might profit a bee or other insect, so that certain individuals
-would be able to obtain their food more quickly than
-others; and thus the communities to which they belonged
-would flourish and throw off many swarms inheriting the
-same peculiarities.”</p>
-
-<p class='c010'>Aside from the general criticism that will suggest itself
-here also, it should be pointed out that even if “certain individuals”
-of the bees had slightly longer proboscides, this
-would, in the case of the hive-bees at least, be of no avail,
-since they do not reproduce, and hence leave no descendants
-with longer mouth-parts. Of course, it may be replied that
-those colonies in which the queens produce more of the long-proboscis
-kind of worker would have an advantage over other
-colonies not having so many individuals of this sort. It
-would then be a competition of one colony with another, as
-Darwin supposes to take place in colonial forms. But whether
-slight differences of this sort would lead to the elimination
-of the least well-endowed colonies is entirely a matter of
-speculation. Since there are flowers with corolla-tubes of
-all lengths, we can readily suppose that if one kind of flower
-excluded individuals of certain colonies, they would search
-elsewhere for their nectar rather than perish. While different
-races might arise in this way, the process would not be
-the survival of the fittest, but a process of adaptation to a new
-environment.</p>
-
-<p class='c010'>We come now to a topic on which Darwin lays much
-stress: the divergence of character. He tries to show how
-the “lesser differences between the varieties become augmented
-into the greater differences between species.”</p>
-
-<p class='c010'><span class='pageno' id='Page_128'>128</span>“Mere chance, as we may call it, might cause one variety
-to differ in some character from its parents, and the offspring
-of this variety again to differ from its parent in the
-very same character and in a greater degree; but this alone
-would never account for so habitual and large a degree of
-difference as that between the species of the same genus.
-As has always been my practice, I have sought light on this
-head from our domestic productions.”</p>
-
-<p class='c010'>Then, after pointing out that under domestication two
-different races, the race-horse and the dray-horse, for instance,
-might arise by selecting different sorts of variations,
-Darwin inquires:—</p>
-
-<p class='c010'>“But how, it may be asked, can any analogous principle
-apply in nature? I believe it can and does apply most
-efficiently (though it was a long time before I saw how), from
-the simple circumstance that the more diversified the descendants
-from any one species become in structure, constitution,
-and habits, by so much will they be better enabled to seize
-on many and widely diversified places in the polity of nature,
-and so be enabled to increase in numbers.”</p>
-
-<p class='c010'>Here we touch on one of the fundamental principles of the
-doctrine of evolution. It is intimated that the new form of
-animal or plant first appears (without regard to any kind of
-selection), and then finds that place in nature where it can
-remain in existence and propagate its kind. Darwin refers
-here, of course, only to the less extensive variations, the individual
-or fluctuating kind; but as we shall discuss at greater
-length in another place, this same process, if extended to
-other kinds of variation, may give us an explanation of evolution
-without competition, or selection, or destruction of the
-individuals of the same kind taking place at all.</p>
-
-<div class='pbb'>
- <hr class='pb c006' />
-</div>
-<div class='chapter'>
-  <span class='pageno' id='Page_129'>129</span>
-  <h2 class='c008'>CHAPTER V<br /> <br /><span class='c013'>THE THEORY OF NATURAL SELECTION (<i>Continued</i>)</span></h2>
-</div>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div><span class='large'><span class='sc'>Objections to the Theory of Natural Selection</span></span></div>
-  </div>
-</div>
-
-<p class='c009'><span class='sc'>Although</span> in the preceding chapter a number of criticisms
-have been made of the special parts of the theory of natural
-selection, there still remain to be considered some further
-objections that have been made since the first publication of
-the theory. It is a fortunate circumstance from every point
-of view that Darwin himself was able in the later editions of
-the “Origin of Species” to reply to those criticisms that he
-thought of sufficient importance. He says:—</p>
-
-<p class='c010'>“Long before the reader has arrived at this part of my
-work, a crowd of difficulties will have occurred to him. Some
-of them are so serious that to this day I can hardly reflect on
-them without being in some degree staggered; but, to the
-best of my judgment, the greater number are only apparent,
-and those that are real are not, I think, fatal to the theory.”</p>
-
-<p class='c010'>The first difficulty is this: “Why, if species have descended
-from other species by fine gradations, do we not everywhere
-see innumerable transitional forms? Why is not all nature
-in confusion, instead of the species being, as we see them,
-well defined?”</p>
-
-<p class='c010'>The answer that Darwin gives is, that by competition the
-new form will crowd out its own less-improved parent form,
-and other less-favored forms. But is this a sufficient or satisfactory
-answer? If we recall what Darwin has said on the
-advantage that those forms will have, in which a great number
-of new variations appear to fit them to the great diversity
-<span class='pageno' id='Page_130'>130</span>of natural conditions, and if we recall the gradations that exist
-in external conditions, I think we shall find that Darwin’s
-reply fails to give a satisfactory answer to the question.</p>
-
-<p class='c010'>It is well known, and Darwin himself has commented on
-it, that the same species often remains constant under very
-diverse external conditions, both inorganic and organic.
-Hence I think the explanation fails, in so far as it is
-based on the accumulation by selection of small individual
-variations that are supposed to give the individuals some
-slight advantage under each set of external conditions.
-Darwin admits that “this difficulty for a long time quite
-confounded me. But I think it can be in large part explained.”
-The first explanation that is offered is that areas
-now continuous may not have been so in the past. This
-may be true in places, but the great continents have had
-continuous areas for a long time, and Darwin frankly acknowledges
-that he “will pass over this way of explaining
-the difficulty.” The second attempt is based on the supposed
-narrowness of the area, where two species, descended
-from a common parent, overlap. In this region the change
-is often very abrupt, and Darwin adds:—</p>
-
-<p class='c010'>“To those who look at climate and the physical conditions
-of life as the all-important elements of distribution, these facts
-ought to cause surprise, as climate and height or depth graduate
-away insensibly. But when we bear in mind that almost
-every species, even in its metropolis, would increase immensely
-in numbers, were it not for other competing species; that nearly
-all either prey on or serve as prey for others; in short, that
-each organic being is either directly or indirectly related in the
-most important manner to other organic beings,—we see that
-the range of the inhabitants of any country by no means exclusively
-depends on insensibly changing physical conditions,
-but in a large part on the presence of other species, on which
-it lives, or by which it is destroyed, or with which it comes
-into competition; and as these species are already defined objects,
-<span class='pageno' id='Page_131'>131</span>not blending one into another by insensible gradations,
-the range of any one species, depending as it does on the
-range of others, will tend to be sharply defined.”</p>
-
-<p class='c010'>Here we have a <i>petitio principii</i>. The sharp definition of
-species, that we started out to account for, is explained by
-the sharp definition of other species!</p>
-
-<p class='c010'>A third part of the explanation is that, owing to the relative
-fewness of individuals at the confines of the range during
-the fluctuations of their enemies, or of their prey, or in
-the nature of the seasons, they would be extremely liable to
-utter extermination. If this were really the case, then new
-species themselves which, on the theory, are at first few in
-numbers ought to be exterminated. On the whole, then, it
-does not appear that Darwin has been very successful in his
-attempt to meet this objection to the theory.</p>
-
-<p class='c010'>Darwin tries to meet the objection, that organs of extreme
-perfection and complication cannot be accounted for by natural
-selection, as follows:—</p>
-
-<p class='c010'>“To suppose that the eye with all its inimitable contrivances
-for adjusting the focus to different distances, for admitting
-different amounts of light, and for the correction of
-spherical and chromatic aberration, could have been formed
-by natural selection, seems, I freely confess, absurd in the
-highest degree.”</p>
-
-<p class='c010'>The following sketch that Darwin gives to show how he
-imagined the vertebrate eye to have been formed is very
-instructive, as illustrating how he supposed that natural selection
-acts:—</p>
-
-<p class='c010'>“If we must compare the eye to an optical instrument, we
-ought in imagination to take a thick layer of transparent
-tissue, with spaces filled with fluid, and with a nerve sensitive
-to light beneath, and then suppose every part of this
-layer to be continually changing slowly in density, so as to
-separate into layers of different densities and thicknesses,
-placed at different distances from each other, and with the
-<span class='pageno' id='Page_132'>132</span>surfaces of each layer slowly changing in form. Further we
-must suppose that there is a power, represented by natural
-selection or the survival of the fittest, always intently watching
-each slight alteration in the transparent layers; and carefully
-preserving each which, under varied circumstances, in
-any way or in any degree, tends to produce a distincter
-image. We must suppose each new state of the instrument
-to be multiplied by the million; each to be preserved
-until a better one is produced, and then the old ones to be
-all destroyed. In living bodies, variation will cause the
-slight alterations, generation will multiply them almost infinitely,
-and natural selection will pick out with unerring skill
-each improvement. Let this process go on for millions of
-years; and during each year on millions of individuals of
-many kinds; and may we not believe that a living optical
-instrument might thus be formed as superior to one of glass,
-as the works of the Creator are to those of man.”</p>
-
-<p class='c010'>We may conclude in Darwin’s own words:—</p>
-
-<p class='c010'>“To arrive, however, at a just conclusion regarding the
-formation of the eye, with all its marvellous yet not absolutely
-perfect characters, it is indispensable that the reason
-should conquer the imagination; but I have felt the difficulty
-far too keenly to be surprised at others hesitating to extend
-the principle of natural selection to so startling a length.”</p>
-
-<p class='c010'>The electric organs, present in several fish, offer a case
-of special difficulty to the selection theory. When well
-developed, as in the Torpedo and in Gymnotus, it is conceivable
-that it may serve as an organ of defence, but in other
-forms the shock is so weak that it is not to be supposed that
-it can have any such function. Romanes, who in many ways
-was one of the stanchest followers of Darwin, admits that, so
-far as he can see, the evolution of the electric organs cannot
-be explained by the selection theory. Darwin offers no
-explanation, but bases his defence on the grounds that we do
-not know of what use this organ can be to the animal.</p>
-
-<p class='c010'><span class='pageno' id='Page_133'>133</span>Darwin also refers to the phosphorescent, or luminous,
-organs as a supposed case of difficulty for his theory.</p>
-
-<p class='c010'>“The luminous organs which occur in a few insects, belonging
-to widely different families, and which are situated in
-different parts of the body, offer, under our present state of
-ignorance, a difficulty almost exactly parallel with that of the
-electric organs.”</p>
-
-<p class='c010'>In this case also, as in that of the electric organs, the
-structures appear in entirely different parts of the body of
-the insect in different species, so that their occurrence in this
-group cannot be accounted for on a common descent. In
-whatever way they have arisen, they must have evolved independently
-in different species. Darwin advances no explanation
-of the origin of the luminous organs, but states
-that they “offer under our present state of ignorance a difficulty
-almost exactly parallel with that of the electric organs.”
-It will be noticed that the difficulty referred to rests on the
-assumption that since the organs are well developed they
-must have some important use!</p>
-
-<p class='c010'>We may next consider “organs of little apparent importance
-as affected by natural selection.” Darwin says:—</p>
-
-<p class='c010'>“As natural selection acts by life and death,—by the survival
-of the fittest, and by the destruction of the less well-fitted
-individuals,—I have sometimes felt great difficulty in
-understanding the origin or formation of parts of little importance;
-almost as great, though of a very different kind, as in
-the case of the most perfect and complex organs.”</p>
-
-<p class='c010'>His answers to this difficulty are: (1) we are too ignorant
-“in regard to the whole economy of any one organic being to
-say what slight modifications would be of importance or not,”—thus
-such apparently trifling characters as the down on fruit,
-or the colors of the skin and hair of quadrupeds, which from
-being correlated with constitutional differences or from determining
-the attacks of insects might be acted on by natural
-selection; (2) organs now of trifling importance have in
-<span class='pageno' id='Page_134'>134</span>some cases been of high importance to an early progenitor;
-(3) the changed conditions of life may account for some of
-the useless organs; (4) reversion accounts for others; (5) the
-complex laws of growth account for still others, such as
-correlation, compensation of the pressure of one part on
-another, etc.; (6) the action of sexual selection is responsible
-for many characters not to be explained by natural selection.
-Admitting that there may be cases that can be accounted for
-on one or the other of these six possibilities, yet there can be
-no doubt that there are still a considerable number of specific
-characters that cannot be explained in any of these ways.
-I do not think that Darwin has by any means met this
-objection, even if all these six possibilities be admitted as
-generally valid.</p>
-
-<p class='c010'>Amongst the “miscellaneous objections” to his theory that
-Darwin considers we may select the most important cases.
-The following paragraph has been sometimes quoted by later
-writers to show that Darwin saw, to a certain extent, the
-insufficiency of fluctuating variations as a basis for selection.
-What he calls here “spontaneous variability” refers to sudden
-and extensive variations, or what we may call discontinuous
-variations. “In the earlier editions of this work I underrated,
-as it now seems probable, the frequency and importance
-of modifications due to spontaneous variability. But it is
-impossible to attribute to this cause the innumerable structures
-which are so well adapted to the habits of life of each
-species. I can no more believe in this, that the well-adapted
-form of a race-horse or greyhound, which before the principle
-of selection by man was well understood, excited so much
-surprise in the minds of the older naturalists, can thus be
-explained.”</p>
-
-<p class='c010'>Darwin appears to mean by the latter part of this statement,
-that he cannot believe that such sudden and great
-variations as have caused a peach tree to produce nectarines
-can account for the wonderful adaptations of organisms; but
-<span class='pageno' id='Page_135'>135</span>it is not really necessary to suppose that this would often
-occur, for the same result could be reached by several stages,
-even if the discontinuous variations had been small, and had
-appeared in many individuals simultaneously. After showing
-that in a number of flowers, especially of the Compositæ and
-Umbelliferæ, the individual flowers in the closely crowded
-heads are sometimes formed on a different type, Darwin concludes:
-“In these several cases, with the exception of that of
-the well-developed ray-florets, which are of service in making
-the flowers conspicuous to insects, natural selection cannot,
-as far as we can judge, have come into play, or only in a
-quite subordinate manner. All these modifications follow
-from the relative position and interaction of the parts; and
-it can hardly be doubted that if all the flowers and leaves on
-the same plant had been subjected to the same external and
-internal condition, as are the flowers and leaves in certain
-positions, all would have been modified in the same manner.”</p>
-
-<p class='c010'>Further on we meet with the following remarkable statement:
-“But when, from the nature of the organism and of
-the conditions, modifications have been induced which are
-unimportant for the welfare of the species, they may be, and
-apparently often have been, transmitted in nearly the same
-state to numerous, otherwise modified, descendants. It cannot
-have been of much importance to the greater number of
-mammals, birds, or reptiles, whether they were clothed with
-hair, feathers, or scales; yet hair has been transmitted to
-almost all mammals, feathers to all birds, and scales to all
-true reptiles. A structure, whatever it may be, which is
-common to many allied forms, is ranked by us as of high
-systematic importance, and consequently is often assumed to
-be of high vital importance to the species. Thus, as I am
-inclined to believe, morphological differences, which we consider
-as important,—such as the arrangement of the leaves,
-the divisions of the flower or of the ovarium, the position of
-the ovules, etc.,—first appeared in many cases as fluctuating
-<span class='pageno' id='Page_136'>136</span>variations, which sooner or later became constant through the
-nature of the organism and of the surrounding conditions, as
-well as through the intercrossing of distinct individuals, but
-not through natural selection; for as these morphological
-characters do not affect the welfare of the species, any slight
-deviations in them could not have been governed or accumulated
-through this latter agency. It is a strange result which
-we thus arrive at, namely, that characters of slight vital importance
-to the species are the most important to the systematist;
-but, as we shall hereafter see when we treat of the
-genetic principle of classification, this is by no means so paradoxical
-as it may at first appear.”</p>
-
-<p class='c010'>If all this be granted, it is once more evident that the only
-variations that come under the action of selection are the
-limited number that are of vital importance to the organism.
-How little the theory of natural selection can be used to
-explain the origin of species will be apparent from the above
-quotation. This is, of course, not an argument against the
-theory itself, which would still be one of vast importance if it
-explained adaptive characters alone; but enough has been
-said, I think, to show that it is improbable that the origin of
-adaptive and non-adaptive characters are to be explained by
-entirely different principles.</p>
-
-<p class='c010'>In reply to a criticism of Mivart, Darwin makes the
-further admission as to the insufficiency of the theory of
-natural selection: “When discussing special cases, Mr.
-Mivart passes over the effects of the increased use and
-disuse of parts, which I have always maintained to be highly
-important, and have treated in my ‘Variation under Domestication’
-at greater length than, as I believe, any other
-writer. He likewise often assumes that I attribute nothing
-to variation, independent of natural selection, whereas in the
-work just referred to I have collected a greater number of
-well-established cases than is to be found in any other work
-known to me.” If this is admitted, and if it can be shown
-<span class='pageno' id='Page_137'>137</span>that the evidence in favor of the inheritance of acquired
-characters is very doubtful at best, may we not conclude
-that Mivart’s criticisms have sometimes hit the mark?</p>
-
-<p class='c010'>The following objection appears to be a veritable stumbling-block
-to the theory. Flatfishes and soles lie on one
-side, and do not stand in a vertical position as do other fish.
-Some species lie on one side and some on the other, and
-some species contain both right-sided and left-sided individuals.
-In connection with this unusual habit we find a
-striking change in the structure. The eye that would be on
-the under side has shifted, so that it has come to lie on the
-upper side of the head, <i>i.e.</i> both eyes lie on the same side,—a
-condition found in no other vertebrate. As a result of the
-shifting of the eye, the bones of the skull have also become
-profoundly modified. The young fish that emerge from the
-egg swim at first upright, as do ordinary fish, and only after
-they have led a free existence for some time do they turn
-to one side and sink to the bottom. Unless the under eye
-moved to the upper side it would be of no use to the flatfish,
-and might even be a source of injury. Mivart points out
-that a sudden, spontaneous transformation in the position of
-eye is hardly conceivable, and to this Darwin, of course,
-assents. Mivart adds: “If the transit was gradual, then
-how such transit of one eye a minute fraction of the journey
-towards the other side of the head could benefit the individual
-is, indeed, far from clear. It seems even that such an
-incipient transformation must rather have been injurious.”
-Darwin’s reply is characteristic:—</p>
-
-<p class='c010'>“We thus see that the first stages of the transit of the
-eye from one side of the head to the other, which Mr. Mivart
-considers would be injurious, may be attributed to the habit,
-no doubt beneficial to the individual and to the species, of
-endeavoring to look upwards with both eyes, whilst resting
-on one side at the bottom. We may also attribute to the
-inherited effects of use the fact of the mouth in several kinds
-<span class='pageno' id='Page_138'>138</span>of flatfish being bent towards the lower surface, with the jaw-bones
-stronger and more effective on this, the eyeless side of
-the head, than on the other side, for the sake, as Dr. Traquair
-supposes, of feeding with ease on the ground. Disuse, on
-the other hand, will account for the less developed condition
-of the whole inferior half of the body, including the lateral
-fins; though Yarrell thinks that the reduced size of these fins
-is advantageous to the fish, as ‘there is so much less room
-for their action, than with the larger fins above.’ Perhaps
-the lesser number of teeth in the proportion of four to seven
-in the upper halves of the two jaws of the plaice, to twenty-five
-to thirty in the lower halves, may likewise be accounted
-for by disuse. From the colorless state of the ventral surface
-of most fishes and of many other animals, we may
-reasonably suppose that the absence of color in flatfish on
-the side, whether it be the right or left, which is undermost,
-is due to the exclusion of light.”</p>
-
-<p class='c010'>By falling back on the theory of inheritance of acquired
-characters Darwin tacitly admits the incompetence of natural
-selection to explain the evolution of the flatfish. If the latter
-theory prove incorrect, it must then be admitted that the evolution
-of the flatfishes cannot be accounted for by either of
-the two main theories on which Darwin relies.</p>
-
-<p class='c010'>Mivart further points out that the beginning stages of the
-mammary glands cannot be explained by Darwin’s theory. To
-which Darwin replies, that an American naturalist, Mr. Lockwood,
-believes from what he has seen of the development of
-the young of the pipe-fish (Hippocampus) that “they are nourished
-by a secretion from the cutaneous glands of the sac” in
-which the young are enclosed. This can scarcely be said to be
-a satisfactory reply; for, if it is true that this is the case for
-the pipe-fish,—and I cannot find on inquiry that this statement
-has been confirmed,—it is still rather speculative to
-suppose that the ancestral mammals nourished their young by
-secreting a fluid into the marsupial sac around the embryos.</p>
-
-<p class='c010'><span class='pageno' id='Page_139'>139</span>Darwin deals with instincts of animals in the same way as he
-deals with their structures. After pointing out that instincts
-are variable, and that the variations are hereditary, he proceeds
-to show how selection may act by picking out those
-individuals possessing the more favorable instincts. In other
-words, the theory of natural selection is applied to functions,
-as well as to structure. Darwin makes use here also of the
-Lamarckian factor of inheritance, and concludes that “in
-most cases habit and selection have probably both occurred.”</p>
-
-<p class='c010'>A few examples will sufficiently serve to illustrate Darwin’s
-meaning. The first case given is that of the cuckoo, which
-lays its eggs in the nests of other birds, where they are
-hatched and the young reared by their foster-parents. The
-starting-point for such a perversion of the ordinary habits of
-birds is to be found, he thinks, in the occasional deposition
-of eggs in the nests of other birds, which has at times
-been observed for a number of species. For instance, this
-has been seen in the American cuckoo, which ordinarily builds
-a nest of its own. It is recorded and believed to be true
-that the young English cuckoo, when only two or three days
-old, ejects from the nest the offspring of its foster-parents,
-and this “strange and odious instinct” is supposed by Darwin
-to have been acquired in order that the young cuckoo might get
-more food, and that the young bird has acquired during successive
-generations the strength and structure necessary for the
-work of ejection. This is of course largely speculative, and
-it is by no means obvious that it was a greater benefit to the
-cuckoo to have other birds rear its young than to do so itself.
-We can equally well imagine, since this is the turn the argument
-takes, that the occasional instinct to deposit eggs in the
-nests of other birds would be disadvantageous, and could not
-have been acquired by the selection of a fluctuating instinct
-of this sort. We have no right to assume, that because a
-new habit has been acquired, that it is a more advantageous
-one than the one that has been lost. All that we can legitimately
-<span class='pageno' id='Page_140'>140</span>infer is, that, although the normal instinct has been
-changed into another, the race has still been able to remain
-in existence. The same conclusion applies to the case of
-<i>Molothrus bonariensis</i>, cited by Darwin, and is here even more
-obvious:—</p>
-
-<p class='c010'>“Some species of Molothrus, a widely distinct genus of
-American birds, allied to our starlings, have parasitic habits
-like those of the cuckoo; and the species present an interesting
-gradation in the perfection of their instincts. The sexes
-of <i>Molothrus badius</i> are stated by an excellent observer, Mr.
-Hudson, sometimes to live promiscuously together in flocks,
-and sometimes to pair. They either build a nest of their own,
-or seize on one belonging to some other bird, occasionally
-throwing out the nestlings of the stranger. They either lay
-their eggs in the nest thus appropriated, or oddly enough
-build one for themselves on the top of it. They usually sit
-on their own eggs and rear their own young; but Mr. Hudson
-says it is probable that they are occasionally parasitic, for he
-has seen the young of this species following old birds of a
-distinct kind and clamoring to be fed by them. The parasitic
-habits of another species of Molothrus, the <i>M. bonariensis</i>,
-are much more highly developed than those of the last, but
-are still far from perfect. This bird, as far as is known,
-invariably lays its eggs in the nest of strangers; but it is
-remarkable that several together sometimes commence to
-build an irregular untidy nest of their own, placed in singularly
-ill-adapted situations, as on the leaves of a large thistle.
-They never, however, as far as Mr. Hudson has ascertained,
-complete a nest for themselves. They often lay so many eggs—from
-fifteen to twenty—in the same foster-nest, that few
-or none can possibly be hatched. They have, moreover, the
-extraordinary habit of pecking holes in the eggs, whether of
-their own species or of their foster-parents, which they find
-in the appropriated nests. They drop also many eggs on the
-bare ground, which are thus wasted.”</p>
-
-<p class='c010'><span class='pageno' id='Page_141'>141</span>Can we possibly be expected to believe that it has been to
-the advantage of this species to give up its original regular
-method of incubating its own eggs, and acquire such a
-haphazard, new method? Does not the explanation prove
-too much, rather than give support to Darwin’s hypothesis?
-Is it not better to conclude, that despite the disadvantages
-entailed by a change in the original instincts, the species
-is still able to remain in existence?</p>
-
-<p class='c010'>Darwin points out, in the case of the slave-making ants,
-that the slave-making instinct may have arisen in the first
-instance by ants carrying pupæ, that they have captured,
-into their own nests. Later this habit might become fixed,
-and, finally, after passing through several stages of development,
-the ants might become absolutely dependent on their
-slaves. It is also supposed that those colonies in which this
-instinct was better developed would survive in competition
-with other colonies of the same species on account of the
-supposed advantage of owning slaves. In this way natural
-selection steps in and perfects the process.</p>
-
-<p class='c010'>It is far from proven, or even made probable, that a species
-of ant that becomes gradually dependent on its slaves is
-more likely to survive than other colonies that are not
-so dependent. All we can be certain of is that with slaves
-they have still been able to maintain their own. Moreover,
-we must not forget that it is not enough to show that a
-particular habit might be useful to a species, but it should
-also be shown that it is of sufficient importance, at every
-stage of its evolution, to give a decisive advantage in the
-“struggle for existence.” For unless a life and death
-struggle takes place between the different colonies, natural
-selection is powerless to bring about its supposed results.
-And who will be bold enough to affirm that the presence of
-slaves in a nest will give victory to that colony in competition
-with its neighbors? Has the history of mankind taught
-us that the slave-making countries have exterminated the
-<span class='pageno' id='Page_142'>142</span>countries without slaves? Is the question so simple as this?
-May not the degeneration of the masters more than compensate
-for the acquirement of slaves, and may not the loss
-of life in obtaining slaves more than counterbalance the advantage
-of the slaves after they are captured? In the face
-of these possibilities it is not surprising to find that Darwin,
-when summing up the chapter, makes the following admission:
-“I do not pretend that the facts in this chapter
-strengthen in any degree my theory; but none of the cases
-of difficulty, to the best of my judgment, annihilate it.”
-Darwin, with his usual frankness, adds:—</p>
-
-<p class='c010'>“No doubt many instincts of very difficult explanation
-could be opposed to the theory of natural selection,—cases,
-in which we cannot see how an instinct could have originated;
-cases, in which no intermediate gradations are known to
-exist; cases of instincts of such trifling importance, that they
-could hardly have been acted on by natural selection; cases
-of instincts almost identically the same in animals so remote
-in the scale of nature, that we cannot account for their
-similarity by inheritance from a common progenitor, and
-consequently must believe that they were independently
-acquired through natural selection. I will not here enter on
-these several cases, but will confine myself to one special
-difficulty, which at first appeared to me insuperable, and
-actually fatal to the whole theory. I allude to the neuters or
-sterile females in insect communities; for these neuters often
-differ widely in instinct and in structure from both the males
-and fertile females, and yet, from being sterile, they cannot
-propagate their kind.</p>
-
-<p class='c010'>“The subject well deserves to be discussed at great length,
-but I will here take only a single case, that of working or
-sterile ants. How the workers have been rendered sterile is
-a difficulty; but not much greater than that of any other
-striking modification of structure; for it can be shown that
-some insects and other articulate animals in a state of nature
-<span class='pageno' id='Page_143'>143</span>occasionally become sterile; and if such insects had been
-social, and it had been profitable to the community that a
-number should have been annually born capable of work, but
-incapable of procreation, I can see no especial difficulty
-in this having been effected through natural selection. But
-I must pass over this preliminary difficulty. The great
-difficulty lies in the working ants differing widely from both
-the males and the fertile females in structure, as in the
-shape of the thorax, and in being destitute of wings and
-sometimes of eyes, and in instinct. As far as instinct alone
-is concerned, the wonderful difference in this respect between
-the workers and the perfect females, would have been better
-exemplified by the hive-bee. If a working ant or other neuter
-insect had been an ordinary animal, I should have unhesitatingly
-assumed that all its characters had been slowly acquired
-through natural selection; namely, by individuals
-having been born with slight profitable modifications, which
-were inherited by the offspring; and that these again varied
-and again were selected, and so onwards. But with the
-working ant we have an insect differing greatly from its
-parents, yet absolutely sterile; so that it could never have
-transmitted successively acquired modifications of structure
-or instinct to its progeny. It may well be asked, how is
-it possible to reconcile this case with the theory of natural
-selection?”</p>
-
-<p class='c010'>Darwin’s answer is that the differences of structure are
-correlated with certain ages and with the two sexes, but this
-is obviously only shifting the difficulty, not meeting it. He
-concludes, “I can see no great difficulty in any character
-becoming correlated with the sterile condition of certain
-members of the insect communities, the difficulty lies in
-understanding how such correlated modifications of structure
-could have been slowly accumulated by natural selection.”
-“This difficulty, though appearing insuperable, is lessened, or,
-as I believe, disappears, when it is remembered that selection
-<span class='pageno' id='Page_144'>144</span>may be applied to the family, as well as to the individual,
-and may thus give the desired end.”</p>
-
-<p class='c010'>Darwin did not fail to see that there is a further difficulty
-even greater than the one just mentioned. He says: “But
-we have not as yet touched on the acme of the difficulty;
-namely, the fact that the neuters of several ants differ, not
-only from the fertile females and males, but from each other,
-sometimes to an almost incredible degree, and are thus divided
-into two or even three castes. The castes, moreover,
-do not commonly graduate into each other, but are perfectly
-well defined; being as distinct from each other as are any
-two species of the same genus, or rather as any two genera
-of the same family. Thus in Eciton, there are working and
-soldier neuters, with jaws and instincts extraordinarily different:
-in Cryptocerus, the workers of one caste alone carry
-a wonderful sort of shield on their heads, the use of which
-is quite unknown: in the Mexican Myrmecocystus, the
-workers of one caste never leave the nest; they are fed by
-the workers of another caste, and they have an enormously
-developed abdomen which secretes a sort of honey, supplying
-the place of that excreted by the aphides, or the domestic
-cattle as they may be called, which our European ants
-guard and imprison.”</p>
-
-<p class='c010'>“It will indeed be thought that I have an overweening confidence
-in the principle of natural selection, when I do not
-admit that such wonderful and well-established facts at once
-annihilate the theory. In the simpler case of neuter insects
-all of one caste, which, as I believe, have been rendered
-different from the fertile males and females through natural
-selection, we may conclude from the analogy of ordinary
-variations, that the successive, slight, profitable modifications
-did not first arise in all the neuters in the same nest, but in
-some few alone; and that by the survival of the communities
-with females which produced most neuters having the advantageous
-modification, all the neuters ultimately came to be
-<span class='pageno' id='Page_145'>145</span>thus characterized. According to this view we ought occasionally
-to find in the same nest neuter insects, presenting
-gradations of structure; and this we do find, even not rarely,
-considering how few neuter insects out of Europe have been
-carefully examined.”</p>
-
-<p class='c010'>From this the conclusion is reached:—</p>
-
-<p class='c010'>“With these facts before me, I believe that natural selection,
-by acting on the fertile ants or parents, could form a
-species which should regularly produce neuters, all of large
-size with one form of jaw, or all of small size with widely different
-jaws; or lastly, and this is the greatest difficulty, one
-set of workers of one size and structure, and simultaneously
-another set of workers of a different size and structure;— a
-graduated series having first been formed, as in the case of
-the driver ant, and then the extreme forms having been produced
-in greater and greater numbers, through the survival
-of the parents which generated them, until none with an
-intermediate structure were produced.</p>
-
-<p class='c010'>“I have now explained how, as I believe, the wonderful
-fact of two distinctly defined castes of sterile workers existing
-in the same nest, both widely different from each other
-and from their parents, has originated. We can see how
-useful their production may have been to a social community
-of ants, on the same principle that the division of labor is
-useful to civilized man. Ants, however, work by inherited
-instincts and by inherited organs or tools, whilst man works
-by acquired knowledge and manufactured instruments. But
-I must confess, that, with all my faith in natural selection, I
-should never have anticipated that this principle could have
-been efficient in so high a degree, had not the case of these
-neuter insects led me to this conclusion. I have, therefore,
-discussed this case, at some little but wholly insufficient
-length, in order to show the power of natural selection, and
-likewise because this is by far the most serious special difficulty
-which my theory has encountered. The case, also, is
-<span class='pageno' id='Page_146'>146</span>very interesting, as it proves that with animals, as with
-plants, any amount of modification may be effected by the
-accumulation of numerous, slight, spontaneous variations,
-which are in any way profitable, without exercise or habit
-having been brought into play. For peculiar habits confined
-to the workers or sterile females, however long they might
-be followed, could not possibly affect the males and fertile
-females, which alone leave descendants. I am surprised
-that no one has hitherto advanced this demonstrative case
-of neuter insects, against the well-known doctrine of inherited
-habit, as advanced by Lamarck.”</p>
-
-<p class='c010'>We may dissent at once from Darwin’s statement which,
-he thinks, “proves that any amount of modification may be
-affected by the accumulation of numerous slight variations
-which are in any way profitable without exercise or habit
-having been brought into play”; we may dissent if for no
-other reason than that this begs the whole point at issue, and
-is not proven. It does not follow because in some colonies
-all intermediate stages of neuters exist, that in other colonies,
-where no such intermediate stages are present, these
-have been slowly weeded out by natural selection, causing
-to disappear all colonies slightly below the mark. It is this
-that begs the question. Because we can imagine that
-intermediate stages between the different castes may have
-been present, it neither follows that such fluctuating variations
-have been the basis for the evolution of the more
-sharply defined types, nor that the imagined advantage of
-such a change would have led through competition to the
-extermination of the other colonies. However much we
-may admire the skill with which Darwin tried to meet this
-difficulty, let us not put down the results to the good of the
-theory, but rather repeat once more Darwin’s own words at
-the end of this chapter, to the effect that the facts do not
-strengthen the theory.</p>
-<div>
-  <span class='pageno' id='Page_147'>147</span>
-  <h3 class='c014'><span class='sc'>Sterility between Species</span></h3>
-</div>
-
-<p class='c015'>The care with which Darwin examined every bearing of
-his theory is nowhere better exemplified than in his treatment
-of the question of sterility between the individuals of
-different species. It would be so obviously to the advantage
-of the selection theory if it were true that sterility between
-species had been acquired by selection in order to prevent
-intercrossing, that it would have been easy for a less cautious
-thinker to have fallen into the error of supposing that sterility
-might have been acquired in this way. Tempting as such a
-view appears, Darwin was not caught by the specious argument,
-as the opening sentence in the chapter of hybridism
-shows:—</p>
-
-<p class='c010'>“The view commonly entertained by naturalists is that
-species, when intercrossed, have been specially endowed with
-sterility, in order to prevent their confusion. This view
-certainly seems at first highly probable, for species living
-together could hardly have been kept distinct had they been
-capable of freely crossing. The subject is in many ways
-important for us, more especially as the sterility of species
-when first crossed, and that of their hybrid offspring, cannot
-have been acquired, as I shall show, by the preservation of
-successive profitable degrees of sterility. It is an incidental
-result of differences in the reproductive systems of the
-parent species.”</p>
-
-<p class='c010'>In dealing with this subject Darwin points out that we must
-be careful to distinguish between “the sterility of species
-when first crossed, and the sterility of hybrids produced from
-them.” In the former case, the reproductive organs of each
-individual are in a perfectly normal condition, while hybrids
-appear to be generally impotent owing to some imperfection
-in the reproductive organs themselves. They are not perfectly
-fertile, as a rule, either with each other, or with either of the
-parent forms.</p>
-
-<p class='c010'><span class='pageno' id='Page_148'>148</span>In striking contrast to the sterility between species is the
-fertility of varieties. If, as Darwin believes, varieties are
-incipient species, we should certainly expect to find them
-becoming less and less fertile with other fraternal varieties, or
-with the parent forms in proportion as they become more
-different. Yet experience appears to teach exactly the opposite;
-but the question is not a simple one, and the results
-are not so conclusive as appears at first sight. Let us first
-see how Darwin met this obvious contradiction to his view.</p>
-
-<p class='c010'>In the first place, he points out that all species are not infertile
-when crossed with other species. The sterility of
-various species, when crossed, is so different in degree, and
-graduates away so insensibly, and the fertility of pure species
-is so easily affected by various circumstances, that it is most
-difficult to say where perfect fertility ends and sterility begins.
-“It can thus be shown that neither sterility nor fertility
-afford any certain distinction between species and
-varieties.” Darwin cites several cases in plants in which
-crosses between species have been successfully accomplished.
-The following remarkable results are also recorded: “Individual
-plants in certain species of Lobelia, Verbascum, and
-Passiflora can easily be fertilized by pollen from a distinct
-species, but not by pollen from the same plant, though this
-pollen can be proved to be perfectly sound by fertilizing
-other plants or species. In the genus Hippeastrum, in Corydalis
-as shown by Professor Hildebrand, in various orchids
-as shown by Mr. Scott and Fritz Müller, all the individuals
-are in this peculiar condition. So that with some species,
-certain abnormal individuals, and in other species all the
-individuals, can actually be hybridized much more readily
-than they can be fertilized by pollen from the same individual
-plant!”<a id='r14' /><a href='#f14' class='c017'><sup>[14]</sup></a></p>
-
-<div class='footnote c018' id='f14'>
-<p class='c019'><span class='label'><a href='#r14'>14</a>.&nbsp;&nbsp;</span>A somewhat parallel case has recently been discovered by Castle for the hermaphroditic
-ascidian <i>Ciona intestinalis</i>. In this case the spermatozoa of any
-individual fail to fertilize the eggs of the same individual, although they will fertilize
-the eggs of any other individual.</p>
-</div>
-
-<p class='c010'><span class='pageno' id='Page_149'>149</span>In regard to animals, Darwin concludes that “if the genera
-of animals are as distinct from each other as are the genera
-of plants, then we may infer that animals more widely distinct
-in the scale of nature can be crossed more easily than in the
-case of plants; but the hybrids themselves are, I think, more
-sterile.”</p>
-
-<p class='c010'>The most significant fact in this connection is that the
-more widely different two species are, so that they are placed
-in different families, so much the less probable is it that
-cross-fertilization will produce any result. From this condition
-of infertility there may be traced a gradation between
-less different forms of the same genus to almost complete,
-or even complete, fertility between closely similar species.
-Darwin further points out that: “The hybrids raised from
-two species which are very difficult to cross, and which rarely
-produce any offspring, are generally very sterile; but the
-parallelism between the difficulty of making a first cross, and
-the sterility of the hybrids thus produced—two classes of
-facts which are generally confounded together—is by no
-means strict. There are many cases, in which two pure
-species, as in the genus Verbascum, can be united with
-unusual facility, and produce numerous hybrid offspring,
-yet these hybrids are remarkably sterile. On the other
-hand, there are species which can be crossed very rarely,
-or with extreme difficulty, but the hybrids, when at last
-produced, are very fertile. Even within the limits of the
-same genus, for instance in Dianthus, these two opposite
-cases occur.”</p>
-
-<p class='c010'>In regard to reciprocal crosses Darwin makes the following
-important statements: “The diversity of the result in reciprocal
-crosses between the same two species was long ago
-observed by Kölreuter. To give an instance: <i>Mirabilis
-jalapa</i> can easily be fertilized by the pollen of <i>M. longiflora</i>,
-and the hybrids thus produced are sufficiently fertile; but
-Kölreuter tried more than two hundred times, during eight
-<span class='pageno' id='Page_150'>150</span>following years, to fertilize reciprocally <i>M. longiflora</i> with the
-pollen of <i>M. jalapa</i>, and utterly failed.”</p>
-
-<p class='c010'>A formal interpretation of this difference can be easily
-imagined. The infertility in one direction may be due to
-some physical difficulty met with in penetrating the stigma,
-or style. For instance, the tissue in one species may be too
-compact, or the style too long. Pflüger, who carried out a
-large number of experiments by cross-fertilizing different
-species of frogs, reached the conclusion that the spermatozoa
-having small and pointed heads could cross-fertilize more
-kinds of eggs, than could the spermatozoa with large blunt
-heads. This is probably due to the ability of the smaller
-spermatozoa to penetrate the jelly around the eggs, or the
-pores in the surface of the egg itself. But there are also
-other sides to this question, as recent results have shown, for,
-even if a foreign spermatozoon can enter an egg, it does not
-follow that the development of the egg will take place.
-Here the difficulty is due to some obscure processes in the
-egg itself. Now that we know more of the nicely balanced
-combinations that take place during fertilization of the egg,
-and during the process of cell division, we can easily see that
-if the processes were in the least different in the two species
-it might be impossible to combine them in a single act.</p>
-
-<p class='c010'>“Now do these complex and singular rules indicate that
-species have been endowed with sterility simply to prevent
-their becoming confounded in nature? I think not. For
-why should the sterility be so extremely different in degree,
-when various species are crossed, all of which we must suppose
-it would be equally important to keep from blending
-together?”</p>
-
-<p class='c010'>“The foregoing rules and facts, on the other hand, appear
-to me clearly to indicate that the sterility both of first crosses
-and of hybrids is simply incidental or dependent on unknown
-differences in their reproductive systems; the differences
-being of so peculiar and limited a nature, that, in reciprocal
-<span class='pageno' id='Page_151'>151</span>crosses between the same two species, the male sexual element
-of the one will often freely act on the female sexual
-element of the other, but not in a reversed direction.”</p>
-
-<p class='c010'>Does Darwin give here a satisfactory answer to the difficulty
-that he started out to explain away? On the whole,
-the reader will admit, I think, that he has fairly met the situation,
-in so far as he has shown that there is no absolute
-line of demarcation between the power of intercrossing of
-varieties and races, and of species. It is also <i>extremely important
-to have found that the difficulties increase, so to speak,
-even beyond the limits of the species</i>; since species, belonging
-to different genera, are as a rule more difficult to intercross
-than when they belong to the same genus. The further
-question, as to whether there are differences in respect to the
-power of intercrossing between different kinds of varieties,
-such as those dependent on selection of fluctuating variations,
-of local conditions, of mutations, etc., is far from being
-settled at the present time.</p>
-
-<p class='c010'>That this property of species is useful to them, in the somewhat
-unusual sense that it keeps them from freely mingling
-with other species, is true; but, as has been said, this would be
-a rather peculiar kind of adaptation. If, however, it be
-claimed that this property is useful to species, as Darwin
-himself claims, then, as he also points out, it is a useful
-acquirement that cannot have arisen through natural selection.
-It is not difficult to show why this must be so. If two
-varieties were to some extent at the start less fertile, <i>inter se</i>,
-than with their own kind, the only way in which they could
-become more infertile through selection would be by selecting
-those individuals in each generation that are still more infertile,
-but the forms of this sort would, <i>ex hypothese</i>, become
-less numerous than the descendants of each species itself,
-which would, therefore, supplant the less fertile ones.</p>
-
-<p class='c010'>Darwin’s own statement in regard to this point is as follows:—</p>
-
-<p class='c010'><span class='pageno' id='Page_152'>152</span>“At one time it appeared to me probable, as it has to
-others, that the sterility of first crosses and of hybrids might
-have been slowly acquired through the natural selection of
-slightly lessened degrees of fertility, which, like any other
-variation, spontaneously appeared in certain individuals of
-one variety when crossed with those of another variety.
-For it would clearly be advantageous to two varieties or incipient
-species, if they could be kept from blending, on
-the same principle that, when man is selecting at the same
-time two varieties, it is necessary that he should keep them
-separate.</p>
-
-<p class='c010'>“In considering the probability of natural selection having
-come into action, in rendering species mutually sterile, the
-greatest difficulty will be found to lie in the existence of
-many graduated steps from slightly lessened fertility to absolute
-sterility. It may be admitted that it would profit an
-incipient species, if it were rendered in some slight degree
-sterile when crossed with its parent form or with some other
-variety; for thus fewer bastardized and deteriorated offspring
-would be produced to commingle their blood with the new
-species in process of formation. But he who will take the
-trouble to reflect on the steps by which this first degree of
-sterility could be increased through natural selection to that
-high degree which is common with so many species, and
-which is universal with species which have been differentiated
-to a generic or family rank, will find the subject extraordinarily
-complex. After mature reflection it seems to me that
-this could not have been effected through natural selection.
-Take the case of any two species which, when crossed, produced
-few and sterile offspring; now, what is there which
-could favor the survival of those individuals which happened
-to be endowed in a slightly higher degree with mutual infertility,
-and which thus approached by one small step toward
-absolute sterility? Yet an advance of this kind, if the theory
-of natural selection be brought to bear, must have incessantly
-<span class='pageno' id='Page_153'>153</span>occurred with many species, for a multitude are mutually
-quite barren.”</p>
-
-<p class='c010'>Darwin points out the interesting parallel existing between
-the results of intercrossing, and those of grafting together
-parts of different species.</p>
-
-<p class='c010'>“As the capacity of one plant to be grafted or budded on
-another is unimportant for their welfare in a state of nature,
-I presume that no one will suppose that this capacity is a
-<i>specially</i> endowed quality, but will admit that it is incidental
-on differences in the laws of growth of the two plants. We
-can sometimes see the reason why one tree will not take on
-another, from differences in their rate of growth, in the
-hardness of their wood, in the period of the flow or nature
-of their sap, etc.; but in a multitude of cases we can assign
-no reason whatever. Great diversity in the size of two
-plants, one being woody and the other herbaceous, one
-being evergreen and the other deciduous, and adapted to
-widely different climates, do not always prevent the two
-grafting together. As in hybridization, so with grafting,
-the capacity is limited by systematic affinity, for no one has
-been able to graft together trees belonging to quite distinct
-families; and, on the other hand, closely allied species, and
-varieties of the same species, can usually, but not invariably,
-be grafted with ease. But this capacity, as in hybridization,
-is by no means absolutely governed by systematic affinity.
-Although many distinct genera within the same family have
-been grafted together, in other cases species of the same
-genus will not take on each other. The pear can be grafted
-far more readily on the quince, which is ranked as a distant
-genus, than on the apple, which is a member of the same
-genus. Even different varieties of the pear take with different
-degrees of facility on the quince; so do different varieties
-of the apricot and peach on certain varieties of the plum.”</p>
-
-<p class='c010'>“We thus see, that although there is a clear and great
-difference between the mere adhesion of grafted stocks, and
-<span class='pageno' id='Page_154'>154</span>the union of the male and female elements in the act of
-reproduction, yet that there is a rude degree of parallelism
-in the results of grafting and of crossing of distinct species.
-And we must look at the curious and complex laws governing
-the facility with which trees can be grafted on each other
-as incidental on unknown differences in their vegetative systems,
-so I believe that the still more complex laws governing
-the facility of first crosses are incidental on unknown differences
-in their reproductive systems.... The facts by
-no means seem to indicate that the greater or lesser difficulty
-of either grafting or crossing various species has been a
-special endowment; although in the case of crossing, the
-difficulty is as important for the endurance and stability
-of specific forms, as in the case of grafting it is unimportant
-for their welfare.”</p>
-<h3 class='c014'><span class='sc'>Weismann’s Germinal Selection</span></h3>
-
-<p class='c015'>We cannot do better, in bringing this long criticism of the
-Darwinian theory to an end, than by considering the way in
-which Weismann has attempted in his paper on “Germinal
-Selection” to solve one of the “patent contradictions” of the
-selection theory. He calls attention, in doing so, to what he
-regards as a vital weakness of the theory in the form in
-which it was left by Darwin himself. Weismann says:—</p>
-
-<p class='c010'>“The basal idea of the essay—the existence of Germinal
-Selection—was propounded by me some time since,<a id='r15' /><a href='#f15' class='c017'><sup>[15]</sup></a> but it is
-here for the first time fully set forth and tentatively shown to
-be the necessary complement of the process of selection.
-Knowing this factor, we remove, it seems to me, the patent
-contradiction of the assumption that the general fitness of
-organisms, or the adaptations <i>necessary</i> to their existence, are
-produced by <i>accidental</i> variations—a contradiction which
-<span class='pageno' id='Page_155'>155</span>formed a serious stumbling-block to the theory of selection.
-Though still assuming that the <i>primary</i> variations are ‘accidental,’
-I yet hope to have demonstrated that an interior
-mechanism exists which compels them to go on increasing in
-a definite direction, the moment selection intervenes. <i>Definitely
-directed variation exists</i>, but not predestined variation,
-running on independently of the life conditions of the organism,
-as Nägeli, to mention the most extreme advocate of this
-doctrine, has assumed; on the contrary, the variation is such
-as is elicited and controlled by those conditions themselves,
-though indirectly.”</p>
-
-<div class='footnote c018' id='f15'>
-<p class='c019'><span class='label'><a href='#r15'>15</a>.&nbsp;&nbsp;</span><i>Neue Gedanken zur Vererbungsfrage, eine Antwort an Herbert Spencer</i>,
-Jena, 1895.</p>
-</div>
-
-<p class='c010'>“The real aim of the present essay is to rehabilitate the
-principle of selection. If I should succeed in reinstating this
-principle in its emperilled rights, it would be a source of
-extreme satisfaction to me; for I am so thoroughly convinced
-of its indispensability as to believe that its demolition would
-be synonymous with the renunciation of all inquiry concerning
-the causal relation of vital phenomena. If we could understand
-the adaptations of nature, whose number is infinite,
-only upon the assumption of a teleological principle, then, I
-think, there would be little inducement to trouble ourselves
-about the causal connection of the stages of ontogenesis, for
-no good reason would exist for excluding teleological principles
-from this field. Their introduction, however, is the ruin
-of science.”<a id='r16' /><a href='#f16' class='c017'><sup>[16]</sup></a></p>
-
-<div class='footnote c018' id='f16'>
-<p class='c019'><span class='label'><a href='#r16'>16</a>.&nbsp;&nbsp;</span>Translated by J. McCormack. The Open Court Publishing Company. The
-following quotations are also taken from this translation.</p>
-</div>
-
-<p class='c010'>Weismann states that those critics who maintain that
-selection cannot create, but only reject, “fail to see that precisely
-through this rejection its creative efficacy is asserted.”
-There is raised here, though not for the first time, a point
-that is of no small importance for both Darwinians and anti-Darwinians
-to consider; for, without further examination, it
-is by no means self-evident, as Weismann implies, that by
-exterminating all variations that are below the average the
-<span class='pageno' id='Page_156'>156</span>standard of successive generations could ever be raised beyond
-the most extreme fluctuating variation. At least this
-appears to be the case if individual, fluctuating variations be
-the sort selected, and it is to this kind of variation to which
-Weismann presumably refers. Without discussing this point
-here, let us examine further what Weismann has to say. He
-thinks that while in each form there may be a very large
-number of possible variations, yet there are also impossible
-variations as well, which do not appear. “The cogency, the
-irresistible cogency as I take it, of the principle of selection
-is precisely its capacity of explaining why fit structures always
-arise, and this certainly is the great problem of life.”
-Weismann points out that it is a remarkable fact that to-day,
-after science has been in possession of this principle for
-something over thirty years, “during which time she has busily
-occupied herself with its scope, the estimation in which
-the theory is held should be on the decline.” “It would be
-easy to enumerate a long list of living writers who assign to
-it a subordinate part only in evolution, or none at all.”
-“Even Huxley implicitly, yet distinctly, intimated a doubt
-regarding the principle of selection when he said: ‘Even if
-the Darwinian hypothesis were swept away, evolution would
-still stand where it is.’ Therefore he, too, regarded it as
-not impossible that this hypothesis should disappear from
-among the great explanatory principles by which we seek
-to approach nearer to the secrets of nature.”</p>
-
-<p class='c010'>Weismann is not, however, of this opinion, and believes
-that the present depression is only transient, because it is only
-a reaction against a theory that had been exalted to the
-highest pinnacle. He thinks that the principle of selection
-is not overestimated, but that naturalists imagined too quickly
-that they understood its workings. “On the contrary, the
-deeper they penetrated into its workings the clearer it appeared
-that something was lacking, that the action of the
-principle, though upon the whole clear and representable, yet
-<span class='pageno' id='Page_157'>157</span>when carefully looked into encountered numerous difficulties,
-which were formidable, for the reason that we were unsuccessful
-in tracing out the actual details of the individual process,
-and, therefore, in <i>fixing</i> the phenomenon as it actually
-occurred. We can state in no single case how great a variation
-must be to have selective value, nor how frequently it
-must occur to acquire stability. We do not know when and
-whether a desired useful variation really occurs, nor on what
-its appearance depends; and we have no means of ascertaining
-the space of time required for the fulfilment of the selective
-processes of nature, and hence cannot calculate the
-exact number of such processes that do and can take place at
-the same time in the same species. Yet all this is necessary
-if we wish to follow out the precise details of a given case.</p>
-
-<p class='c010'>“But perhaps the most discouraging circumstance of all
-is, that we can assert in scarcely a single actual instance in
-nature whether an observed variation is useful or not—a
-drawback that I distinctly emphasized some time ago. Nor
-is there much hope of betterment in this respect, for think
-how impossible it would be for us to observe all the individuals
-of a species in all their acts of life, be their habitat ever
-so limited—and to observe all this with a precision enabling
-us to say that this or that variation possessed selective value,
-that is, was a decisive factor in determining the existence of
-the species.”</p>
-
-<p class='c010'>“And thus it is everywhere. Even in the most indubitable
-cases of adaptation as, for instance, in that of the striking protective
-coloring of many butterflies, the sole ground of inference
-that the species on the whole is adequately adapted to
-its conditions of life, is the simple fact that the species is,
-to all appearances, preserved undiminished, but the inference
-is not at all permissible that just this protective coloring has
-selective value for the species, that is, if it were lacking,
-the species would necessarily have perished.”</p>
-
-<p class='c010'>Few opponents of Darwinism could give a more pessimistic
-<span class='pageno' id='Page_158'>158</span>account of the accomplishments of the theory of natural selection
-than this, by one of the leaders of the modern school:
-“Discouraging, therefore, as it may be that the control of
-nature in her minutest details is here gainsaid us, yet it were
-equivalent to sacrificing the gold to the dross, if simply from
-our inability to follow out the details of the individual case
-we should renounce altogether the principle of selection, or
-should proclaim it as only subsidiary, on the ground that we
-believe the protective coloring of the butterfly is not a protective
-coloring, but a combination of colors inevitably resulting
-from internal causes. The protective coloring remains a
-protective coloring whether at the time in question it is or is
-not necessary for the species; and it arose as protective coloring—arose
-not because it was a constitutional necessity of
-the animal’s organism that here a red and there a white,
-black, or yellow spot should be produced, but because it was
-advantageous, because it was necessary for the animal.
-There is only one explanation possible for such patent adaptations,
-and that is selection. What is more, no other natural
-way of their originating is conceivable, for we have no right
-to assume teleological forces in the domain of natural phenomena.”</p>
-
-<p class='c010'>Weismann states that he does not accept Eimers’s view that
-the markings of the wings of the butterflies of the genus
-Papilio are due to a process of evolution in a direct line, independent
-of external causes.</p>
-
-<p class='c010'>“On the contrary, I believe it can be clearly proved that
-the wing of the butterfly is a tablet on which Nature has inscribed
-everything she has deemed advantageous to the preservation
-and welfare of her creatures, and nothing else; or, to
-abandon the simile, that these color patterns have not proceeded
-from inward evolutional forces but are the result of
-selection. At least in all places where we do understand
-their biological significance these patterns are constituted and
-distributed over the wing exactly as utility would require.”</p>
-
-<p class='c010'><span class='pageno' id='Page_159'>159</span>Again: “I should be far from maintaining that the markings
-arose unconformably to law. Here, as elsewhere, the
-dominance of law is certain. But I take it, that the laws
-involved, that is, the physiological conditions of the variation,
-here are without exception subservient to the ends of a higher
-power—utility; and that it is utility primarily that determines
-the kind of colors, spots, streaks, and bands that shall
-originate, as also their place and mode of disposition. The
-laws come into consideration only to the extent of conditioning
-the quality of the constructive materials—the variations, out
-of which selection fashions the designs in question. And this
-also is subject to important restrictions, as will appear in the
-sequel.” This conclusion contains all that the most ardent
-Darwinian could ask.</p>
-
-<p class='c010'>He rejects the idea that internal laws alone could have produced
-the result, because:—</p>
-
-<p class='c010'>“If internal laws controlled the markings on butterflies’
-wings, we should expect that some general rule could be established,
-requiring that the upper and under surfaces
-of the wings should be alike or that they should be
-different, or that the fore wings should be colored the same
-as or differently from the hind wings, etc. But in reality all
-possible kinds of combinations occur simultaneously, and no
-rule holds throughout. Or, it might be supposed that bright
-colors should occur only on the upper surface or only on the
-under surface, or on the fore wings or only on the hind wings.
-But the fact is they occur indiscriminately, now here, now
-there, and no one method of appearance is uniform throughout
-all the species. But the fitness of the various distributions of
-colors is apparent, and the moment we apply the principle of
-utility we know why in the diurnal butterflies the upper surface
-alone is usually variegated and the under surface protectively
-colored, or why in the nocturnal butterflies the fore
-wings have the appearance of bark, of old wood, or of a leaf,
-whilst the hind wings, which are covered when resting, alone
-<span class='pageno' id='Page_160'>160</span>are brilliantly colored. On this theory we also understand
-the exceptions to these rules. We comprehend why Danaids,
-Heliconids, Euploids, and Acracids, in fact all diurnal butterflies
-offensive to the taste and smell, are mostly brightly marked
-and equally so on both surfaces, whilst all species not thus
-exempt from persecution have the protective coloring on the
-under surface and are frequently quite differently colored
-there from what they are on the upper.</p>
-
-<p class='c010'>“In any event, the supposed formative laws are not obligatory.
-Dispensations from them can be issued and are issued
-<i>whenever utility requires it</i>.”</p>
-
-<p class='c010'>Dispensations from the laws of growth! Does not a
-philosophy of this sort seem to carry us back into the dark
-ages? Is this the best that the Darwinian school can do
-to protect itself against the difficulties into which its chief
-disciple confesses it has fallen?</p>
-
-<p class='c010'>Weismann lays great emphasis on the case of the Indian
-leaf-butterfly, <i>Kallima inachis</i>; and points out that the leaf
-markings are executed “in absolute independence of the
-other uniformities governing the wing.”</p>
-
-<p class='c010'>“The venation of the wing is utterly ignored by the leaf
-markings, and its surface is treated as a <i>tabula rasa</i> upon
-which anything conceivable can be drawn. In other words,
-we are presented here with a <i>bilaterally symmetrical</i> figure
-engraved on a surface which is essentially <i>radially symmetrical</i>
-in its divisions.</p>
-
-<p class='c010'>“I lay unusual stress upon this point because it shows that
-we are dealing here with one of those cases which cannot be
-explained by mechanical, that is, by natural means, unless
-natural selection actually exists and is actually competent to
-create new properties; for the Lamarckian principle is excluded
-here <i>ab initio</i>, seeing that we are dealing with a formation
-which is only passive in its effects: the leaf markings
-are effectual simply by their existence and not by any function
-which they perform; they are present in flight as well
-<span class='pageno' id='Page_161'>161</span>as at rest, during the absence of a danger, as well as during
-the approach of an enemy.</p>
-
-<p class='c010'>“Nor are we helped here by the assumption of <i>purely internal
-motive forces</i>, which Nägeli, Askenasy, and others have
-put forward as supplying a <i>mechanical</i> force of evolution. It
-is impossible to regard the coincidence of an Indian butterfly
-with the leaf of a tree now growing in an Indian forest as
-fortuitous, as a <i>lusus naturæ</i>. Assuming this seemingly mechanical
-force, therefore, we should be led back inevitably
-to a teleological principle which produces adaptive characters
-and which must have deposited the directive principle in the
-very first germ of terrestrial organisms, so that after untold
-ages at a definite time and place the illusive leaf markings
-should be developed. The assumption of preëstablished
-harmony between the evolution of the ancestral line of the
-tree with its prefigurative leaf, and that of the butterfly with
-its imitating wing, is absolutely necessary here, as I pointed
-out many years ago, but as is constantly forgotten by the
-promulgators of the theory of internal evolutionary forces.”</p>
-
-<p class='c010'>Weismann concludes, therefore, that for his present purpose
-it suffices to show “that cases exist wherein all natural
-explanations except that of selection fail us,” and he then
-proceeds to point out that even the natural selection of Darwin
-and of Wallace also fail to give us a reasonable explanation
-of how, for example, the markings on the wings of the
-Kallima butterfly have come about. The main reason that
-he gives to show that this is the case rests on the difficulty of
-the assumption that the right variations should always be
-present in the right place. Here “is the insurmountable
-barrier for the explanatory power of the principle [natural
-selection] for who, or what, is to be our guarantee that the
-dark scales shall appear at the exact spots on the wing where
-the midrib of the leaf must grow? And that later dark
-scales shall appear at the exact spots to which the midrib
-must be prolonged? And that still later such dark scales
-<span class='pageno' id='Page_162'>162</span>shall appear at the places whence the lateral ribs start, and
-that here also a definite acute angle shall be preserved.”
-Thus the philosopher in his closet multiplies and magnifies
-the difficulties for which he is about to offer a panacea. Had
-the same amount of labor been spent in testing whether the
-life of this butterfly is so closely dependent on the exact imitation
-of the leaf, we might have been spared the pains of
-this elaborate exordium. There are at least some grounds
-for suspicion that the whole case of Kallima is “made up.”
-If this should prove true, it will be a bad day for the Darwinians,
-unless they fall back on Weismann’s statement that
-their theory is insufficient to prove a single case!</p>
-
-<p class='c010'>Weismann has used Kallima only as the most instructive
-illustration. The objections that are here evident are
-found not only in the cases of protective coloration, but “are
-applicable in all cases where the process of selection is concerned.
-Take, for example, the case of instincts that are
-called into action only once in life, as the pupal performances
-of insects, the fabrication of cocoons, etc. How is it that
-the useful variations were always present here?” Weismann
-concludes that “something is still wanting to the selection
-theory of Darwin and Wallace, which it is obligatory on us
-to discover, if we possibly can, and without which selection
-as yet offers no complete explanation of the phyletic processes
-of transformation.” Weismann’s first step in the solution of
-the difficulty is contained in the following statement:—</p>
-
-<p class='c010'>“My inference is a very simple one: if we are forced by
-the facts on all hands to the assumption that the useful
-variations which render selection possible are always present,
-then, <i>some profound connection must exist between the utility
-of a variation and its actual appearance</i>, or, in other words,
-<i>the direction of the variation of a part must be determined by
-utility</i>, and we shall have to see whether facts exist that confirm
-our conjecture.”</p>
-
-<p class='c010'>Weismann finds the solution in the method by which the
-<span class='pageno' id='Page_163'>163</span>breeder has obtained his results in artificial selection. For
-instance, the long-tailed variety of the domestic cock of Japan
-owes its existence, it is claimed, to skilful selection, and not
-at all to the circumstance that, at some period of the race’s
-history, a cock with tail-feathers six feet in length suddenly
-and spasmodically appeared.</p>
-
-<p class='c010'>Weismann continues: “Now what does this mean? Simply
-that the hereditary diathesis, the germinal constitution (the
-<i>Anlage</i>) of the breed was changed in the respect in question,
-and our conclusion from this and numerous similar facts of
-artificial selection runs as follows: <i>by the selection alone of the
-plus or minus variations of a character is the constant modification
-of that character in the plus or minus direction determined</i>.
-Obviously the hereditary <i>diminution</i> of a part is also
-effected by the simple selection of the individuals in each
-generation possessing the smallest parts, as is proved, for
-example, by the tiny bills and feet of numerous breeds of
-doves. We may assert, therefore, in general terms: a definitely
-directed progressive variation of a given part is produced
-by continued selection in that definite direction. This
-is no hypothesis, but a direct inference from the facts and
-may also be expressed as follows: <i>by a selection of the kind
-referred to the germ is progressively modified in a manner
-corresponding with the production of a definitely directed
-progressive variation of the part</i>.”</p>
-
-<p class='c010'>So far there is nothing essentially new offered, since Darwin
-often tacitly recognized that the standard of variation could
-be raised in this way, and in some places he has made
-definite statements that this will take place. Weismann
-thinks that after each selection, fluctuation will then occur
-around a higher average (mode). He says “that this is a
-fact,” and is proved by the case of the Japanese cock. It
-need scarcely be pointed out that it is an assumption, based
-on what is supposed to have taken place in this bird, and is
-not a “fact.”</p>
-
-<p class='c010'><span class='pageno' id='Page_164'>164</span>Weismann continues: “But the question remains, <i>why</i> is
-this the fact?” He believes his hypothesis of the existence
-of determinants in the germ gives a satisfactory answer to
-this “why.” “According to this theory every independent
-and hereditarily variable part is represented in the germ by
-a <i>determinant</i>, whose size and power of assimilation corresponds
-to the size and vigor of the part. These determinants
-multiply as do all vital units by growth and division, and
-necessarily they increase rapidly in every individual, and the
-more rapidly the greater the quantity of the germinal cells
-the individual produces. And since there is no more reason
-for excluding irregularities of passive nutrition, and of the
-supply of nutriment in these minute, microscopically invisible
-parts, than there is in the larger visible parts of the cells,
-tissues, and organs, consequently the descendants of a determinant
-can never all be exactly alike in size and capacity of
-assimilation, but they will oscillate in this respect to and fro
-about the maternal determinant as about their zero point, and
-will be partly greater, partly smaller, and partly of the same
-size as that. In these oscillations, now, the material for
-further selection is presented, and in the inevitable fluctuations
-of the nutrient supply, I see the reason why every
-step attained immediately becomes the zero point of new
-fluctuations, and consequently why the size of a part can
-be augmented or diminished by selection without limit, solely
-by the displacement of the zero point of variation as the
-result of selection.”</p>
-
-<p class='c010'>The best illustration of this process of germinal selection
-is found, Weismann believes, in the case of the degeneration
-of organs. “For in most retrogressive processes <i>active</i> selection
-in Darwin’s sense plays no part, and advocates of the
-Lamarckian principle, as above remarked, have rightly
-denied that active selection, that is, the selection of individuals
-possessing the useless organ in its most reduced
-state, is sufficient to explain the process of degeneration. I,
-<span class='pageno' id='Page_165'>165</span>for my part, have never assumed this, and have on this very
-account enunciated the <i>principle of panmixia</i>. Now, although
-this, as I have still no reason for doubting, is a perfectly correct
-principle, which really does have an essential and indispensable
-share in the process of retrogression, still it is not
-<i>alone</i> sufficient for a full explanation of the phenomena.
-My opponents, in advancing this objection, were right, to the
-extent indicated, and as I expressly acknowledge, although
-they were unable to substitute anything positive in its stead
-or to render my explanation complete. The very fact of the
-cessation of control over the organ is sufficient to explain its
-<i>degeneration</i>, that is, its deterioration, the disharmony of its
-parts, but not the fact which actually and always occurs
-where an organ has become useless—viz., <i>its gradual and
-unceasing diminution continuing for thousands and thousands
-of years and culminating in its final and absolute effacement</i>.”</p>
-
-<p class='c010'>If then neither selection of persons nor the cessation of
-personal selection can explain the phenomenon, we must
-look elsewhere for the answer. This Weismann finds in
-the application of Roux’s hypothesis of the struggle of the
-parts to obtain nourishment.</p>
-
-<p class='c010'>“The production of the long tail-feathers of the Japanese
-cock does not repose solely on the displacement directly
-effected by personal selection, of the zero point of variation
-upward, but that <i>it is also fostered and strengthened by
-germinal selection</i>. Were that not so, the phenomena of the
-transmutation of species, in so far as fresh growth and the
-enlargement and complication of organs already present are
-concerned, <i>would not be a whit more intelligible than they
-were before</i>.”</p>
-
-<p class='c010'>Thus Weismann has piled up one hypothesis on another as
-though he could save the integrity of the theory of natural
-selection by adding new speculative matter to it. The most
-unfortunate feature is that the new speculation is skilfully
-removed from the field of verification, and invisible germs
-<span class='pageno' id='Page_166'>166</span>whose sole functions are those which Weismann’s imagination
-bestows on them, are brought forward as though they
-could supply the deficiencies of Darwin’s theory. This is,
-indeed, the old method of the philosophizers of nature. An
-imaginary system has been invented which attempts to explain
-all difficulties, and if it fails, then new inventions are to
-be thought of. Thus we see where the theory of the selection
-of fluctuating germs has led one of the most widely known
-disciples of the Darwinian theory.</p>
-
-<p class='c010'>The worst feature of the situation is not so much that
-Weismann has advanced new hypotheses unsupported by
-experimental evidence, but that the speculation is of such a
-kind that it is, from its very nature, unverifiable, and therefore
-useless. Weismann is mistaken when he assumes that
-many zoologists object to his methods because they are
-largely speculative. The real reason is that the speculation
-is so often of a kind that cannot be tested by observation or
-by experiment.</p>
-
-<div class='pbb'>
- <hr class='pb c006' />
-</div>
-<div class='chapter'>
-  <span class='pageno' id='Page_167'>167</span>
-  <h2 class='c008'>CHAPTER VI<br /> <br /><span class='c013'>DARWIN’S THEORY OF SEXUAL SELECTION</span></h2>
-</div>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div><span class='c020'><span class='sc'>Sexual Selection</span></span></div>
-  </div>
-</div>
-
-<p class='c009'><span class='sc'>The</span> theory of sexual selection was formulated by Darwin,
-even in the first edition of the “Origin of Species,” but was
-developed at much greater length in “The Descent of Man.”
-“This form of selection depends, not on a struggle for existence
-in relation to other organic beings or to external conditions,
-but on a struggle between the individuals of one sex,
-generally the males, for the possession of the other sex. The
-result is not death to the unsuccessful competitor, but few or
-no offspring. Sexual selection is, therefore, less rigorous
-than natural selection. Generally the most vigorous males,
-those which are best fitted for their place in nature, will leave
-most progeny. But in many cases victory depends, not so
-much on general vigor, as on having special weapons, confined
-to the male sex. A hornless stag or spurless cock
-would have a poor chance of leaving numerous offspring.
-Sexual selection, by always allowing the victor to breed,
-might surely give indomitable courage, length to the spur,
-and strength to the wing to strike in the spurred leg in
-nearly the same manner as the brutal cock-fighter by the
-careful selection of his best cocks.” It is important to notice
-that the theory of sexual selection is admittedly an
-extension of the selection principle into a new field. Having
-accounted for domesticated animals and plants by artificial
-selection, and for the adaptations of wild species by natural
-selection, there remained only to account for the secondary
-<span class='pageno' id='Page_168'>168</span>sexual differences between the sexes by the principle of
-sexual selection.</p>
-
-<p class='c010'>There are two ways in which Darwin supposes sexual selection
-to act: (1) through competition of the individuals of
-the same sex with each other,—the strongest or best-equipped
-for fighting or for finding the individuals of the other sex
-gaining an advantage; (2) through selection by the individuals
-of one sex of certain preferred individuals of the other sex.</p>
-
-<p class='c010'>The first category is natural selection applied to the members
-of one sex in competition with each other, although the result
-does not lead to the death of the unsuccessful individual,
-but excludes it from leaving progeny. In the second category
-a new element is introduced, namely, the <i>selective power</i>
-of the individuals of one sex, usually the female. It is this
-part that adds a distinctly new element to Darwin’s other
-two theories of selection, and it is this part that we naturally
-think of as the theory of sexual selection <i>par excellence</i>.
-Darwin makes, however, no sharp distinction between these
-two sides of his theory, but includes both under the heading
-of sexual selection.</p>
-
-<p class='c010'>In order to get the theory itself before us in as concrete
-form as possible, let us examine some of the cases that
-Darwin has given to show how he supposes the process to
-be carried out.</p>
-
-<p class='c010'>“There are many other structures and instincts which must
-have been developed through sexual selection—such as the
-weapons of offence and the means of defence of the males for
-fighting with and driving away their rivals—their courage
-and pugnacity—their various ornaments—their contrivances
-for producing vocal or instrumental music—and their glands
-for emitting odors, most of these latter structures serving
-only to allure or excite the female. It is clear that these
-characters are the result of sexual and not of ordinary selection,
-since unarmed, unornamented, or unattractive males
-would succeed equally well in the battle for life and in leaving
-<span class='pageno' id='Page_169'>169</span>a numerous progeny, but for the presence of better-endowed
-males. We may infer that this would be the case, because
-the females, which are unarmed and unornamented, are able to
-survive and procreate their kind. Secondary sexual characters
-of the kind just referred to will be fully discussed in the
-following chapters, as being in many respects interesting,
-but especially as depending on the will, choice, and rivalry of
-the individuals of either sex. When we behold two males
-fighting for the possession of the female, or several male birds
-displaying their gorgeous plumage, and performing strange
-antics before an assembled body of females, we cannot doubt
-that, though led by instinct, they know what they are about,
-and consciously exert their mental and bodily powers.”</p>
-
-<p class='c010'>This general statement gives an idea of the class of phenomena
-that Darwin proposes to explain by the theory of sexual
-selection. The close resemblance between this process
-and that of artificial selection may be gathered from the following
-statement:—</p>
-
-<p class='c010'>“Just as man can improve the breed of his game-cocks by
-the selection of those birds which are victorious in the cockpit,
-so it appears that the strongest and most vigorous males,
-or those provided with the best weapons, have prevailed
-under nature, and have led to the improvement of the natural
-breed or species. A slight degree of variability leading to
-some advantage, however slight, in reiterated deadly contests
-would suffice for the work of sexual selection; and it is certain
-that secondary sexual characters are eminently variable. Just
-as man can give beauty, according to his standard of taste, to
-his male poultry, or more strictly can modify the beauty originally
-acquired by the parent species, can give to the Sebright
-bantam a new and elegant plumage, an erect and peculiar carriage—so
-it appears that female birds in a state of nature have,
-by a long selection of the more attractive males, added to their
-beauty or other attractive qualities. No doubt this implies
-powers of discrimination and taste on the part of the female
-<span class='pageno' id='Page_170'>170</span>which will at first appear extremely improbable; but by the
-facts to be adduced hereafter, I hope to be able to show that
-the females actually have these powers. When, however, it
-is said that the lower animals have a sense of beauty, it must
-not be supposed that such sense is comparable with that of a
-cultivated man, with his multiform and complex associated
-ideas. A more just comparison would be between the taste
-for the beautiful in animals, and that in the lowest savages,
-who admire and deck themselves with any brilliant, glittering,
-or curious object.”</p>
-
-<p class='c010'>Darwin did not close his eyes to the difficulties which the
-theory had to contend against. One of the most formidable
-of these objections is described in the following words:
-“Our difficulty in regard to sexual selection lies in understanding
-how it is that the males which conquer other males,
-or those which prove the most attractive to the females,
-leave a greater number of offspring to inherit their superiority
-than their beaten and less attractive rivals. Unless
-this result does follow, the characters which give to certain
-males an advantage over others could not be perfected and
-augmented through sexual selection. When the sexes exist
-in exactly equal numbers, the worst-endowed males will
-(except where polygamy prevails) ultimately find females,
-and leave as many offspring, as well fitted for their general
-habits of life, as the best-endowed males. From various
-facts and considerations, I formerly inferred that with most
-animals, in which secondary sexual characters are well
-developed, the males considerably exceeded the females in
-number; but this is not by any means always true. If the
-males were to the females as two to one, or as three to two,
-or even in a somewhat lower ratio, the whole affair would be
-simple; for the better-armed or more attractive males would
-leave the largest number of offspring. But after investigating,
-as far as possible, the numerical proportion of the
-sexes, I do not believe that any great inequality in number
-<span class='pageno' id='Page_171'>171</span>commonly exists. In most cases sexual selection appears
-to have been effective in the following manner.</p>
-
-<p class='c010'>“Let us take any species, a bird for instance, and divide
-the females inhabiting a district into two equal bodies, the
-one consisting of the more vigorous and better-nourished
-individuals, and the other of the less vigorous and healthy.
-The former, there can be little doubt, would be ready to
-breed in the spring before the others; and this is the
-opinion of Mr. Jenner Weir, who has carefully attended to
-the habits of birds during many years. There can also be
-no doubt that the most vigorous, best-nourished and earliest
-breeders would on an average succeed in rearing the largest
-number of fine offspring. The males, as we have seen, are
-generally ready to breed before the females; the strongest,
-and with some species the best-armed of the males, drive
-away the weaker; and the former would then unite with
-the more vigorous and better-nourished females, because
-they are the first to breed. Such vigorous pairs would
-surely rear a larger number of offspring than the retarded
-females, which would be compelled to unite with the conquered
-and less powerful males, supposing the sexes to be
-numerically equal; and this is all that is wanted to add, in
-the course of successive generations, to the size, strength
-and courage of the males, or to improve their weapons.”</p>
-
-<p class='c010'>I shall comment later on the points here raised, but we
-should not let this opportunity pass without noticing, that even
-if the pairing were to follow according to the method here
-imagined, still the argument breaks down at the critical
-point, for there is no evidence that the more precocious
-females would rear a larger number of offspring than the
-more normal females, or even those that breed somewhat
-later.</p>
-
-<p class='c010'>The greater eagerness of the males which has been observed
-in so many different classes of animals is accounted
-for as follows:—</p>
-
-<p class='c010'><span class='pageno' id='Page_172'>172</span>“But it is difficult to understand why the males of species,
-of which the progenitors were primordially free, should invariably
-have acquired the habit of approaching the females,
-instead of being approached by them. But in all cases, in
-order that the males should seek efficiently, it would be
-necessary that they should be endowed with strong passions;
-and the acquirement of such passions would naturally follow
-from the more eager leaving a larger number of offspring
-than the less eager.”</p>
-
-<p class='c010'>Thus we are led to the rather complex conclusion, that
-the more eager males will leave more descendants, and those
-that are better endowed with ornaments will be the ones
-selected. But unless it can be shown that there is some
-connection between greater eagerness and better ornamentation,
-it might often occur that the less ornamented were the
-more eager individuals, in which case there would be an
-apparent conflict between the two acquirements.</p>
-
-<p class='c010'>After giving some cases of the greater variability of the
-males, in respect to characters that are not connected with
-sexual selection, and presumably not the result of any kind
-of selection, Darwin concludes: “Through the action of
-sexual and natural selection male animals have been rendered
-in very many instances widely different from their females;
-but independently of selection the two sexes, from differing
-constitutionally, tend to vary in a somewhat different manner.
-The female has to expend much organic matter in the
-formation of her ova, whereas the male expends much force
-in fierce contests with his rivals, in wandering about in
-search of the female, in exerting his voice, pouring out
-odoriferous secretions, etc.: and this expenditure is generally
-concentrated within a short period. The great vigor
-of the male during the season of love seems often to intensify
-his colors, independently of any marked difference
-from the female. In mankind, and even as low down in the
-organic scale as in the Lepidoptera, the temperature of the
-<span class='pageno' id='Page_173'>173</span>body is higher in the male than in the female, accompanied
-in the case of man by a slower pulse. On the whole, the
-expenditure of matter and force by the two sexes is probably
-nearly equal, though effected in very different ways and at
-different rates.”</p>
-
-<p class='c010'>Again: “From the causes just specified, the two sexes
-can hardly fail to differ somewhat in constitution, at least
-during the breeding season; and although they may be
-subjected to exactly the same conditions, they will tend to
-vary in a different manner. If such variations are of no
-service to either sex, they will not be accumulated and increased
-by sexual or natural selection. Nevertheless, they
-may become permanent if the exciting cause acts permanently;
-and in accordance with a frequent form of inheritance
-they may be transmitted to that sex alone in which they
-first appeared. In this case, the two sexes will come to
-present permanent, yet unimportant, differences of character.
-For instance, Mr. Allen shows that with a large number of
-birds inhabiting the northern and southern United States,
-the specimens from the south are darker-colored than those
-from the north; and this seems to be the direct result of
-the difference in temperature, light, etc., between the two
-regions. Now, in some few cases, the two sexes of the same
-species appear to have been differently affected; in the
-<i>Agelæus phœniceus</i> the males have had their colors greatly
-intensified in the south; whereas with <i>Cardinalis virginianus</i>
-it is the females which have been thus affected: with <i>Quiscalus
-major</i> the females have been rendered extremely variable
-in tint, whilst the males remain nearly uniform.”</p>
-
-<p class='c010'>The admissions contained in this statement would seem
-to jeopardize the entire question, for, if it is admitted that, on
-account of the difference in the constitution of the two sexes,
-the influence of the surrounding conditions would produce a
-different effect on them, it would seem that there is no need
-whatsoever for the theory of sexual selection. What Darwin
-<span class='pageno' id='Page_174'>174</span>is probably attempting to show is that the material for the
-further action of sexual selection is already given; but the
-question may well be asked, if the external conditions have
-done so much, why may they not have gone farther and produced
-the entire result?</p>
-
-<p class='c010'>Darwin makes the following suggestion to account for those
-cases in which the female is the more highly colored:—</p>
-
-<p class='c010'>“A few exceptional cases occur in various classes of
-animals, in which the females instead of the males have
-acquired well-pronounced secondary sexual characters, such
-as brighter colors, greater size, strength, or pugnacity.
-With birds there has sometimes been a complete transposition
-of the ordinary characters proper to each sex; the
-females having become the more eager in courtship, the
-males remaining comparatively passive, but apparently selecting
-the more attractive females, as we may infer from the
-results. Certain hen birds have thus been rendered more
-highly colored or otherwise ornamented, as well as more
-powerful and pugnacious than the cocks; these characters
-being transmitted to the female offspring alone.”</p>
-
-<p class='c010'>Then follows immediately the discussion as to whether a
-double process of sexual selection may not be supposed to go
-on at the same time. “It may be suggested that in some
-cases a double process of selection has been carried on; that
-the males have selected the more attractive females, and the
-latter the more attractive males. This process, however,
-though it might lead to the modification of both sexes, would
-not make the one sex different from the other, unless indeed
-their tastes for the beautiful differed; but this is a supposition
-too improbable to be worth considering in the case of any
-animal, excepting man. There are, however, many animals
-in which the sexes resemble each other, both being furnished
-with the same ornaments, which analogy would lead us to
-attribute to the agency of sexual selection. In such cases
-it may be suggested with more plausibility, that there has
-<span class='pageno' id='Page_175'>175</span>been a double or mutual process of sexual selection; the
-more vigorous and precocious females selecting the more
-attractive and vigorous males, the latter rejecting all except
-the more attractive females. But from what we know of the
-habits of animals, this view is hardly probable, for the male
-is generally eager to pair with any female. It is more probable
-that the ornaments common to both sexes were acquired
-by one sex, generally the male, and then transmitted to the
-offspring of both sexes. If, indeed, during a lengthened
-period the males of any species were greatly to exceed the
-females in number, and then during another lengthened
-period, but under different conditions, the reverse were to
-occur, a double but not simultaneous process of sexual selection
-might easily be carried on, by which the two sexes might
-be rendered widely different.”</p>
-
-<p class='c010'>The improbability of such a process is so manifest that
-the suggestion can scarcely be looked upon as anything more
-than pure speculation. We shall have occasion later to return
-to the same subject, and point out its bearing more
-explicitly.</p>
-
-<p class='c010'>Nearly the whole animal kingdom is passed in review by
-Darwin from the point of view of the sexual selection theory.
-There is brought together a large number of extremely interesting
-facts, and if the theory did no more than merely hold
-them together, it has served, in this respect, a useful end.
-We may select some of the most instructive cases by way of
-illustrating the theory.</p>
-
-<p class='c010'>In many of the lower animals in which the sexes are separated,
-and these alone, of course, can be supposed to come
-within the range of the theory, there are no striking differences
-between the sexes, in regard to ornamentation, although
-in other respects differences may exist.</p>
-
-<p class='c010'>“Moreover it is almost certain that these animals have too
-imperfect senses and much too low mental powers, to appreciate
-each other’s beauty or other attractions, or to feel rivalry.</p>
-
-<p class='c010'><span class='pageno' id='Page_176'>176</span>“Hence in these classes or subkingdoms, such as the Protozoa,
-Cœlenterata, Echinodermata, Scolecida, secondary sexual
-characters, of the kind which we have to consider, do not
-occur; and this fact agrees with the belief that such characters
-in the higher classes have been acquired through sexual
-selection, which depends on the will, desire, and choice of
-either sex.”</p>
-
-<p class='c010'>There are some cases, however, in which animals low in
-the scale show a difference in the ornamentation of the two
-sexes. A few cases have been recorded in the roundworms,
-where different shades of the same tint distinguish the sexes.
-In the annelids the sexes are sometimes so different, that, as
-Darwin remarks, they have been placed in different genera
-and even families, “yet the differences do not seem to be of
-the kind which can be safely attributed to sexual selection.”
-In regard to the nemertian worms, although they “vie in
-variety and beauty of coloring with any other group in the
-invertebrate series,” yet McIntosh states that he “cannot
-discover that these colors are of any service.” In the copepods,
-belonging to the group of lower Crustacea, Darwin
-excludes those cases in which the males alone “are furnished
-with perfect swimming legs, antennæ, and sense-organs; the
-females being destitute of these organs, with their bodies
-often consisting of a mere distorted mass,” because these
-extraordinary differences between the two sexes are no doubt
-related to their widely different habits of life. Nevertheless,
-it is important to observe that such extreme differences may
-exist in cases where sexual selection cannot come in, because
-of the absence of eyes in the female.</p>
-
-<p class='c010'>In regard to another copepod, Saphirina, Darwin points
-out that the males are furnished with minute scales, which
-exhibit beautiful changing colors, and these are absent in
-the females; yet he states that it would be extremely rash
-to conclude that these curious organs serve to attract
-the females. Differences in the sexes are also found in one
-<span class='pageno' id='Page_177'>177</span>species of Squilla, and a species of Gelasimus. In the latter
-case Darwin thinks that the difference is probably due to
-sexual selection. In addition to these cases, recorded by
-Darwin, there may be added the two remarkable cases,
-shown in our Figure <a href='#fig-2'>2 A, B</a>, of <i>Calocalanus pavo</i>, the female of
-which has a gorgeous tail worthy of a peacock, and of <i>Calocalanus
-plumulosus</i>, in which one of the setæ of the tail is
-drawn out into a long featherlike structure. In the former,
-the male is much more modestly adorned, as shown in Figure <a href='#fig-2'>2 C</a>;
-in the latter species the male is unknown.</p>
-<div id='fig-2'  class='figcenter id004'>
-<img src='images/i177.jpg' alt='' class='ig001' />
-<div class='ic003'>
-<p><span class='sc'>Fig. 2.</span>—A male of the copepod, <i>Calocalanus plumulosus</i>.<br />B and C, a male and a female of <i>Calocalanus pavo</i>. (After Giesbrecht.)</p>
-</div>
-</div>
-<p class='c009'>In spiders, where as a rule the sexes do not differ much
-<span class='pageno' id='Page_178'>178</span>from each other in color, the males are often of a darker shade
-than the females. “In some species, however, the difference
-is conspicuous; thus the female of <i>Sparassus smaragdulus</i> is
-dullish green, whilst the adult male has the abdomen of a fine
-yellow with three longitudinal stripes of rich red.” Darwin
-believes that sexual selection must take place in this group,
-because Canestrini has observed that the males fight for the
-possession of the females. He has also stated that the
-males pay court to the female, and that she rejects some of
-the males who court her, and sometimes devours them, until
-finally one is chosen. Darwin believed, on this evidence,
-that the difference in color of the sexes had been acquired
-by sexual selection, “though we have here not the best kind
-of evidence—the display by the male of his ornaments.”
-This evidence has, however, now been supplied through
-the interesting observations of Mr. and Mrs. Peckham.
-These accurate observers have studied the courtship of the
-male, and observed that during the process, he twists and
-turns his body in such a way as to show to best advantage
-his colors to the female. From their account this certainly
-appears to be the result of his movements, but whether this
-is really the case, and whether the female makes any choice
-amongst her suitors, according to whether they are more or
-less brilliantly marked, we are absolutely ignorant. The following
-account given by Darwin should not pass unnoticed:—</p>
-
-<p class='c010'>“The male is generally much smaller than the female,
-sometimes to an extraordinary degree, and he is forced to be
-extremely cautious in making his advances, as the female
-often carries her coyness to a dangerous pitch. De Geer
-saw a male that ‘in the midst of his preparatory caresses
-was seized by the object of his attentions, enveloped by her
-in a web and then devoured, a sight which, as he adds, filled
-him with horror and indignation.’ The Rev. O. P. Cambridge
-accounts in the following manner for the extreme
-smallness of the male in the genus Nephila. ‘M. Vinson
-<span class='pageno' id='Page_179'>179</span>gives a graphic account of the agile way in which the diminutive
-male escapes from the ferocity of the female, by gliding
-about and playing hide and seek over her body and along her
-gigantic limbs: in such a pursuit it is evident that the
-chances of escape would be in favor of the smallest males,
-while the larger ones would fall early victims; thus gradually
-a diminutive race of males would be selected, until at last
-they would dwindle to the smallest possible size compatible
-with the exercise of their generative functions,—in fact
-probably to the size we now see them, <i>i.e.</i> so small as to be
-a sort of parasite upon the female, and either beneath her
-notice, or too agile and too small for her to catch without
-great difficulty.’”</p>
-
-<p class='c010'>It is certainly surprising to find Darwin ascribing even
-this difference in size between the sexes to the action of
-selection. Is it not a little ludicrous to suppose that the
-females have reduced the males to a size too small for them
-to catch?</p>
-
-<p class='c010'>There are many cases known in the animal kingdom where
-there is a difference in size between the two sexes, especially
-in the group of insects; but I doubt very much if they are to
-be accounted for as the result of sexual selection. In some
-of these cases Darwin accounts for the larger size of the
-female, on account of the large number of eggs which she
-has to carry. In other insects where the male is larger,
-as in the stag-beetle, the size is ascribed to the conflicts of
-the males, leading to the survival of the larger individuals.
-In still other cases, where the males are larger, but do not
-fight, an explanation is admittedly wanting; but it is suggested
-that here there would be no necessity for the males to be
-smaller than the females in order to mature before them (as
-is supposed to happen in other species), for in these cases
-the individuals are not short-lived, and there would be ample
-time for pairing. Again, although the males of nearly all
-bees are smaller than the females, yet the reverse is true in
-<span class='pageno' id='Page_180'>180</span>those forms in which the females are fertilized during the
-marriage flight. The explanation offered is that in these
-forms the male carries the female, and this is assumed to
-require greater size on his part. This loose way of guessing,
-as to a possible explanation, is characteristic of the whole
-hypothesis of sexual selection. First one, and then another,
-guess is made as to the causes of the differences between the
-sexes. It is not shown in a single one of the instances that
-the postulated cause has really had anything to do with the
-differences in question; and the attempt to show that the
-theory is probable, by pointing out the large number of cases
-which it appears to account for, is weakened to a very great
-degree by the number of exceptional cases, for which an
-equally ready explanation of a different kind is forthcoming.
-This way of giving loose rein to the imagination has been
-the bane of the method that has followed hard on the track
-of Darwin’s hypothesis, and for which his example has been
-in no small measure responsible. Thus, in the case just
-quoted, there are no less than four distinct conjectures made
-to account for the differences in size between the sexes, and
-each guess involves an entirely different set of processes.
-Considering the complicated relation of the life of organisms,
-it may be doubted if any of the imagined processes could
-bring about the result, and certainly not a single one has
-been shown to be a real, or a sufficient, cause in the evolutionary
-process. Neither the actuality of the postulated causes,
-nor their application to a particular case, has been shown
-to exist.</p>
-
-<p class='c010'>In the Diptera, or flies, Wallace records one interesting
-case of sexual difference in the genus Elaphomyia of New
-Guinea, in which the males are furnished with horns, which
-the females lack. Darwin writes:—</p>
-
-<p class='c010'>“The horns spring from beneath the eyes, and curiously
-resemble those of a stag, being either branched or palmated.
-In one of the species, they equal the whole body in length.
-<span class='pageno' id='Page_181'>181</span>They might be thought to be adapted for fighting, but as in
-one species they are of a beautiful pink color, edged with
-black, with a pale central stripe, and as these insects have
-altogether a very elegant appearance, it is perhaps more
-probable that they serve as ornaments.”</p>
-
-<p class='c010'>Presumably, therefore, Darwin means these colored horns
-have been acquired by sexual selection.</p>
-
-<p class='c010'>In the Hemiptera, or bugs, both sexes of some species are
-“beautifully colored,” and as the members of the group are
-often unpalatable to other animals, the color in this case is
-supposed to act as a warning signal.</p>
-
-<p class='c010'>In other cases it is stated, however, that “a small pink and
-green species” could hardly be distinguished from the buds
-on the trunks of the lime trees which this insect frequents.
-In this case the color appears “to be directly protective.”
-Thus without any means of forming a correct judgment,
-the color of one animal is supposed to be the result of
-natural selection, since it resembles its surroundings, but
-of sexual selection if the color is present or more pronounced
-in one sex. Where neither view can easily be
-applied, the color is ascribed in a general way to the nature
-of the organism.</p>
-
-<p class='c010'>In respect to the group of Hymenoptera, or bees, Darwin
-records the following cases:—</p>
-
-<p class='c010'>“In this order slight differences in color, according to
-sex, are common, but conspicuous differences are rare except
-in the family of bees; yet both sexes of certain groups are so
-brilliantly colored—for instance in Chrysis, in which vermilion
-and metallic greens prevail—that we are tempted to
-attribute the result to sexual selection. In the Ichneumonidæ,
-according to Mr. Walsh, the males are almost universally
-lighter-colored than the females. On the other hand, in the
-Tenthredinidæ the males are generally darker than the
-females. In the Siricidæ the sexes frequently differ; thus
-the male of <i>Sirex juvencus</i> is banded with orange, whilst the
-<span class='pageno' id='Page_182'>182</span>female is dark purple; but it is difficult to say which sex is
-the more ornamented.”</p>
-
-<p class='c010'>In other families of bees, differences in the color of the
-sexes have been recorded, and since the males have been seen
-fighting for the possession(?) of the females, and since bees
-are known to recognize differences in color, Darwin believes
-that:—</p>
-
-<p class='c010'>“In some species the more beautiful males appear to have
-been selected by the females; and in others the more beautiful
-females by the males. Consequently in certain genera,
-the males of the several species differ much in appearance,
-whilst the females are almost indistinguishable; in other
-genera the reverse occurs. H. Müller believes that the
-colors gained by one sex through sexual selection have often
-been transferred in a variable degree to the other sex, just as
-the pollen-collecting apparatus of the female has often been
-transferred to the male, to whom it is absolutely useless.”</p>
-
-<p class='c010'>Although in beetles the sexes are generally colored alike,
-yet in some of the longicorns there are exceptions to the rule.
-“Most of these insects are large and splendidly colored. The
-males in the genus Pyrodes, which I saw in Mr. Bates’s
-collection, are generally redder but rather duller than the
-females, the latter being colored of a more or less splendid
-golden-green. On the other hand, in one species the male
-is golden-green, the female being richly tinted with red and
-purple. In the genus Esmeralda the sexes differ so greatly
-in color that they have been ranked as distinct species; in
-one species both are of a beautiful shining green, but the
-male has a red thorax. On the whole, as far as I could
-judge, the females of those Prionidæ, in which the sexes
-differ, are colored more richly than the males, and this does
-not accord with the common rule in regard to color, when
-acquired through sexual selection.”</p>
-
-<p class='c010'>The great horns that rise from the heads of many male
-beetles are very striking cases of sexual difference, and
-<span class='pageno' id='Page_183'>183</span>Darwin compares them to the horns of stags and of the
-rhinoceros. They “are wonderful from their size and
-shapes.” Darwin offers the following conjecture as to their
-meaning: “The extraordinary size of the horns, and their
-widely different structure in closely allied forms, indicate
-that they have been formed for some purpose; but their
-excessive variability in the males of the same species leads
-to the inference that this purpose cannot be of a definite
-nature. The horns do not show marks of friction, as if used
-for any ordinary work. Some authors suppose that as the
-males wander about much more than the females, they require
-horns as a defence against their enemies; but as the
-horns are often blunt, they do not seem well adapted for
-defence. The most obvious conjecture is that they are
-used by the males for fighting together; but the males have
-never been observed to fight; nor could Mr. Bates, after a
-careful examination of numerous species, find any sufficient
-evidence, in their mutilated or broken condition, of their having
-been thus used. If the males had been habitual fighters,
-the size of their bodies would probably have been increased
-through sexual selection, so as to have exceeded that of the
-females; but Mr. Bates, after comparing the two sexes in
-above a hundred species of the Copridæ, did not find any
-marked difference in this respect amongst well-developed
-individuals. In Lethrus, moreover, a beetle belonging to
-the same great division of the lamellicorns, the males are
-known to fight, but are not provided with horns, though their
-mandibles are much larger than those of the female.”</p>
-
-<p class='c010'>“The conclusion that the horns have been acquired as ornaments
-is that which best agrees with the fact of their having
-been so immensely, yet not fixedly, developed,—as shown
-by their extreme variability in the same species, and by their
-extreme diversity in closely allied species. This view will at
-first appear extremely improbable; but we shall hereafter
-find with many animals standing much higher in the scale,
-<span class='pageno' id='Page_184'>184</span>namely fishes, amphibians, reptiles and birds, that various
-kinds of crests, knobs, horns and combs have been developed
-apparently for this sole purpose.”</p>
-
-<p class='c010'>It is asking a great deal to suppose that animals, so dull
-and sluggish as these beetles, are endowed with a sufficient
-æsthetic discrimination to select in each generation those
-males whose horns are a little longer than the average. The
-resemblance of the horns to those of stags is, as Darwin
-points out, obvious, but in the latter case also it remains to
-be proven that they are the result of sexual selection, as
-Darwin believes to be the case; but the evidence for this
-belief is not much better, as we shall see in the case of the
-antlers of deer, than it is in these beetles.</p>
-
-<p class='c010'>In regard to butterflies, the males and females are both
-often equally brilliantly colored; in other species the differences
-in the sexes are very striking. Darwin states:—</p>
-
-<p class='c010'>“Even within the same genus we often find species presenting
-extraordinary differences between the sexes, whilst
-others have their sexes closely alike.” The fine colors of
-the wings of many moths are also supposed by Darwin to
-have arisen through sexual selection, although the colors
-are usually on the lower wings, which are covered during
-the day by the less ornamented upper wings. It is assumed
-that, since the moths often begin to fly at dusk, their colors
-might at this time be seen and appreciated by the other sex.
-It should not be overlooked, however, that, in the case of
-some of the most highly colored moths, it is known that the
-males find the females through the sense of smell. Moreover,
-although moths are often finely colored, Darwin points
-out that “it is a singular fact that no British moths which
-are brilliantly colored, and, as far as I can discover, hardly
-any foreign species, differ much in color according to sex;
-though this is the case with many brilliant butterflies.”</p>
-
-<p class='c010'>Yet Darwin does not hesitate to conclude: “From the several
-foregoing facts it is impossible to admit that the brilliant
-<span class='pageno' id='Page_185'>185</span>colors of butterflies, and of some few moths, have commonly
-been acquired for the sake of protection. We have seen
-that their colors and elegant patterns are arranged and exhibited
-as if for display. Hence I am led to believe that the
-females prefer or are most excited by the more brilliant
-males; for on any other supposition the males would, as far
-as we can see, be ornamented to no purpose. We know that
-ants and certain lamellicorn beetles are capable of feeling
-an attachment for each other, and that ants recognize their
-fellows after an interval of several months. Hence there is
-no abstract improbability in the Lepidoptera, which probably
-stand nearly or quite as high in the scale as these insects,
-having sufficient mental capacity to admire bright colors.
-They certainly discover flowers by color.”</p>
-
-<p class='c010'>So far as the evidence of ants having an attachment for
-each other is concerned, we may eliminate this part of the
-argument, since the evidence on which the statement is based
-is now regarded as only showing that ants recognize each
-other by their sense of smell, which resides in the antennæ.
-Hence the so-called fondling means only that the
-ants are trying by smell to determine the odor of the other
-individual.</p>
-
-<p class='c010'>Darwin points out a number of cases in which the females
-are more brightly colored than the males, and for such cases
-he reverses the process of selection, supposing that the males
-have been discriminating, and have not “gladly accepted any
-female.” No explanation is offered to account for this
-reversal of instinct, in fact, no evidence to show that such a
-reversal really exists. Darwin points out that in most cases
-the male insect carries the female during the period of union,
-while in two species of butterflies, <i>Colias edusa</i> and <i>hyale</i>, the
-females carry the males, and the females are here the more
-highly colored. He suggests that since in this case “the
-females take the more active part in the final marriage ceremony,
-so we may suppose that they likewise do so in the
-<span class='pageno' id='Page_186'>186</span>wooing; and in this case we can understand how it is that
-they have been rendered the more beautiful.”</p>
-
-<p class='c010'>A most significant fact in connection with the difference
-in sexual coloration of butterflies did not escape Darwin’s
-attention.</p>
-
-<p class='c010'>“Whilst reflecting on the beauty of many butterflies, it
-occurred to me that some caterpillars were splendidly colored;
-and as sexual selection could not possibly have here acted, it
-appeared rash to attribute the beauty of the mature insect to
-this agency, unless the bright colors of their larvæ could be
-somehow explained. In the first place, it may be observed
-that the colors of caterpillars do not stand in any close correlation
-with those of the mature insect. Secondly, their bright
-colors do not serve in any ordinary manner as a protection.
-Mr. Bates informs me, as an instance of this, that the most
-conspicuous caterpillar which he ever beheld (that of a
-Sphinx) lived on the large green leaves of a tree on the open
-llanos of South America; it was about four inches in length,
-transversely banded with black and yellow, and with its head,
-legs, and tail of a bright red. Hence it caught the eye of any
-one who passed by, even at the distance of many yards, and
-no doubt that of every passing bird.”</p>
-
-<p class='c010'>Darwin applied to Wallace for a solution of this difficulty,
-and received the reply that he “thought it probable that conspicuously
-colored caterpillars were protected by having a
-nauseous taste; but as their skin is extremely tender, and as
-their intestines readily protrude from a wound, a slight peck
-from the beak of a bird would be as fatal to them as if they
-had been devoured. Hence, as Mr. Wallace remarks, ‘distastefulness
-alone would be insufficient to protect a caterpillar
-unless some outward sign indicated to its would-be destroyer
-that its prey was a disgusting morsel.’ Under these circumstances
-it would be highly advantageous to a caterpillar to be
-instantaneously and certainly recognized as unpalatable by all
-birds and other animals. Thus the most gaudy colors would
-<span class='pageno' id='Page_187'>187</span>be serviceable, and might have been gained by variation and
-the survival of the most easily recognized individuals.”</p>
-
-<p class='c010'>It need scarcely be pointed out that an occasional peck
-can scarcely be supposed to have led to the splendid development
-of color shown by some caterpillars, and Darwin confesses
-that at first sight this hypothesis appears bold, but
-nevertheless he believes that it will be found to be true. He
-adds, “We cannot, however, at present thus explain the
-elegant diversity in the colors of many caterpillars.”</p>
-
-<p class='c010'>A most important fact in this connection should not be overlooked,
-namely, that in the caterpillar stage the sexual organs
-are so little developed that it is generally impossible at this
-time to distinguish between the sexes, unless a microscopic
-examination is made. This gives us, perhaps, a clew as to the
-difference between the mature sexual forms. These differences
-are connected with difference of sex itself. This conclusion
-also fits in well with the fact that during the period
-when the sexual organs are at the height of their development
-the individuals are most brilliantly colored. The primary
-cause of the brilliant color of many animals concerns
-us here only secondarily, for, since it is known that many of
-the lower forms are no less brilliantly and elaborately colored
-than are the sexes of the higher forms, it is not surprising
-that the sexes themselves sometimes differ in this respect.</p>
-
-<p class='c010'>Organs for producing sounds of different sorts are present
-in some insects, and these organs Darwin includes under the
-head of secondary sexual organs. In the group of Hemiptera,
-or bugs, the cicadas are the most familiar species that produce
-sounds. The noise is made by the males; the females
-are quite mute.</p>
-
-<p class='c010'>“With respect to the object of the music, Dr. Hartman, in
-speaking of the <i>Cicada septemdecim</i> of the United States,
-says, ‘the drums are now (June 6th and 7th, 1851) heard in
-all directions. This I believe to be the marital summons
-from the males. Standing in thick chestnut sprouts about
-<span class='pageno' id='Page_188'>188</span>as high as my head, where hundreds were around me, I
-observed the females coming around the drumming males.’
-He adds, ‘this season (August, 1868) a dwarf pear-tree in my
-garden produced about fifty larvæ of <i>C. pruinosa</i>; and I
-several times noticed the females to alight near a male while
-he was uttering his clanging notes.’ Fritz Müller writes to
-me from S. Brazil that he has often listened to a musical
-contest between two or three males of a species with a particularly
-loud voice, seated at a considerable distance from
-each other: as soon as one had finished his song, another
-immediately began, and then another. As there is so much
-rivalry between the males, it is probable that the females not
-only find them by their sounds, but that, like female birds,
-they are excited or allured by the male with the most attractive
-voice.”</p>
-
-<p class='c010'>In the flies the following cases are given by Darwin:—</p>
-
-<p class='c010'>“That the males of some Diptera fight together is certain;
-for Professor Westwood has several times seen this with the
-Tipulæ. The males of other Diptera apparently try to win
-the females by their music: H. Müller watched for some
-time two males of an Eristalis courting a female; they hovered
-above her, and flew from side to side, making a high
-humming noise at the same time. Gnats and mosquitoes
-(Culicidæ) also seem to attract each other by humming; and
-Professor Mayer has recently ascertained that the hairs on
-the antennæ of the male vibrate in unison with the notes of a
-tuning-fork, within the range of the sounds emitted by the
-female.”</p>
-
-<p class='c010'>In the crickets, grasshoppers, and locusts, the males “are
-remarkable for their musical powers”; and it is generally
-assumed that the sounds serve to call or to excite the female.
-In these forms the noise is made by rubbing the wings over
-each other or the legs against the wing-covers.</p>
-
-<p class='c010'>In some of these forms both sexes have stridulating organs,
-and in one case they differ to a certain extent from each
-<span class='pageno' id='Page_189'>189</span>other. “Hence we cannot suppose that they have been
-transferred from the male to the female, as appears to have
-been the case with the secondary sexual characters of many
-other animals. They must have been independently developed
-in the two sexes, which no doubt mutually call to each
-other during the season of love.”</p>
-
-<p class='c010'>Some beetles also possess rasping organs in different parts
-of the body, but they cannot produce much noise by this
-means.</p>
-
-<p class='c010'>“We thus see that in the different coleopterous families
-the stridulating organs are wonderfully diversified in position,
-but not much in structure. Within the same family some
-species are provided with these organs, and others are destitute
-of them. This diversity is intelligible, if we suppose
-that originally various beetles made a shuffling or hissing
-noise by the rubbing together of any hard and rough parts
-of their bodies, which happened to be in contact; and that
-from the noise thus produced being in some way useful, the
-rough surfaces were gradually developed into regular stridulating
-organs. Some beetles as they move, now produce,
-either intentionally or unintentionally, a shuffling noise, without
-possessing any proper organs for the purpose.”</p>
-
-<p class='c010'>Darwin says that he expected from analogy to find in this
-group also differences in the sexes, but none such were found,
-although in some cases the males alone possess certain characters
-or have them more highly developed.</p>
-
-<p class='c010'>It is important not to forget, when considering all questions
-connected with sexual selection, that in order for the result
-to be successful it is not only necessary that the female
-respond to the noises and music of the other sex, but that
-she choose the suitor that makes the greatest, or the most
-pleasing, noise. If the stridulating organs are only used by
-the animals in finding each other, then the case might be
-considered as coming under the head of natural selection.
-If this be granted, then it may be claimed, and apparently
-<span class='pageno' id='Page_190'>190</span>Darwin is inclined to adopt this view, that those males that
-make the most noise will be more likely to be heard, and
-possibly approached. They will, therefore, be more likely to
-leave descendants. We have already considered this question
-when dealing with the theory of natural selection in the preceding
-chapter and need not go over the ground again. This
-much may, however, be said again, that even if it is probable
-that these organs are of use to the animals in finding each
-other, and this seems not improbable, it does not follow that
-the organs have been acquired through selection for this
-purpose.</p>
-
-<p class='c010'>Darwin finds his best examples of secondary sexual characters
-in the group of vertebrates, and since in this group the
-intelligence is of a higher order than in the other groups, the
-argument that the female chooses the more pleasing suitor is
-made to appear more plausible.</p>
-
-<p class='c010'>The elongation of the lower jaw that occurs in a few fishes
-at the breeding season is regarded as a secondary sexual
-character. On the other hand, Darwin recognizes the following
-difficulty in regard to the size of the males:—</p>
-
-<p class='c010'>“In regard to size, M. Carbonnier maintains that the
-female of almost all fishes is larger than the male; and Dr.
-Günther does not know of a single instance in which the
-male is actually larger than the female. With some cyprinodonts
-the male is not even half as large. As in many kinds
-of fishes the males habitually fight together, it is surprising
-that they have not generally become larger and stronger than
-the females through the effects of sexual selection. The
-males suffer from their small size, for, according to M. Carbonnier,
-they are liable to be devoured by the females of
-their own species when carnivorous, and no doubt by other
-species. Increased size must be in some manner of more
-importance to the females, than strength and size are to the
-males for fighting with other males; and this perhaps is to
-allow of the production of a vast number of ova.”</p>
-
-<p class='c010'><span class='pageno' id='Page_191'>191</span>The last sentence implies that this particular case is to
-be explained by the females becoming larger on account of
-the number of eggs that they are to produce. But why was
-not the same explanation offered in the case of the spiders?
-It is this uncertain way of applying any explanation that suggests
-itself, that puts the whole method in an unfortunate
-light.</p>
-
-<p class='c010'>In many species of fish the males are brighter in color
-than the females. In the case of <i>Callionymus lyra</i>, Darwin
-states:—</p>
-
-<p class='c010'>“When fresh caught from the sea the body is yellow of
-various shades, striped and spotted with vivid blue on the
-head; the dorsal fins are pale brown with dark longitudinal
-bands, the ventral, caudal, and anal fins being bluish black.
-The female, or sordid dragonet, was considered by Linnæus,
-and by many subsequent naturalists, as a distinct species; it
-is of a dingy reddish brown, with the dorsal fin brown and
-the other fins white. The sexes differ also in the proportional
-size of the head and mouth, and in the position of the
-eyes; but the most striking difference is the extraordinary
-elongation in the male of the dorsal fin. Mr. W. Saville
-Kent remarks that this ‘singular appendage appears from
-my observations of the species in confinement, to be subservient
-to the same end as the wattles, crests, and other abnormal
-adjuncts of the male in gallinaceous birds, for the purpose
-of fascinating their mates.’”</p>
-
-<p class='c010'>In the case of another fish, <i>Cottus scorpius</i>, there is also a
-great difference between the sexes, and here the males become
-very brilliant only at the breeding season. In other
-fishes, in which the sexes are colored alike, the males may
-become more brilliant during the breeding season. This,
-too, is explained by Darwin on the assumption that those
-males that have varied at the breeding season, so as to become
-more brightly colored, have been chosen in preference
-to the other males.</p>
-
-<p class='c010'><span class='pageno' id='Page_192'>192</span>A few cases are cited in which it has been observed that
-the males appear to exhibit themselves before the females, as
-in the following case of the Chinese Macropus:—</p>
-
-<p class='c010'>“The males are most beautifully colored, more so than the
-females. During the breeding season they contend for the
-possession of the females; and, in the act of courtship, expand
-their fins, which are spotted and ornamented with
-brightly colored rays, in the same manner, according to M.
-Carbonnier, as the peacock. They then also bound about
-the females with much vivacity, and appear by ‘l’étalage de
-leurs vives couleurs chercher à attirer l’attention des femelles,
-lesquelles ne paraissaient indifférentes à ce manége, elles
-nageaient avec une molle lenteur vers les mâles et semblaient
-se complaire dans leur voisinage.’”</p>
-
-<p class='c010'>In this connection Darwin makes the following general
-statement:—</p>
-
-<p class='c010'>“The males sedulously court the females, and in one case,
-as we have seen, take pains in displaying their beauty before
-them. Can it be believed that they would thus act to no
-purpose during their courtship? And this would be the case,
-unless the females exert some choice and select those males
-which please or excite them most. If the female exerts such
-choice, all the above facts on the ornamentation of the males
-become at once intelligible by the aid of sexual selection.”</p>
-
-<p class='c010'>While it may readily be granted that display of the male
-may have for its purpose the excitement of the female, it is
-another question as to whether she will be more excited by
-the more beautiful suitor. The attentions of the male may
-be supposed to have a purpose, even if the female does not
-choose the more beautiful of her suitors. It is this last proposition,
-so necessary for the theory of sexual selection, that
-seems improbable. But even if it were probable, there are,
-as we shall see, other difficulties to be overcome before we
-should be justified in accepting Darwin’s statement quoted
-above, concerning the results of sexual selection.</p>
-
-<p class='c010'><span class='pageno' id='Page_193'>193</span>In regard to those species of fish in which both sexes are
-equally ornamented, Darwin returns once more to his hypothesis
-that the color of the male, acquired through sexual
-selection, may be transmitted to the other sex, and then, as
-if in doubt on this point, he adds, that it may be the result
-of the “nature of the tissues and of the surrounding conditions.”
-He even makes the suggestion, somewhat further
-on, that the colors may be warning, although it is confessedly
-unknown that these fish are distasteful to fish-devouring
-animals.</p>
-
-<p class='c010'>In amphibians the crest on the back of the male triton,
-which becomes colored along its edge, is described as a secondary
-sexual character. The vocal sacs, present in some species
-of frogs, are found sometimes in both sexes, but more highly
-developed in the males. In other species, as in the toad, it
-is the male alone that sings. In the reptiles we find that the
-two sexes of the turtles are colored alike, and this holds also
-for the crocodiles. Some male turtles make sounds at the
-breeding season, and the same is true for the crocodiles, the
-males of which are said to make a “prodigous display.” In
-snakes the males are smaller, as a rule, than the females, and
-the colors are more strongly pronounced, and although some
-snakes are very brilliantly colored, Darwin puts this down
-either to protective coloration, or to mimicry of other kinds
-of snakes. But surely the extremely brilliant colors of many
-snakes cannot be accounted for in any of these ways. The
-cause of the color of the venomous kinds, that are supposed
-to be imitated by the others, “remains to be explained and
-this may perhaps be sexual selection.”</p>
-
-<p class='c010'>“It does not, however, follow because snakes have some
-reasoning power, strong passions and mutual affection, that
-they should likewise be endowed with sufficient taste to
-admire brilliant colors in their partners, so as to lead to the
-adornment of the species through sexual selection. Nevertheless,
-it is difficult to account in any other manner for the
-<span class='pageno' id='Page_194'>194</span>extreme beauty of certain species; for instance, of the coral-snakes
-of South America, which are of a rich red with black
-and yellow transverse bands.”</p>
-
-<p class='c010'>In lizards the erectile crests of the male <i>Anolis</i>, the brilliant
-throat patches of <i>Sitaria minor</i>, which is colored blue, black,
-and red, the skinny appendages present on the throat of the
-little lizards of the genus Draco, which in the beauty of their
-colors baffle description, are given as cases of sexual adornment.
-In the last case cited the ornaments are present,
-however, in both sexes. The remarkable horns in the males
-of different species of chameleons are imagined to have been
-acquired through the battle of the males with each other.</p>
-
-<p class='c010'>In the group of birds we find some of the most striking
-cases of secondary sexual differences. The spurs, combs,
-wattles, horns, air-filled sacs, topknots, feathers with naked
-shafts, plumes, and greatly elongated feathers are all secondary
-sexual characters. The songs of the males, the rattling
-together of the quills of the peacock, the drumming of the
-grouse, and the booming sounds made by the night jars
-while on the wing, are further examples of secondary sexual
-differences. The odor of the male of the Australian
-musk duck is also put in the same category.</p>
-
-<p class='c010'>The pugnacity of many male birds is well known, and it is
-imagined that one of the results of the competition of the
-individuals of the same sex with each other has led to the
-development of the organs of defence and offence. The
-males that have been successful in these battles are then supposed
-to mate with the best females. In this way those
-secondary sexual differences, connected with the encounters
-of the males, are supposed to have been formed. Darwin
-states in this connection:—</p>
-
-<p class='c010'>“Even with the most pugnacious species it is probable
-that the pairing does not depend exclusively on the mere
-strength and courage of the male; for such males are generally
-decorated with various ornaments, which often become
-<span class='pageno' id='Page_195'>195</span>more brilliant during the breeding season, and which are
-sedulously displayed before the females. The males also
-endeavor to charm or excite their mates by love-notes, songs,
-and antics; and the courtship is, in many instances, a prolonged
-affair. Hence it is not probable that the females are
-indifferent to the charms of the opposite sex, or that they are
-invariably compelled to yield to the victorious males.”</p>
-
-<p class='c010'>Thus a double process of selection is imagined to take
-place; one, the outcome of a competition of the males with
-each other, and the other, through a choice of the more successful
-males by the females, the more beautiful being
-supposed to be chosen.</p>
-
-<p class='c010'>It may be well not to lose sight of the fact that unless the
-selection is severe in each generation, its good effects will be
-lost, as has been stated in connection with the theory of natural
-selection. Still more important is the consideration
-that unless the same variations appear at the same time, in
-many of the surviving males, the results will be lost through
-crossing. These statements will show that the difficulties of
-the theory are by no means small, and when we are asked to
-believe further that another process still has been superimposed
-on this one, namely, the selection of the more beautiful
-males by the females, we can appreciate how great are the
-difficulties that must be overcome in order that the process
-may be carried out.</p>
-
-<p class='c010'>The love-antics and dances of male birds at the breeding
-season furnish many curious data. The phenomena are
-imagined by Darwin to be connected with sexual selection,
-for in the dances the males are supposed to exhibit their ornaments
-to the females who are imagined to choose the suitor
-that is most to their taste.</p>
-
-<p class='c010'>Hudson, who has studied the habits of birds in the field,
-asks some very pertinent questions in connection with their
-performances of different kinds. “What relation that we
-can see or imagine to the passion of love and the business of
-<span class='pageno' id='Page_196'>196</span>courtship have these dancing and vocal performances in nine
-cases out of ten? In such cases, for instance, as that of the
-scissortail tyrant-bird, and its pyrotechnic displays, when a
-number of couples leave their nests containing eggs and
-young to join in a wild aërial dance; the mad exhibitions of
-ypecahas and ibises and the jacana’s beautiful exhibition of
-grouped wings; the triplet dances of the spur-winged lapwing,
-to perform which two birds already mated are compelled to
-call in a third bird to complete the set; the harmonious duets
-of the oven-birds and the duets and choruses of nearly all
-the wood-hewers, and the wing-slapping aërial displays of the
-whistling widgeons,—will it be seriously contended that the
-female of this species makes choice of the male able to administer
-the most vigorous and artistic slaps?”</p>
-
-<p class='c010'>“The believer in the theory would put all these cases
-lightly aside to cite the case of the male cow-bird practising
-antics before the female, and drawing a wide circle of melody
-around her, etc.... And this was in substance what Darwin
-did.” “How unfair the argument is based on these
-carefully selected cases gathered from all regions of the globe
-and often not properly reported is seen when we turn to the
-book of nature and closely consider the habits and actions
-of all the species inhabiting any <i>one</i> district.” Hudson concludes
-that he is convinced that any one who will note the
-actions of animals for himself will reach the conviction, that
-“conscious sexual selection on the part of the female is not
-the cause of music and dancing performances in birds, nor
-of the brighter colors and ornaments that distinguish the
-male.”</p>
-
-<p class='c010'>The differences in color in the sexes of birds are classified
-by Darwin as follows: (1) when the males are ornamented
-exclusively or in a much higher degree than the females;
-(2) when both sexes are highly ornamented; (3) when the
-female is more brightly colored. A few examples of each
-sort may be chosen for illustration.</p>
-
-<p class='c010'><span class='pageno' id='Page_197'>197</span>“In regard to color, hardly anything need here be said,
-for every one knows how splendid are the tints of many
-birds, and how harmoniously they are combined. The colors
-are often metallic and iridescent. Circular spots are
-sometimes surrounded by one or more differently shaded
-zones, and are thus converted into ocelli. Nor need much be
-said on the wonderful difference between the sexes of many
-birds. The common peacock offers a striking instance.
-Female birds of paradise are obscurely colored and destitute
-of all ornaments, whilst the males are probably the most
-highly decorated of all birds, and in so many different ways,
-that they must be seen to be appreciated. The elongated
-and golden-orange plumes which spring from beneath the
-wings of the <i>Paradisea apoda</i>, when vertically erected and
-made to vibrate, are described as forming a sort of halo, in
-the centre of which the head ‘looks like a little emerald sun,
-with its rays formed by the two plumes.’”</p>
-
-<p class='c010'>Male humming-birds are almost as splendidly colored as
-are the birds of paradise, some having the feathers modified
-in a truly extraordinary way. “Almost every part of their
-plumage has been taken advantage of, and modified; and the
-modifications have been carried, as Mr. Gould showed me, to
-a wonderful extreme in some species belonging to nearly
-every subgroup. Such cases are curiously like those which
-we see in our fancy breeds, reared by man for the sake of
-ornament: certain individuals originally varied in one character,
-and other individuals of the same species in other characters;
-and these have been seized on by man and much
-augmented—as shown by the tail of the fantail pigeon, the
-hood of the jacobin, the beak and wattle of the carrier, and
-so forth. The sole difference between these cases is that
-in the one the result is due to man’s selection, whilst in
-the other, as with humming-birds, birds of paradise, etc., it
-is due to the selection by the females of the more beautiful
-males.”</p>
-
-<p class='c010'><span class='pageno' id='Page_198'>198</span>A remarkable bird of South America, the bell-bird, has a
-peculiar note that “can be distinguished at the distance of
-nearly three miles and astonishes every one who hears it....
-The male is pure white, whilst the female is dusky-green;
-and white is a very rare color in terrestrial species
-of moderate size and inoffensive habits. The male, also, as
-described by Waterton, has a spiral tube, nearly three inches
-in length, which rises from the base of the beak. It is jet-black,
-dotted over with minute downy feathers. This tube
-can be inflated with air, through a communication with the
-palate; and when not inflated hangs down on one side. The
-genus consists of four species, the males of which are very
-distinct, whilst the females, as described by Mr. Sclater in a
-very interesting paper, closely resemble each other, thus offering
-an excellent instance of the common rule that within the
-same group the males differ much more from each other than
-do the females. In a second species (<i>C. nudicollis</i>) the male
-is likewise snow-white, with the exception of a large space of
-naked skin on the throat and round the eyes, which during
-the breeding season is of a fine green color. In a third
-species (<i>C. tricarunculatus</i>) the head and neck alone of the
-male are white, the rest of the body being chestnut-brown,
-and the male of this species is provided with three filamentous
-projections half as long as the body—one rising from the
-base of the beak, and the two others from the corners of the
-mouth.”</p>
-
-<p class='c010'>The most familiar case of sexual difference amongst North
-American birds is that of the scarlet tanager, in which the
-male is scarlet with jet-black wings, while the female is an
-inconspicuous yellow-green color. Amongst domesticated
-animals the peafowl shows the most beautiful case of sexual
-differences. The magnificent tail of the male can be lifted
-up, so as to be seen to best advantage when the male faces
-the observer. Moreover the wild form, living in the forests
-of India, has the same gorgeous train.</p>
-
-<p class='c010'><span class='pageno' id='Page_199'>199</span>The male Argus pheasant has a remarkable series of spots,
-or ocelli, on the secondary wing-covers. They are concealed
-until the male displays them before the female. Darwin
-states that, while it may seem incredible that such elegant
-shading and exquisite patterns could have been the outcome
-of the taste of the female, yet the extraordinary attitude
-assumed by the male during courtship appears entirely purposeless,
-unless it be supposed that he is attempting to charm
-the female by a display of his ornamentation.</p>
-
-<p class='c010'>Let us pass to the second class of cases, in which both
-sexes are similarly and brightly colored, and in which the
-young have a plumage different from the adults. For example,
-the male and the female of the splendid scarlet ibis are
-alike, whilst the young are brown. The males and females of
-many finely colored herons are ornamented alike, and this
-plumage, Darwin admits, has a nuptial character. He even
-tries to explain this by the curious assumption, that while the
-color has been acquired through the selection of the males
-by the females, the results attained in this way have been
-transmitted to both sexes. We find here another example of
-the method so often employed by Darwin. When he meets
-with facts that are not in conformity with the theory, he proceeds
-to make a new assumption without establishing its
-validity. Thus, to assume that in all cases where the sexes
-are colored differently, the characters acquired by the males
-have been transmitted only to the same sex, and in those
-cases where the sexes are colored alike the transmission has
-been to both sexes, is most arbitrary.</p>
-
-<p class='c010'>In other cases, which are commoner than the last, the male
-and female have the same color, and the young in their first
-plumage resemble the adults. Darwin admits that here the
-facts are so complex that his conclusions are doubtful. The
-following account of the tree-sparrow shows how vague are
-the principles involved in the entire discussion in relation to
-transmission:—</p>
-
-<p class='c010'><span class='pageno' id='Page_200'>200</span>“Now with the tree-sparrow (<i>P. montanus</i>) both sexes and
-the young closely resemble the male of the house-sparrow;
-so that they have all been modified in the same manner, and
-all depart from the typical coloring of their early progenitor.
-This may have been effected by a male ancestor of the tree-sparrow
-having varied, firstly, when nearly mature; or secondly,
-whilst quite young, and by having in either case
-transmitted his modified plumage to the females and the
-young; or, thirdly, he may have varied when adult and transmitted
-his plumage to both adult sexes, and, owing to the
-failure of the law of inheritance at corresponding ages, at
-some subsequent period to his young.”</p>
-
-<p class='c010'>The further admissions made in the following quotation are
-also significant:—</p>
-
-<p class='c010'>“The plumage of certain birds goes on increasing in
-beauty during many years after they are fully mature; this
-is the case with the train of the peacock, with some of the
-birds of paradise, and with the crest and plumes of certain
-herons, for instance, the <i>Ardea ludovicana</i>. But it is doubtful
-whether the continued development of such feathers is
-the result of the selection of successive beneficial variations
-(though this is the most probable view with birds of paradise)
-or merely of continuous growth. Most fishes continue
-increasing in size, as long as they are in good health and
-have plenty of food; and a somewhat similar law may prevail
-with the plumes of birds.”</p>
-
-<p class='c010'>We need not follow Darwin through his discussion of
-those cases in which the adults have a winter and a summer
-dress and the young resemble the one or the other in plumage,
-or are different from either. The discussion of these
-cases, confessedly very complex, adds nothing to our understanding
-of the theory, and little but conjecture is offered
-to account for the facts.</p>
-
-<p class='c010'>The extreme to which even conjecture can be carried may
-be gathered from the following quotation, taken from the
-<span class='pageno' id='Page_201'>201</span>section dealing with cases in which the young in their first
-plumage differ from each other according to sex, the young
-males resembling more or less closely the adult males, and
-the young females more or less closely the adult females:</p>
-
-<p class='c010'>“Two humming-birds belonging to the genus Eustephanus,
-both beautifully colored, inhabit the small island of Juan
-Fernandez, and have always been ranked as specifically distinct.
-But it has lately been ascertained that the one which
-is of a rich chestnut-brown color with a golden-red head, is
-the male, whilst the other, which is elegantly variegated with
-green and white with a metallic-green head, is the female.
-Now the young from the first somewhat resemble the adults
-of the corresponding sex, the resemblance gradually becoming
-more and more complete.</p>
-
-<p class='c010'>“In considering this last case, if as before we take the plumage
-of the young as our guide, it would appear that both
-sexes have been rendered beautiful independently; and not
-that one sex has partially transferred its beauty to the other.
-The male apparently has acquired his bright colors through
-sexual selection in the same manner as, for instance, the peacock
-or pheasant in our first class of cases; and the female
-in the same manner as the female Rhynchæa or Turnix in
-our second class of cases. But there is much difficulty in
-understanding how this could have been effected at the same
-time with the two sexes of the same species. Mr. Salvin
-states, as we have seen in the eighth chapter, that with certain
-humming-birds the males greatly exceed the females in
-number, whilst with other species inhabiting the same country
-the females greatly exceed the males. If, then, we might
-assume that during some former lengthened period the males
-of the Juan Fernandez species had greatly exceeded the
-females in number, but that during another lengthened
-period the females had far exceeded the males, we could
-understand how the males at one time, and the females at
-another, might have been rendered beautiful by the selection
-<span class='pageno' id='Page_202'>202</span>of the brighter-colored individuals of either sex; both sexes
-transmitting their characters to their young at a rather
-earlier age than usual. Whether this is the true explanation
-I will not pretend to say; but the case is too remarkable to
-be passed over without notice.”</p>
-
-<p class='c010'>The third group of cases include those in which the females
-are more brightly colored, or more ornamented, than
-the males. These cases are rare, and the differences between
-the sexes are never so great as when the male is the more
-highly colored. Wallace thinks that since in these cases the
-male incubates the eggs his less conspicuous colors have
-been acquired through natural selection. In the genus
-Turnix the female is larger than the male, and lacks the
-black on the throat and neck, and the plumage as a whole is
-lighter than that of the male. The natives assert that the
-females after laying their eggs associate in flocks, and leave
-the males to do the incubating; and from other evidence
-Darwin thinks that this is true.</p>
-
-<p class='c010'>In three species of painted snipe the females “are not only
-larger but much more richly colored than the males,” and the
-trachea is more convoluted in some species. “There is also
-reason to believe that the male undertakes the duty of incubation.”
-In the dotterel plover the female is larger and
-somewhat more strongly colored. The males take at least
-a share in the incubation. In the common cassowary the
-female is larger and the skin of the head more brightly
-colored than in the male. The female is pugnacious during
-the breeding season and the male sits on the eggs. The
-female emu is large and has a crest. She is more courageous
-and pugilistic and makes a deep, hollow, guttural boom.
-The male is more docile and can only hiss or croak. He
-not only incubates the eggs, but defends the young against
-their own mother. “So that with this emu we have a complete
-reversal not only of the parental and incubating instincts,
-but of the usual moral qualities of the two sexes; the females
-<span class='pageno' id='Page_203'>203</span>being savage, quarrelsome, and noisy, the males gentle and
-good. The case is very different with the African ostrich,
-for the male is somewhat larger than the female and has
-finer plumes with more strongly contrasted colors; nevertheless
-he undertakes the whole duty of incubation.”</p>
-
-<p class='c010'>Darwin attempts to explain these reversals of instincts on
-the assumption that the males have turned the tables on the
-females, and have themselves done the selecting; and incidentally,
-it may be pointed out in passing, they have had to
-pay the penalty by incubating the eggs.</p>
-
-<p class='c010'>In the group of mammals, Darwin thinks that the male wins
-the female by conquering other males rather than by charming
-her through his display. The males, even when unarmed,
-engage in desperate conflicts with each other, and sometimes
-kill, but more often only wound, their fellows. The secondary
-sexual characters of the males have been acquired,
-therefore, by natural selection applied to one sex, and less
-frequently through the choice of the female. Since we are
-here more especially concerned with the latter class of
-phenomena, we may examine only a few cases under the
-first head.</p>
-
-<p class='c010'>The horns of stags are used by them in their conflicts
-with each other; the tusks of the elephant make this animal
-the most dangerous in the world, when in must. The horns
-of bulls, the canine teeth of many mammals, the tusks of the
-walrus, are further examples of organs which have been,
-according to Darwin, acquired through the competitions of
-the males with each other.</p>
-
-<p class='c010'>The voices of mammals are used for various purposes, “as
-a signal of danger, as a call from one member of the troup to
-another, and from the mother to her lost offspring, or from
-the latter for protection.”</p>
-
-<p class='c010'>“Almost all male animals use their voices much more during
-the rutting season than at any other time; and some, as
-the giraffe and porcupine, are said to be completely mute
-<span class='pageno' id='Page_204'>204</span>excepting at this season. As the throats (<i>i.e.</i> the larynx and
-thyroid bodies) of stags periodically become enlarged at the
-beginning of the breeding season, it might be thought that
-their powerful voices must be somehow of high importance
-to them; but this is very doubtful. From information given
-to me by two experienced observers, Mr. McNeill and Sir P.
-Egerton, it seems that young stags under three years old do
-not roar or bellow; and that the old ones begin bellowing at
-the commencement of the breeding season, at first only occasionally
-and moderately, whilst they restlessly wander about
-in search of the females. Their battles are prefaced by loud
-and prolonged bellowing, but during the actual conflict they
-are silent. Animals of all kinds which habitually use their
-voices utter various noises under any strong emotion, as
-when enraged and preparing to fight; but this may merely
-be the result of nervous excitement, which leads to the spasmodic
-contraction of almost all the muscles of the body, as
-when a man grinds his teeth and clenches his fists in rage or
-agony. No doubt stags challenge each other to mortal combat
-by bellowing; but those with the more powerful voices,
-unless at the same time the stronger, better-armed, and more
-courageous, would not gain any advantage over their rivals.”</p>
-
-<p class='c010'>“Some writers suggest that the bellowing serves as a call
-to the female; but the experienced observers above quoted
-inform me that female deer do not search for the male,
-though the males search eagerly for the females, as indeed
-might be expected from what we know of the habits of other
-male quadrupeds. The voice of the female, on the other
-hand, quickly brings to her one or more stags, as is well
-known to the hunters who in wild countries imitate her cry.</p>
-
-<p class='c010'>“As the case stands, the loud voice of the stag during the
-breeding season does not seem to be of any special service
-to him, either during his courtship or battles, or in any other
-way. But may we not believe that the frequent use of the
-voice, under the strong excitement of love, jealousy, and rage,
-<span class='pageno' id='Page_205'>205</span>continued during many generations, may at last have produced
-an inherited effect on the vocal organs of the stag, as
-well as of other male animals? This appears to me, in our
-present state of knowledge, the most probable view.”</p>
-
-<p class='c010'>Here once more we find that Darwin makes use, as a sort
-of last resort, of the principle of the inheritance of acquired
-characters. As long as the theory of selection, in any of its
-forms, appears to offer a satisfactory solution, we find the
-facts used in support of this theory, but as soon as a difficulty
-arises the Lamarckian theory is brought to the front.
-It is this shifting, as we have already more than once pointed
-out, that shows how little real basis there is for the theory of
-sexual selection.</p>
-
-<p class='c010'>The male gorilla has a tremendous voice, and he has, as
-has also the orang, a laryngeal sac. One species of gibbon
-has the power of producing a correct octave of musical notes.</p>
-
-<p class='c010'>“The vocal organs of the American <i>Mycetes caraya</i> are
-one-third larger in the male than in the female, and are wonderfully
-powerful. These monkeys in warm weather make
-the forests resound at morning and evening with their overwhelming
-voices. The males begin the dreadful concert, and
-often continue it during many hours, the females sometimes
-joining in with their less powerful voices. An excellent
-observer, Rengger, could not perceive that they were excited
-to begin by any special cause; he thinks that, like many
-birds, they delight in their own music, and try to excel each
-other. Whether most of the foregoing monkeys have acquired
-their powerful voices in order to beat their rivals and charm
-the females—or whether the vocal organs have been strengthened
-and enlarged through the inherited effects of long-continued
-use without any particular good being thus gained—I
-will not pretend to say; but the former view, at least in
-the case of the <i>Hylobates agilis</i>, seems the most probable.”</p>
-
-<p class='c010'>The odor of some mammals is confined to, or more developed,
-in the males; but in some forms, as in the skunk, it is
-<span class='pageno' id='Page_206'>206</span>present in both sexes. In the shrew mice, abdominal scent
-glands are present, but since these mice are rejected by birds
-of prey, their glands probably serve to protect them; “nevertheless
-the glands become enlarged in the males during the
-breeding season.” In many other quadrupeds the scent
-glands are of the same size in both sexes, and their function
-is unknown.</p>
-
-<p class='c010'>“In other species the glands are confined to the males, or
-are more developed than in the females; and they almost
-always become more active during the rutting season. At
-this period the glands on the sides of the face of the male
-elephant enlarge, and emit a secretion having a strong musky
-odor. The males, and rarely the females, of many kinds of
-bats have glands and protrudable sacs situated in various
-parts; and it is believed that these are odoriferous.</p>
-
-<p class='c010'>“The rank effluvium of the male goat is well known, and
-that of certain male deer is wonderfully strong and persistent.
-Besides the general odor, permeating the whole body
-of certain ruminants (for instance, <i>Bos moschatus</i>) in the
-breeding season, many deer, antelopes, sheep, and goats,
-possess odoriferous glands in various situations, more especially
-on their faces. The so-called tear-sacs, or suborbital
-pits, come under this head. These glands secrete a
-semifluid fetid matter which is sometimes so copious as to
-stain the whole face, as I have myself seen in an antelope.
-They are ‘usually larger in the male than in the female,
-and their development is checked by castration.’ According
-to Desmarest they are altogether absent in the female of
-<i>Antilope subgutturosa</i>. Hence, there can be no doubt that
-they stand in close relation with the reproductive functions.
-They are also sometimes present, and sometimes absent, in
-nearly allied forms. In the adult male musk-deer (<i>Moschus
-moschiferus</i>), a naked space round the tail is bedewed with
-an odoriferous fluid, whilst in the adult female and in the
-male until two years old, this space is covered with hair, and
-<span class='pageno' id='Page_207'>207</span>is not odoriferous.” Darwin believes in these cases that the
-odor serves to attract the females. He admits that here,
-“active and long-continued use cannot have come into
-play as in the case of the vocal organs.” He concludes,
-therefore, that “the odor emitted must be of considerable
-importance to the male, inasmuch as large and complex
-glands, furnished with muscles for everting the sac, and for
-closing or opening the orifice, have in some cases been
-developed. The development of these organs is intelligible
-through sexual selection, if the most odoriferous males are
-the most successful in winning the females, and in leaving
-offspring to inherit their gradually perfected glands and
-colors.”</p>
-
-<p class='c010'>There is sometimes a difference in the mammals in the
-hair of the two sexes both in amount and in color. In some
-species of goats the males have a beard, in others it is
-present in both sexes. The bull, but not the cow, has curly
-hair on the forehead. In some monkeys the beard is confined
-to the male, as in the orang; in other species it is only
-larger in the males.</p>
-
-<p class='c010'>“The males of various members of the ox family (Bovidæ),
-and of certain antelopes, are furnished with a dewlap, or
-great fold of skin on the neck, which is much less developed
-in the female.</p>
-
-<p class='c010'>“Now, what must we conclude with respect to such sexual
-differences as these? No one will pretend that the beards
-of certain male goats, or the dewlap of the bull, or the crests
-of hair along the backs of certain male antelopes, are of any
-use to them in their ordinary habits.</p>
-
-<p class='c010'>“Must we attribute all these appendages of hair or skin to
-mere purposeless variability in the male? It cannot be
-denied that this is possible; for in many domesticated quadrupeds,
-certain characters, apparently not derived through
-reversion from any wild parent form, are confined to the
-males, or are more developed in them than in the females—for
-<span class='pageno' id='Page_208'>208</span>instance, the hump on the male zebu cattle of India,
-the tail of fat-tailed rams, the arched outline of the forehead
-in the males of several breeds of sheep, and, lastly, the mane,
-the long hairs on the hind-legs, and the dewlap of the male
-of the Berbura goat.”</p>
-
-<p class='c010'>In these cases and in others that Darwin cites, which seem
-clearly to indicate that some of these secondary sexual characters
-are not the result of sexual selection, he concludes, “that
-they must be due to simple variability, together with sexually
-limited inheritance.</p>
-
-<p class='c010'>“Hence it appears reasonable to extend this same view to
-all analogous cases with animals in a state of nature. Nevertheless
-I cannot persuade myself that it generally holds good,
-as in the case of the extraordinary development of hair on
-the throat and fore-legs of the male Ammotragus, or in
-that of the immense beard of the male Pithecia. Such study
-as I have been able to give to nature makes me believe that
-parts or organs which are highly developed, were acquired
-at some period for a special purpose. With those antelopes
-in which the adult male is more strongly colored than the
-female, and with those monkeys in which the hair on the
-face is elegantly arranged and colored in a diversified
-manner, it seems probable that the crests and tufts of hair
-were gained as ornaments; and this I know is the opinion of
-some naturalists. If this be correct, there can be little doubt
-that they were gained, or at least modified through sexual
-selection; but how far the same view may be extended to
-other mammals is doubtful.”</p>
-
-<p class='c010'>The astonishing colors in some of the monkeys cannot
-be passed over without comment.</p>
-
-<p class='c010'>“In the beautiful <i>Cercopithecus diana</i>, the head of the
-adult male is of an intense black, whilst that of the female
-is dark gray; in the former the fur between the thighs is of
-an elegant fawn-color, in the latter it is paler.</p>
-
-<p class='c010'>“In the <i>Cercopithecus cynosurus</i> and <i>griseoviridis</i> one part
-<span class='pageno' id='Page_209'>209</span>of the body, which is confined to the male sex, is of the most
-brilliant blue or green, and contrasts strikingly with the naked
-skin on the hinder part of the body, which is vivid red.</p>
-
-<p class='c010'>“Lastly, in the baboon family, the adult male of <i>Cynocephalus
-hamadryas</i> differs from the female not only by his
-immense mane, but slightly in the color of the hair and of
-the naked callosities. In the drill (<i>C. leucophæus</i>) the females
-and young are much paler-colored, with less green, than the
-adult males. No other member in the whole class of mammals
-is colored in so extraordinary a manner as the adult
-male mandrill (<i>C. mormon</i>). The face at this age becomes
-of a fine blue, with the ridge and tip of the nose of the most
-brilliant red. According to some authors, the face is also
-marked with whitish stripes, and is shaded in parts with
-black, but the colors appear to be variable. On the forehead
-there is a crest of hair, and on the chin a yellow beard.
-‘Toutes les parties supérieures de leurs cuisses et le grand
-espace nu de leurs fesses sont également colorés du rouge le
-plus vif, avec un mélange de bleu qui ne manque réellement
-pas d’élégance.’ When the animal is excited all the naked
-parts become much more vividly tinted.”</p>
-
-<p class='c010'>Darwin sums up the evidence in regard to the differences
-in color between the male and female in the following
-statement:—</p>
-
-<p class='c010'>“I have now given all the cases known to me of a difference
-in color between the sexes of mammals. Some of
-these may be the result of variations confined to one sex
-and transmitted to the same sex, without any good being
-gained, and therefore without the aid of selection. We
-have instances of this with our domesticated animals, as in
-the males of certain cats being rusty-red, whilst the females
-are tortoise-shell colored. Analogous cases occur in nature:
-Mr. Bartlett has seen many black varieties of the jaguar,
-leopard, vulpine phalanger, and wombat; and he is certain
-that all or nearly all these animals, were males. On the
-<span class='pageno' id='Page_210'>210</span>other hand, with wolves, foxes, and apparently American
-squirrels, both sexes are occasionally born black. Hence it
-is quite possible that with some mammals a difference in
-color between the sexes, especially when this is congenital,
-may simply be the result, without the aid of selection, of
-the occurrence of one or more variations, which from the
-first were sexually limited in their transmission. Nevertheless
-it is improbable that the diversified, vivid, and contrasted
-colors of certain quadrupeds, for instance, of the
-above monkeys and antelopes, can thus be accounted for.”</p>
-
-<p class='c010'>Finally, the case of man must be considered from the
-point of view of sexual selection, for Darwin claims that
-man has acquired a number of his secondary sexual characters
-in this way. For instance, the beard is an excellent
-case of a secondary sexual character. Darwin’s interpretation
-is that the beard has been retained, or even developed,
-through the selection by the females of those males that
-had this outgrowth best developed. Conversely, the absence
-of hair on the face of the female is supposed by Darwin to
-have been brought about by men selecting those women
-having less hair on their faces. The greater intellect,
-energy, courage, pugnacity, and size of man are the outcome
-of the competition of the males with each other, since the
-individual excelling in these qualities will be able to select
-the most desirable wife, or wives, and it is assumed will,
-therefore, leave more descendants. The standard of beauty
-has been kept up by men selecting the most beautiful women
-in each generation (the fate of the other married women is
-ignored), and this beauty is supposed to have been transmitted
-primarily to their daughters, but also to their sons.</p>
-
-<p class='c010'>Although all these forms of selection are imagined to be
-acting in man, either alternately or simultaneously, yet Darwin
-recognizes in man a number of checks to the action
-of sexual selection: amongst savages, the so-called communal
-marriages; second, infanticide, generally of the young
-<span class='pageno' id='Page_211'>211</span>females, which appears in some races to be practised to an
-astonishing degree; third, early betrothals; fourth, the holding
-of women as slaves.</p>
-
-<p class='c010'>When we recall that selection to be effective can only
-be carried out under very exacting conditions, we cannot
-but be appalled at the demands made here on our credulity.
-The choice of the women has produced the beard of man,
-the choice of man the absence of a beard in women; the
-competition of the males with each other is leading at the
-same time to the development of at least half a dozen
-qualities that are supposed to be male specialities, and
-while all this is going on the results are being checked
-sometimes by one means, sometimes by another. Moreover,
-even this is not all that we are asked to accept, for there
-are several other qualities of the male that are put down as
-secondary sexual characters. For example, let us examine
-what Darwin has to say in regard to the development of
-the voice, and of singing in man.</p>
-
-<p class='c010'>In man the vocal cords are about a third longer than in
-woman and his voice deeper. Emasculation arrests the development
-of the vocal apparatus, and the voice remains like
-that of a woman. This difference between the sexes, Darwin
-thinks, is due probably to long-continued use by the
-male “under the excitement of love, rage, and jealousy.”
-In other words, an appeal is again made to the Lamarckian
-theory, and in this case to explain the origin of an organ that
-conforms to all the requirements of the secondary sexual
-characters.</p>
-
-<p class='c010'>“The capacity and love for singing, or music, though not a
-sexual character in man,” in the sense of being confined to
-one sex, yet is supposed to have arisen through sexual selection
-in the following way: “Human song is generally
-admitted to be the basis or origin of instrumental music.
-As neither the enjoyment nor the capacity of producing
-musical notes are faculties of the least use to man in reference
-<span class='pageno' id='Page_212'>212</span>to his daily habits of life, they must be ranked amongst
-the most mysterious with which he is endowed.”</p>
-
-<p class='c010'>Man is supposed to have possessed this faculty of song
-from a very remote time, and even the most savage races
-make musical sounds, although we do not enjoy their music,
-or they ours.</p>
-
-<p class='c010'>“We see that the musical faculties, which are not wholly
-deficient in any race, are capable of prompt and high development,
-for Hottentots and Negroes have become excellent
-musicians, although in their native countries they rarely
-practise anything that we should consider music. Hence the
-capacity for high musical development, which the savage
-races of man possess, may be due either to the practice by
-our semi-human progenitors of some rude form of music, or
-simply to their having acquired the proper vocal organs for
-a different purpose. But in this latter case we must assume,
-as in the above instance of parrots, and as seems to occur
-with many animals, that they already possessed some sense
-of melody.”</p>
-
-<p class='c010'>Darwin sums up the evidence in the two following statements,
-the insufficiency of which to explain the phenomena
-is I think only too obvious: “All these facts in respect to
-music and impassioned speech become intelligible to a certain
-extent, if we assume that musical tones and rhythm were used
-by our half-human ancestors, during the season of courtship,
-when animals of all kinds are excited not only by love, but
-by the strong passions of jealousy, rivalry, and triumph.
-From the deeply laid principle of inherited associations,
-musical tones in this case would be likely to call up vaguely
-and indefinitely the strong emotions of a long past age.”
-Thus the difficulty is shifted to the shoulders of our long-lost
-savage ancestors; or even, in fact, to our simian forefathers,
-as the following paragraph indicates:—</p>
-
-<p class='c010'>“As the males of several quadrumanous animals have
-their vocal organs much more developed than in the females,
-<span class='pageno' id='Page_213'>213</span>and as a gibbon, one of the anthropomorphous apes, pours
-forth a whole octave of musical notes and may be said to
-sing, it appears probable that the progenitors of man, either
-the males or females or both sexes, before acquiring the
-power of expressing their mutual love in articulate language,
-endeavored to charm each other with musical notes and
-rhythm. So little is known about the use of the voice by
-the Quadrumana during the season of love, that we have no
-means of judging whether the habit of singing was first
-acquired by our male or female ancestors. Women are
-generally thought to possess sweeter voices than men, and as
-far as this serves as any guide, we may infer that they first
-acquired musical powers in order to attract the other sex.
-But if so, this must have occurred long ago, before our ancestors
-had become sufficiently human to treat and value their
-women merely as useful slaves. The impassioned orator,
-bard, or musician, when with his varied tones and cadences
-he excites the strongest emotions in his hearers, little
-suspects that he uses the same means by which his half-human
-ancestors long ago aroused each other’s ardent passions
-during their courtship and rivalry.”</p>
-
-<p class='c010'>We have now examined in some detail the evidence that
-Darwin has brought forward in support of his hypothesis of
-sexual selection. A running comment has been made while
-considering the individual cases, but it may be well to sum
-up the matter by briefly indicating the reasons why the hypothesis
-seems incompetent to explain the facts.</p>
-<h3 class='c014'><span class='sc'>General Criticism of the Theory of Sexual Selection</span></h3>
-
-<p class='c015'>1. Some of the objections that apply to the theory of
-natural selection apply also with equal force to the theory of
-sexual selection in so far as the results in both cases are supposed
-to be the outcome of the selection of individual, or
-fluctuating, variations. If these variations appear in only
-<span class='pageno' id='Page_214'>214</span>a few individuals, their perpetuation is not possible, since
-they will soon disappear through crossing. It would be, of
-course, preposterous to suppose that at any one time only
-those few individuals pair and leave descendants that have the
-secondary sexual characters developed to the highest point,
-but if something of this sort does not occur, the extreme of
-fluctuating variations cannot be maintained. Even if half
-of the individuals are selected in each generation, the accumulation
-of a variation in a given direction could not go
-very far. The assumption, however, that only half of all the
-individuals that reach maturity breed, and that all of these
-are chosen on account of the special development of their
-secondary sexual characters, seems preposterous. Furthermore,
-if it is assumed that the high development of the new
-character appears in a large number of individuals, then it
-is not improbable that its continued appearance might be
-accounted for without bringing in, at all, the hypothesis of
-sexual selection.</p>
-
-<p class='c010'>2. But even supposing that the females select the most beautiful
-males, then, since in the vast majority of higher animals
-the males and the females are in equal numbers, the others will
-also be able to unite with each other in pairs after this first
-selection has taken place. Nothing will therefore be gained
-in the next generation. It is interesting to see how Darwin
-attempts to meet this argument. He tries to show in the
-case of birds, that there are always unpaired individuals, but
-since the few facts that he has been able to collect show that
-there are as many additional females as males, the argument
-proves too much. A few species are polygamous, one male
-having a number of female birds; but on this basis we can
-only account, at best, for the development through competition
-of the organs of offence and defence used to keep
-away the weaker males. Yet it is just amongst these birds
-that we often find the ornamental characters well developed.
-In fact, since all the females in such cases are selected, and
-<span class='pageno' id='Page_215'>215</span>since they will transmit the characters of all the males, it is
-evident that the secondary sexual characters could not be
-formed in the way imagined.</p>
-
-<p class='c010'>3. If the female fails to select only the more ornamental
-males, no result will follow. It has not been shown that she
-is capable of making such a choice, and in the lower forms
-particularly, it does not seem probable that this is done.
-The argument that Darwin often employs, namely, that
-unless she does select, the display of the males before her is
-meaningless, is not to the point. So far as we can detect
-the “cause” of the display of the male, it appears to be due
-to his own excitement; and even if we go so far as to admit
-that the “purpose” is to attract the other sex, it still does
-not in the least follow that the most ornamental male is selected,
-and unless this occurs the display has no bearing on
-the hypothesis of sexual selection.</p>
-
-<p class='c010'>4. The two forms of sexual selection, namely, competition
-of the males with one another (really one form of natural
-selection), and the selection of the most ornamental or gifted
-individuals, are both used by Darwin to explain secondary
-sexual characters, the one for organs of offence and defence,
-and the other for ornamental characters. If we fully appreciate
-the difficulties that any theory of selection meets with,
-we shall realize how extraordinarily complex the action must
-be, when two such processes are carried out at the same
-time, or even during alternating periods.</p>
-
-<p class='c010'>5. It has been objected to Darwin’s theory of sexual selection,
-that he suddenly reverses its mode of action to explain
-those cases in which the female is the stronger and more
-ornamented sex; but if, as Darwin shows, the instincts of
-the male have also changed, and have become more like those
-of the female, I can see no inherent difficulty in this way of
-applying the theory. A much more serious objection, it
-seems to me, is that the male is supposed to select the female
-for one set of characteristics, and the female to select the
-<span class='pageno' id='Page_216'>216</span>male for another set. It sounds a little strange to suppose
-that women have caused the beard of man to develop by selecting
-the best-bearded individuals, and the compliment has
-been returned by the males selecting the females that have
-the least amount of beard. It is also assumed that the results
-of the selection are transmitted to one sex only. Unless, in
-fact, the character in question were from the beginning
-peculiar to only one sex as to its inheritance, the two sexes
-might go on forever selecting at cross-purposes, and the result
-would be nothing.</p>
-
-<p class='c010'>6. The development, or the presence, of the æsthetic feeling
-in the selecting sex is not accounted for on the theory.
-There is just as much need to explain why the females are
-gifted with an appreciation of the beautiful, as that the beautiful
-colors develop in the males. Shall we assume that still
-another process of selection is going on, as a result of which
-those females are selected by the males that appreciate their
-unusual beauty, or that those females whose taste has soared
-a little higher than that of the average (a variation of this
-sort having appeared) select males to correspond, and thus the
-two continue heaping up the ornaments on one side and the
-appreciation of these ornaments on the other? No doubt an
-interesting fiction could be built up along these lines, but
-would any one believe it, and, if he did, could he prove it?</p>
-
-<p class='c010'>Darwin assumes that the appreciation on the part of the
-female is always present, and he thus simplifies, in appearance,
-the problem, but he leaves half of it unexplained.</p>
-
-<p class='c010'>7. It has been pointed out, that it is important to distinguish
-between the possible excitement of the female by
-the display or antics of the male, and the selection of the
-more beautiful or agile performer. Darwin himself records
-a few cases, which plainly show that the more beautiful is
-not always the more successful. It has also been suggested
-that the battles of the males are sometimes sham performances,
-and even when they are real, if the less vigorous do not remain
-<span class='pageno' id='Page_217'>217</span>to be destroyed but run away, they live to find mates of their
-own. In fact, the conduct of the males at the breeding
-season appears to be much more the outcome of their own
-excitement than an attempt to attract the females.</p>
-
-<p class='c010'>8. There is another side to the question, the importance
-of which is so great, that it is surprising that Darwin has
-not taken any notice of it. If, in order to bring about, or
-even maintain, the results of sexual selection, such a tremendous
-elimination of individuals must take place, it is
-surprising that natural selection would not counteract this
-by destroying those species in which a process, so useless for
-the welfare of the species, is going on. It is curious that this
-has not been realized by those who believe in both of these
-two hypotheses.</p>
-
-<p class='c010'>9. What has just been said applies also with almost equal
-force to the development of such structures as the horns of
-deer, bison, antelopes, and the brilliant colors of many insects
-and birds. If in nature, competition between species takes
-place on the scale that the Darwinian theory of natural selection
-postulates, such forms, if they are much exposed, would
-be needlessly reduced in numbers in the process of acquiring
-these structures. So many individuals would have been at
-such a disadvantage in breeding, that if competition is as severe
-as the theory of natural selection postulates, these species
-could hardly be expected to compete successfully with other
-species in which sexual selection was not taking place.</p>
-
-<p class='c010'>10. Darwin admits that, in certain cases, external conditions
-may have acted directly to produce the colors in certain
-forms, and if these were not injurious he thinks they might
-have become constant. Such cases are left unexplained in
-the sense that they are not supposed to be adaptations to anything
-in particular. That colors produced in this way might
-afterward be found useful, irrespective of how they arose, is
-admitted as one of the ways in which sexual differences may
-have arisen.</p>
-
-<p class='c010'><span class='pageno' id='Page_218'>218</span>11. It is baffling to find Darwin resorting to the Lamarckian
-explanation in those cases in which the improbability of
-the hypothesis of sexual selection is manifest. If either principle
-is true, we should expect it to apply to all phenomena of
-the same sort; yet Darwin makes use of the Lamarckian
-principle, in the hypothesis of sexual selection, only when
-difficulties arise.</p>
-
-<p class='c010'>12. In attempting to explain the development of the musical
-sense in man, it is clear that the hypothesis of sexual
-selection fails to give a satisfactory explanation. To suppose
-that the genius of a Beethoven or of a Mozart could have
-been the result of a process of sexual selection is too absurd
-to discuss. Neither the power of appreciation nor of expression
-in music could possibly have been the outcome of such a
-process, and it does not materially help the problem to refer
-it back to a troop of monkeys making the woods hideous
-with their cries.</p>
-
-<p class='c010'>We come now to some of the special cases to which Darwin’s
-hypothesis has been applied.</p>
-
-<p class='c010'>13. In one case at least, it is stated that a bird living on
-the ground might have acquired the color of the upper surface
-of the body through natural selection, while the under
-surface of the males of the same species might have become
-ornamented through the action of sexual selection. Thus in
-one and the same individual the two processes are supposed
-to have been at work, and it does not lessen the difficulty very
-much by supposing the two processes to have been carried
-out at different times, because it is evident that what had
-been gained at one time by one process might become lost
-while the color of certain parts was being acquired through
-the other process.</p>
-
-<p class='c010'>14. Darwin points out that “the plumage of certain birds
-goes on increasing in beauty during many years after they
-are fully mature,” as in the peacock, and in some of the birds
-of paradise, and with the plumes and crests of some herons.
-<span class='pageno' id='Page_219'>219</span>This is explained as possibly merely the result of “continued
-growth.” The improbability of selection is manifest in these
-cases, but if “continued growth” can accomplish this much,
-why may not the whole process be also the outcome of such
-growth? At any rate, whatever the explanation is, it is important
-to find a case of a secondary sexual character that the
-hypothesis obviously is insufficient to explain.</p>
-
-<p class='c010'>15. It is admitted in a number of cases, as in the stag for
-instance, that, although the larynx of the male is enlarged,
-this is not, in all probability, the outcome of sexual selection,
-but in other forms this same enlargement is ascribed to the
-selection process.</p>
-
-<p class='c010'>16. It is admitted that in none of the highly colored
-British moths is there much difference according to sex,
-although when a difference of color is found in butterflies
-this is put down to the action of sexual selection. If such
-wonderful colors as those of moths can arise without the
-action of selection, why make a special explanation for those
-cases in which this difference is associated with sex?</p>
-
-<p class='c010'>17. It is well known that birds sing at other times of the
-year than at the breeding season, and an attempt is made to
-account for this in that birds take pleasure in practising those
-instincts that they make use of at other times, as the cat
-plays with the captive mouse. Does not this suggest that,
-if they had certain instincts, they would be more likely to
-employ them at the times when their vitality or excitement
-is at its highest without regard to the way in which they have
-come by them?</p>
-
-<p class='c010'>18. The color of the iris of the eyes of many species of
-hornbills is said to be an intense crimson in the males, and
-white in the females. In the male condor the eye is yellowish
-brown, and in the female a bright red. Darwin admits that
-it is doubtful if this difference is the result of sexual selection,
-since in the latter case the lining of the mouth is black
-in the males, and flesh-colored in the females, which does not
-<span class='pageno' id='Page_220'>220</span>affect the external beauty. Yet if these colors were more
-extensive and on the exterior, there can be little doubt that
-they would have been explained as due to sexual selection.</p>
-
-<p class='c010'>19. When the females in certain species of birds differ
-more from each other than they do from their respective
-males, the case is compared to “those inexplicable ones,
-which occur independently of man’s selection in certain sub-breeds
-of the game-fowl, in which the females are very different,
-whilst the males can hardly be distinguished.” Here
-then is a case of difference in color associated with sex, but
-not the outcome of sexual selection.</p>
-
-<p class='c010'>20. The long hairs on the throat of the stag are said possibly
-to be of use to him when hunted, since the dogs generally
-seize him by the throat, “but it is not probable that the hairs
-were specially developed for this purpose; otherwise the
-young and the females would have been equally protected.”
-Here also is a sexual difference that can scarcely be ascribed
-to selection.</p>
-
-<p class='c010'>Some cases of differences in color between the sexes
-“may be the result of variations confined to one sex, and
-transmitted to the same sex without any good being gained,
-and, therefore, without the aid of selection. We have
-instances of this with our domesticated animals, as in the
-males of certain cats being rusty-red while the females are
-tortoise-shell colored. Analogous cases occur in nature:
-Mr. Bartlett has seen many black varieties of the jaguar,
-leopard, vulpine phalanger, and wombat; and he is certain
-that all or nearly all of these animals were males.” If
-changes of this sort occur, associated with one sex, why is
-there any need of a special explanation in other cases of
-difference?</p>
-
-<hr class='c021' />
-
-<p class='c010'>In the light of the many difficulties that the theory of
-sexual selection meets with, I think we shall be justified in
-rejecting it as an explanation of the secondary sexual differences
-<span class='pageno' id='Page_221'>221</span>amongst animals. Other attempts to explain these
-differences have been equally unsuccessful. Thus Wallace
-accounts for them as due to the excessive vigor of the male,
-but Darwin’s reply to Wallace appears to show that this is
-not the cause of the difference. He points out that, while
-the hypothesis might appear plausible in the case of color,
-it is not so evident in the case of other secondary sexual
-characters, such, for instance, as the musical apparatus of the
-males of certain insects, and the difference in the size of the
-larynx of certain birds and mammals.</p>
-
-<p class='c010'>Darwin’s theory served to draw attention to a large number
-of most interesting differences between the sexes, and,
-even if it prove to be a fiction, it has done much good in
-bringing before us an array of important facts in regard to
-differences in secondary sexual characters. More than this I
-do not believe it has done. The theory meets with fatal objections
-at every turn.</p>
-
-<p class='c010'>In a later chapter the question will be more fully discussed
-as to the sense in which these secondary sexual differences
-may be looked upon as adaptations.</p>
-
-<div class='pbb'>
- <hr class='pb c006' />
-</div>
-<div class='chapter'>
-  <span class='pageno' id='Page_222'>222</span>
-  <h2 class='c008'>CHAPTER VII<br /> <br /><span class='c013'>THE INHERITANCE OF ACQUIRED CHARACTERS AS A FACTOR IN&nbsp;EVOLUTION</span></h2>
-</div>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div><span class='c020'><span class='sc'>Lamarck’s Theory</span></span></div>
-  </div>
-</div>
-
-<p class='c009'><span class='sc'>One</span> of the most striking and peculiar characteristics of
-living things is that through use a part is able to carry out
-a particular function better than before, and in some cases
-the use of the part leads to its increase in size. Conversely,
-disuse leads to the decrease of a part in size. We are perfectly
-familiar with this process in ourselves as applied to our
-nervous system and muscles.</p>
-
-<p class='c010'>It is not surprising that the idea should have arisen that,
-if the results of the use of a part are inherited by the next
-generation, the adaptation of organisms might be explained
-in this way. The presence of the organs of touch, in those
-parts of the body that are more likely to come into contact
-with foreign bodies, offers a striking parallel to the perfecting
-of the sensation of touch that can be brought about through
-the use of any part. The development of eyes only on the
-exposed parts of the body, as on the tentacles of the sedentary
-annelids, or along the margin of the mantle of a bivalve
-mollusk, suggests that there may be some direct connection
-between their presence in these regions and the effect of
-light on the parts. In fact, ever since the time of Lamarck,
-there have been many zoologists who have claimed that many
-of the adaptations of organisms have arisen in this way, that
-is, through the inheritance of the characters acquired through
-use. In general this theory is summed up in the phrase,
-“the inheritance of acquired characters.”</p>
-
-<p class='c010'><span class='pageno' id='Page_223'>223</span>This view is prominently associated with the name of
-Lamarck, who held, however, a different view in regard
-to the origin of some of the other structures of the organism.
-Moreover, Erasmus Darwin, even before Lamarck, had suggested
-the principle of the inheritance of acquired characters.</p>
-
-<p class='c010'>As has just been said, Lamarck held that the inheritance of
-acquired characters was only one of the ways in which animals
-have become changed, and he clearly stated that in the
-case of all plants and of some of the lower animals the change
-(evolution) which he supposed them to undergo was due to
-the general influence of the environment. Since plants and
-the lower animals (as he supposed) have no central nervous
-system, or at least no such well-defined nervous system as
-have the higher animals, Lamarck thought that they could
-not have evolved in the same way as have the higher animals.
-We now know that, so far as the lower animals, at least, are
-concerned, there was no need for such a distinction, since
-many of their responses are like those of the higher animals.
-This distinction that Lamarck made is responsible, no doubt,
-for a misconception that was long held in regard to a part of
-his views. It is often stated that he supposed the desire
-of the animal for a particular part has led to the development
-of that part; while in reality he only maintained the
-desire to use a particular organ to fulfil some want led to
-its better development through exercise, and the result was
-inherited. Lamarck also supposed that the <i>decrease</i> in use
-of a part which leads to its decrease in size accounts for the
-degeneration of organs.</p>
-
-<p class='c010'>Lamarck first advanced his theory in 1801, when he cited
-the following examples in its favor. A bird, driven through
-want to the water to find its food, will separate its toes when
-they strike the water. The skin uniting the bases of the toes
-will be stretched in consequence, and in this way the broad
-membrane between the toes of ducks and geese has been
-acquired. The toes of a bird that is in the habit of perching
-<span class='pageno' id='Page_224'>224</span>on a tree become elongated in consequence of becoming
-stretched, hence has arisen the foot with the long toes characteristic
-of arboreal birds.</p>
-
-<p class='c010'>Shore-birds, “which do not care to swim,” but must
-approach the water in order to obtain food, will be in danger
-of sinking into the mud, “but, wishing to act so that their
-body shall not fall into the liquid, they will contract the habit
-of extending and lengthening their legs.” Hence have arisen
-the stiltlike legs of shore-birds.</p>
-
-<p class='c010'>These ideas were more fully elaborated in the following
-year. He added the further examples: Our dray-horses
-have arisen through the use to which they have been put,
-and the race-horse also, which has been used in a different
-way. Cultivated plants, on the contrary, are the result of the
-new environment to which they have been subjected.</p>
-
-<p class='c010'>In the “Philosophic Zoologique,” published in 1809, Lamarck
-has much more fully developed his theory. Here he combats
-strenuously the idea that species are fixed. His point of view
-may be judged by the following propositions, which he believes
-can be established:—</p>
-
-<p class='c010'>1. That all organized bodies of our globe are veritable
-productions of nature, which she has successively produced
-in the course of a long time.</p>
-
-<p class='c010'>2. That in her progress nature began, and begins still
-every day, to produce the simplest organisms, and that she
-still produces directly the same primitive kinds of organizations.
-This process has been called spontaneous generation.</p>
-
-<p class='c010'>3. That the first beginning of animals and of plants takes
-place in favorable localities and under favorable circumstances.
-An organic movement having once established
-their production, they have of necessity gradually developed
-their organs, and have become diversified in the course of
-time.</p>
-
-<p class='c010'>4. That the power of growth of each part of the body
-being inherited as a consequence of the first effect of life,
-<span class='pageno' id='Page_225'>225</span>different modes of multiplication and of regeneration have
-arisen, and these have been conserved.</p>
-
-<p class='c010'>5. That with the aid of sufficient time and of favorable
-circumstances the changes that have taken place on the surface
-of the globe have called forth new structures and new
-habits, and in consequence have modified the organs of the
-body, and made animals and plants such as we see them at
-the present day.</p>
-
-<p class='c010'>6. Finally, as a result of these changes that living bodies
-have been forced to undergo, species have been formed, but
-these species have only a relative constancy, and are not as
-ancient as is nature herself. If the environment remains the
-same, species also remain the same, as is exemplified by the
-animals living at present in Egypt, which are exactly like
-those living there in ancient times.</p>
-
-<p class='c010'>Lamarck concludes that the appearance of stability is
-always mistaken by the layman for the reality, because, in
-general, every one judges things relatively to himself. In
-fact, species are not absolutely constant, but are so only
-temporarily. “The influence of the environment is continuous
-and always active, but its effects may only be
-recognized after a long time.” The irregularity and the
-complexity of the organization of animals is the outcome of
-the infinitely diversified circumstances to which they have
-been subjected. These changes, Lamarck claims, do not
-directly cause modifications in the form of animals,<a id='r17' /><a href='#f17' class='c017'><sup>[17]</sup></a> but
-bring about changes in their needs, and changes in their
-needs bring about changes in their actions. If the needs
-remain the same, the acquired actions become habits. These
-habitual actions lead to the use of certain parts in preference
-to others, and this in turn to an alteration in form and structure.
-The individuals so changed breed together and leave
-descendants that inherit the acquired modification.</p>
-
-<div class='footnote c018' id='f17'>
-<p class='c019'><span class='label'><a href='#r17'>17</a>.&nbsp;&nbsp;</span>This is clearly meant to be applied only in the case of higher animals.</p>
-</div>
-
-<p class='c010'>Curiously enough, Lamarck follows up this argument by
-<span class='pageno' id='Page_226'>226</span>citing some cases amongst plants that have been changed
-directly by the action of the environment. He says that
-since plants have no motions they have consequently no
-habits, but they are developed by changes in their nutrition,
-etc., and this brings about the superiority of some of the
-vital movements over others.</p>
-
-<p class='c010'>Amongst domestic animals Lamarck cites the case of the
-dog, that has come from a wild form like the wolf, but having
-been carried into different countries has acquired different
-and new habits, and this has led to the formation of new
-races, such as the bulldog, greyhound, pug-dog, spaniel, etc.</p>
-
-<p class='c010'>Lamarck’s argument shifts so often back and forth from
-animals to plants, that it is clear that in his own mind he did
-not see any important difference between the action of the
-environment on plants, and the use of the organs of the
-animal. He gives in this same connection his oft-quoted
-summary of what he calls the two laws of nature “which
-observation always establishes.”</p>
-
-<p class='c010'>First Law. In every animal, that has not passed beyond
-the term of its development, the frequent and sustained use
-of any organ strengthens it, develops it, increases its size,
-and gives it strength proportionate to the length of time of its
-employment. On the other hand, the continued lack of use of
-the same organ sensibly weakens it; it deteriorates, and its
-faculties diminish progressively until at last it disappears.</p>
-
-<p class='c010'>Second Law. Nature preserves everything that she has
-caused the individual to acquire or to lose by the influence
-of the circumstances to which the race has been for a long
-time exposed, and consequently by the influence of the predominant
-use of certain organs (or in consequence of its
-continued disuse). She does this by the generation of new
-individuals which are produced with the newly acquired
-organs. This occurs, provided that the acquired changes
-were common to the two sexes, or to the individuals that
-produced the new forms.</p>
-
-<p class='c010'><span class='pageno' id='Page_227'>227</span>These laws are, Lamarck says, fundamental truths which
-cannot be misunderstood except by those who have never
-observed or followed nature in her operations. He insists
-that it is a mistake to suppose that the parts are responsible
-for the functions, for it is easy to demonstrate that it is the
-needs and uses of the organs that have caused the parts to
-develop.</p>
-
-<p class='c010'>If it is supposed, he continues, that these laws are hypothetical,
-they may be demonstrated by the following facts:
-The adult baleen whale is without teeth, although in the
-fœtus teeth are present, concealed in the jaws. The loss
-of the teeth is the result of the whale swallowing its food
-without first masticating it. The ant-eater is also without
-teeth, and has also the habit of swallowing its food without
-chewing it. The mole has very small eyes, and this is the
-result of its having made very little use of them, since its
-habits are subterranean. Another animal, the aspalax, has
-only the rudiments of eyes, and has almost completely lost
-the power of sight. This animal also lives underground like
-the mole.</p>
-
-<p class='c010'>Proteus, an aquatic salamander living in deep caves, has
-only rudimentary eyes. In these latter cases it is the disuse
-of the eye that has led to its degeneration. This is proven,
-Lamarck adds, by the fact that the organs of hearing are
-never in this condition, because sound vibrations penetrate
-everywhere, even into the densest bodies.</p>
-
-<p class='c010'>It is a part of the plan of organization of the reptiles that
-they have four legs; but the snakes, although belonging to
-this group, have no legs. This absence of legs is explained
-by their having acquired the habit of gliding over the ground,
-and of concealing themselves in the grass. Owing to their
-repeated effort to elongate themselves, in order to pass
-through narrow spaces, their bodies have become drawn out.
-Under these circumstances legs would be useless, since long
-ones would interfere with their motion, and short ones could
-<span class='pageno' id='Page_228'>228</span>not move their long bodies. Since the plan of organization
-limits the snakes to only four legs, and since this number
-would be useless, they have disappeared.</p>
-
-<p class='c010'>Many insects are destitute of wings, although wings are a
-part of the plan of organization of this group. They are
-absent only in those forms whose habits render wings useless,
-consequently they have disappeared through disuse.</p>
-
-<p class='c010'>The preceding cases are those in which the disuse of an
-organ has led to its degeneration. The following cases
-are cited to show that by use an organ increases in size.
-The formation of the web in the feet of water-birds has
-already been given as a character which Lamarck supposes
-to have been acquired through use; also the case of shore-birds,
-which, by an effort to elongate their legs, have actually
-made them so in the course of time. The necks of water-birds
-are also long on account of their having been stretched
-in the efforts to catch fish. The long tongues of the ant-eater,
-of the woodpecker, and of humming-birds are the result of
-use, and the long, forked tongue of serpents has come from
-their using their tongue to feel objects in front of them.</p>
-
-<p class='c010'>Fishes that have acquired the habit of living in shallow
-water, flounders, soles, etc., have been forced to swim on their
-sides in order to approach nearer to the shore. Since more
-light comes from above than from below, the eye on the
-under side, straining to turn to the light, has finally migrated
-to the upper side.</p>
-
-<p class='c010'>The habit of eating great quantities of food, which distends
-the digestive organs, has caused the bodies of herbivorous
-quadrupeds to become large, as seen in the elephant, the
-rhinoceros, oxen, horses, and buffaloes. The habit of standing
-for a long time on their feet has caused some animals to
-develop hard, thick hoofs. Herbivorous animals, that inhabit
-countries where they are constantly subjected to attack, as
-deer and antelopes for example, are forced to escape by rapid
-flight, and in consequence their bodies have become slenderer
-<span class='pageno' id='Page_229'>229</span>and their legs thinner. The horns, antlers, and protuberances
-that many of these animals possess are the results
-of their butting each other when angered.</p>
-
-<p class='c010'>“The long neck and the form of the giraffe offer a curious
-case. We know that the giraffe is the tallest of all animals.
-It inhabits the centre of Africa, living in those localities
-where the earth is nearly always dry and without herbage.
-It is obliged to browse on the foliage of trees, and this leads
-to its stretching continually upwards. As a result of this
-habit, carried on for a long time, in all the individuals of the
-race, the anterior limbs have become longer than the posterior,
-and its neck has also lengthened, so that the giraffe
-without rising on its hind-legs stretches up its neck and can
-reach to the height of six metres.”</p>
-
-<p class='c010'>The curved claws of the carnivora have arisen from the
-necessity of grasping their prey. The power of retracting
-the claws has also been acquired by the effort to draw them
-in when running over hard ground. The abdominal pouch
-of the kangaroo, in which the young are carried, opens anteriorly,
-and this has led to the animal standing erect so that
-its young are not injured. In consequence, the fore-legs
-have become shorter through disuse, and the hind-legs have
-become stronger through use. The tail, which is also used as
-a support, has become enormously thick at its base.</p>
-
-<p class='c010'>The sloth has been compelled to seek refuge in the trees,
-and has taken up its abode permanently there, feeding on
-leaves. Its movements are limited to those involved in
-crawling along the limbs in order to reach the leaves. After
-feeding it remains inactive and sluggish, these habits being
-provoked by the heat of the climate. The results of its mode
-of life have been to cause the arms to become elongated due
-to the habit of the sloth of grasping the limbs of the tree;
-the claws of the fingers and toes have also become long and
-hooked in order to retain their hold. The digits that do not
-make any individual movements have lost the power to do
-<span class='pageno' id='Page_230'>230</span>so, and have become fused, and can only be bent in and
-straightened out. The thighs, being bent out to clasp the
-larger branches, have caused the pelvis to widen, and, in consequence,
-the cotyloid cavities have become directed backward.
-Many of the bones of the skeleton have become
-fused, as a result of the immobility of the animal.</p>
-
-<p class='c010'>Lamarck says, that “Nature, in producing, successively, all
-the species of animals, beginning with the most imperfect, or
-the most simple, and terminating with the most perfect, has
-gradually complicated their organization. These animals
-becoming scattered throughout the habitable regions of the
-globe each species has received from the influences of its
-surroundings its present habits, and the modifications of the
-parts the use of which we recognize.”</p>
-
-<p class='c010'>Such are Lamarck’s views and a fairly complete statement
-of the facts from which he draws his conclusions. His
-illustrations appear naïve, and often not a little ludicrous,
-but it must be admitted that, despite their absurdities, his
-theory appears in some cases to account wonderfully well for
-the facts. The long legs of wading birds, the long neck and
-disproportionately long fore-legs of the giraffe, the structure
-of the sloth, and particularly the degeneration of the eyes of
-animals living in the dark, seem to find a simple explanation
-in the principle of the inheritance of acquired characters.
-But the crucial point of the entire theory is passed over in
-silence, or rather is taken for granted by Lamarck, namely, the
-inheritance in the offspring of the characters acquired through
-use or disuse in the parent. He does not even discuss this
-topic, but in several places states unreservedly that the increase
-or decrease of a part reappears in the next generation.
-It is here that Lamarck’s theory has been attacked in more
-modern times, for as soon as experimental proof was demanded
-to show that the results of use or of disuse of an
-organ is inherited, no such proof was forthcoming. Yet
-the theory is one that has the great merit of being capable of
-<span class='pageno' id='Page_231'>231</span>experimental test, and it is astonishing to find that, with
-the immense amount that has been written by his followers,
-so few attempts have been made to give the theory a thorough
-test. The few results that have been obtained are not, however,
-favorable to the theory, but almost the only attempts at
-experiment that have been made in this direction have been
-those of mutilating certain parts; and were it not for popular
-belief to the effect that such mutilations are inherited,
-one would least expect to get evidence for or against the
-theory in this direction. Lamarck himself believed that the
-changes were slowly acquired, and I think modern Lamarckians
-are justified in claiming that the validity of the theory
-can only be tested by experiments in which the organism is
-subjected to influences extending over a considerable period,
-although Lamarck appears to have believed that the first
-results may appear quite soon. Before expressing any
-opinion in regard to the probability of the theory, let us
-examine what the followers of Lamarck have contributed in
-the way of evidence to the theory, rather than the applications
-that they have made of the theory. We shall also find
-it profitable to consider some of the modern criticism, to which
-the theory has been subjected.</p>
-
-<p class='c010'>Despite the contempt with which Darwin referred to
-Lamarck’s theory, he himself, as we have seen, often made
-use of the principle of the inheritance of acquired characters,
-and even employed the same illustrations cited by Lamarck.
-Darwin seems to have misunderstood Lamarck’s view, and
-to have accepted the current opinion that Lamarck supposed
-an animal acquired a new organ by desiring or needing
-it. Darwin says, “Heaven forefend me from Lamarck’s
-nonsense of a tendency to progressive adaptation from
-the slow willing of the animals.” Darwin speaks of Lamarck
-as stating that animals will that the egg shall be
-a particular form so as to become attached to particular
-objects. Lamarck’s latest biographer, Packard, says he is
-<span class='pageno' id='Page_232'>232</span>unable to find any statements of this sort in Lamarck’s
-writings.</p>
-
-<p class='c010'>The following cases that Darwin tried to explain through
-the inheritance of acquired characters are exactly like those
-to which Lamarck applied his theory. The bones of the
-wing of the domestic duck weigh less than those of the wild
-duck, and the bones of the leg more. Darwin believes this
-is due to the effects of the inheritance of acquired characters.
-The drooping ears of many domestic mammals are also
-explained by him as a result of disuse—“the animals being
-seldom much alarmed.” In speaking of the male of the
-beetle, <i>Onites apelles</i>, Darwin quotes Kirby to the effect that
-the tarsi are so habitually lost that the species has been
-described without this part of the foot. In the sacred beetle
-of Egypt the tarsus is totally absent. Hence he concludes
-that the absence of tarsi in the sacred beetle, and the rudimentary
-condition of the tarsus in others, is probably the
-result of disuse, rather than a case of inheritance of a mutilation.
-Darwin grants that “the evidence that accidental
-mutilations can be inherited is at present not decisive, but
-the remarkable case observed by Brown-Séquard in guinea-pigs
-of the inherited effects of operations should make us
-cautious in denying this tendency.”</p>
-
-<p class='c010'>The wingless condition of several insects inhabiting oceanic
-islands has come about, Darwin thinks, through disuse. The
-ostrich also, owing to its increase in size, made less use of its
-wings and more use of its legs, with the result that its wings
-degenerated and its legs got stronger. The rudimentary
-condition of the eyes of the mole is the result of disuse,
-“aided perhaps by natural selection.” Many of the animals
-inhabiting the caves of Kentucky and of Carniola
-are blind, and this is ascribed to disuse. “As it is difficult
-to imagine that the eyes, though useless, could be in
-any way injurious to animals living in darkness, their loss
-may be attributed to disuse.” The long neck of the giraffe
-<span class='pageno' id='Page_233'>233</span>Darwin attributes partly to natural selection and partly
-to use.</p>
-
-<p class='c010'>These references will suffice to show that Darwin is in full
-accord with the main argument of Lamarck. In fact, the
-curious hypothesis of pangenesis that Darwin advanced was
-invented partly to account for the inheritance of acquired
-characters. Despite the hesitancy that Darwin himself felt
-in advancing this view, and contrary to Huxley’s advice, he
-at last published his provisional hypothesis of pangenesis in
-the twenty-seventh chapter of his “Animals and Plants
-under Domestication.”</p>
-<h3 class='c014'><span class='sc'>Darwin’s Hypothesis of Pangenesis</span></h3>
-
-<p class='c015'>The study of bud variation, of the various forms of inheritance,
-and of reproduction and of the causes of variation, led
-him, Darwin says, to the belief that these subjects stand in
-some sort of relation to each other. He says: “I have been
-led, or rather forced, to form a view which to a certain extent
-connects these facts by a tangible method. Every one would
-wish to explain to himself, even in an imperfect manner, how
-it is possible for a character possessed by some remote
-ancestor suddenly to reappear in the offspring; how the
-effects of increased or decreased use of a limb can be transmitted
-to the child; how the male sexual element can act not
-solely on the ovules, but occasionally on the mother form;
-how a hybrid can be produced by the union of the cellular
-tissue of two plants independently of the organs of generation;
-how a limb can be reproduced on the exact line of
-amputation, with neither too much nor too little added; how
-the same organism may be produced by such widely different
-processes, as budding and true seminal generation; and,
-lastly, how of two allied forms, one passes in the course of
-its development through the most complex metamorphoses,
-and the other does not do so, though when mature both are
-<span class='pageno' id='Page_234'>234</span>alike in every detail of structure. I am aware that my view
-is merely a provisional hypothesis or speculation; but, until
-a better one be advanced, it will serve to bring together a
-multitude of facts which are at present left disconnected by
-any efficient cause.”</p>
-
-<p class='c010'>In presenting the hypothesis of pangenesis Darwin begins
-by enumerating the different kinds of sexual and asexual
-processes of reproduction, for which he hopes to offer a
-provisional explanation. Here we find mentioned various
-methods of budding and self-division, regeneration, parthenogenesis,
-sexual reproduction, and the inheritance of acquired
-characters. It is with the last only that we are here chiefly
-concerned; in fact, the need of an hypothesis <i>of this sort</i> to
-explain the other kinds of inheritance is by no means evident.
-There are, however, two other phenomena, besides that of the
-supposed inheritance of acquired characters, to which the
-hypothesis of pangenesis might appear to apply specially,
-namely, the effect of foreign pollen on the tissues of the
-mother plant, and the supposed influence of the union with
-the first male on the subsequent young (telegony). It is,
-however, far from being shown that any influence of this
-latter kind really occurs, despite the fact that it is generally
-believed in by breeders.</p>
-
-<p class='c010'>It is important to observe that Darwin proposes to explain
-on the hypothesis of pangenesis, not only the inheritance of
-characters acquired through use, but also the decrease of
-structures through disuse; and this applies, not only to the
-structure, but to function as well, as when the intelligence of
-the dog is explained through his association with man, and
-the tameness of the domestic rabbits through their long confinement.
-In the following quotation these points are referred
-to: “How can the use or disuse of a particular limb or of the
-brain affect a small aggregate of reproductive cells, seated in
-a distant part of the body, in such a manner that the being
-developed from these cells inherits the characters of either
-<span class='pageno' id='Page_235'>235</span>one or both parents? Even an imperfect answer to this
-question would be satisfactory.”</p>
-
-<p class='c010'>Coming now to the theory, we find that it consists of one
-chief assumption and several minor ones. “It is universally
-admitted that the cells or units of the body increase by self-division
-or proliferation, retaining the same nature, and that
-they ultimately become converted into the various tissues and
-substances of the body. But besides this means of increase
-I assume that the units throw off minute granules which are
-dispersed throughout the whole system; that these, when
-supplied with proper nutriment, multiply by self-division, and
-are ultimately developed into units like those from which
-they were originally derived. These granules may be called
-gemmules. They are collected from all parts of the system
-to constitute the sexual elements, and their development in
-the next generation forms a new being; but they are likewise
-capable of transmission in a dormant state to future generations,
-and may then be developed.... Gemmules are supposed
-to be thrown off by every unit, not only during the
-adult state, but during each stage of development of every
-organism; but not necessarily during the continued existence
-of the same unit. Lastly, I assume that the gemmules in
-their dormant state have a mutual affinity for each other,
-leading to their aggregation into buds, or into the sexual
-elements. Hence, it is not the reproductive organs, or buds,
-which generate new organisms, but the units of which each
-individual is composed. These assumptions constitute the
-provisional hypothesis which I have called Pangenesis.”</p>
-
-<p class='c010'>It will be noticed that the first assumption is that the cells
-throw off minute gemmules or granules. The second assumption
-is that these are collected in the reproductive organs, or
-in buds, or in regenerating parts; the third assumption is
-that the gemmules may lie dormant through several generations;
-the fourth, that the development of the reproductive
-cells is not so much the development of the cell itself, but of
-<span class='pageno' id='Page_236'>236</span>the gemmules that have collected in it. The fifth assumption
-is that the gemmules are thrown off at all stages of development;
-the sixth, that in their dormant state they have a
-mutual affinity for each other; the seventh, that there may be
-a sort of continual competition in the germ-cells between the
-original gemmules and the new ones, and, according to which
-win, the old or the new form develops. Thus we see on
-closer analysis that the pangenesis hypothesis is made up of
-a goodly number of different assumptions. At least half a
-dozen imaginary properties are ascribed to the imaginary
-gemmules, and these attributes are all essential to the
-working of the hypothesis.</p>
-
-<p class='c010'>Some of the more obvious objections to the hypothesis
-have been stated by Darwin himself. Such, for instance, as
-our ignorance at what stage in their history the body-cells are
-capable of throwing off gemmules, and whether they collect
-only at certain times in the reproductive organs, as the
-increased flow of blood to these organs at certain seasons
-might seem to indicate. Nor have we any evidence that they
-are carried by the blood at all. The experiment of Galton, of
-transfusing the blood of one animal into another, and finding
-that this produced no effect on the young that were born
-later, might be interpreted to mean that gemmules are not transported
-by the blood; but this kind of experiment is inconclusive,
-especially in the light of recent results on the effect of
-the blood of one animal on that of another.</p>
-
-<p class='c010'>A part of the evidence on which Darwin relied to support
-his theory has been shown to be incorrect by later work.
-Thus the assumption that more than a single pollen grain, or
-more than one spermatozoon, is necessary in some cases for
-fertilization, is certainly wrong. In most cases, in fact, the
-entrance of more than one spermatozoon into the egg is disastrous
-to the development. The cases referred to by Darwin
-can probably be explained by the difficulty that some of
-the pollen grains, or spermatozoa, may have in penetrating
-<span class='pageno' id='Page_237'>237</span>the egg, or to the immaturity or impotence of some of the
-male germ-cells, and not to the need of more than one to
-accomplish the true fertilization.</p>
-
-<p class='c010'>Darwin’s idea that the small number of gemmules in the
-unfertilized egg may account for the lack of power of such
-eggs to develop until they are fertilized, has been shown to
-be incorrect by recent results in experimental embryology.
-We now know that many different kinds of stimuli have the
-power to start the development of the egg. Moreover, we
-also know that if a single spermatozoon is supplied with a
-piece of egg-protoplasm without a nucleus, it suffices to cause
-this piece of protoplasm to develop.</p>
-
-<p class='c010'>In the case of regeneration, which Darwin also tries to
-explain on the pangenesis hypothesis, we find that there is
-no need at all for an hypothesis of this sort; and there are a
-number of facts in connection with regeneration that are not
-in harmony with the hypothesis. For instance, when a part is
-cut off, the same part is regenerated; but under these circumstances
-it cannot be imagined that the part removed supplies
-the gemmules for the new part. Darwin tries to meet this
-objection by the assumption that every part of the body contains
-gemmules from every other part. But it has been
-shown that if a limb of the newt is completely extirpated, a
-new limb does not regenerate; and there is no reason why it
-should not do so on Darwin’s assumption that germs of the
-limb exist throughout the body.</p>
-
-<p class='c010'>The best-authenticated cases of the influence of the male
-on the tissues of the female are those in plants, where one
-species, or variety, is fertilized by another. Thus, if the
-orange is fertilized by the pollen of the lemon, the fruit may
-have the color and flavor of the lemon. Now the fruit is a
-product of the tissues of the ovary of the female, and not a
-part of the seedling that develops in the fruit from the cross-fertilized
-egg-cell. Analogous cases are recorded for the
-bean, whose pods may have their color influenced by fertilizing
-<span class='pageno' id='Page_238'>238</span>the flower with pollen of another variety having pods
-of a different color. In these cases we do not know whether
-the color of the fruit is influenced directly by the foreign
-pollen, or whether the influence is through the embryo that
-develops from the egg-cell. The action may appear to be the
-same, however, in either case; but because it seems probable
-here that there is some sort of influence of one tissue on
-another, let us not too readily conclude that this is brought
-about through any such imaginary bodies as gemmules. It
-may be directly caused, for instance, by some chemical substance
-produced in the young hybrid plant. If this is the
-case, the result would not be different in kind from that of
-certain flowers whose color may be influenced by certain
-chemical substances in the soil.</p>
-
-<p class='c010'>In the cases amongst animals, where the maternal tissues are
-believed to be influenced by a previous union with the male, as
-in the oft-cited case of Lord Morton’s mare, a reëxamination of
-the evidence by Ewart has shown that the case is not demonstrated,
-and not even probable. Several years ago I tried to
-test this view in the case of mice. A white mouse was first
-bred to a dark male house-mouse, and the next time to a
-white mouse, but none of the offspring from the second union
-showed any trace of black. If the spermatozoa of the dark
-mouse are hypodermically injected into the body-cavity of the
-female, the subsequent young from a white male show no evidence
-that the male cells have had any influence on the ovary.</p>
-
-<p class='c010'>The following facts, spoken of by Darwin himself, are
-not in favor of his hypothesis of pangenesis: “But it
-appears at first sight a fatal objection to our hypothesis
-that a part of an organ may be removed during several
-successive generations, and if the operation be not followed
-by disease, the lost part reappears in the offspring. Dogs
-and horses formerly had their tails docked during many generations
-without any inherited effect; although, as we have
-seen, there is some reason to believe that the tailless conditions
-<span class='pageno' id='Page_239'>239</span>of certain sheep-dogs is due to such inheritance.” The
-answer that Darwin gives is that the gemmules themselves,
-that were once derived from the part, are still present in
-other parts of the body, and it is from these that the organs
-in the next generation may be derived. But Darwin fails to
-point out that, if this were the case, it must also be true for
-those cases in which an organ is no longer used. Its decrease
-in size in successive generations cannot be due to its disuse,
-for the rest of the body would supply the necessary gemmules
-to keep it at its full state of development. Thus, in trying to
-meet an obvious objection to his hypothesis, Darwin brings forward
-a new view that is fatal to another part of his hypothesis.</p>
-
-<p class='c010'>The following cases, also given by Darwin, are admitted by
-him to be inexplicable on his hypothesis: “With respect to
-variations due to reversion, there is a similar difference between
-plants propagated from buds and seeds. Many varieties
-can be propagated securely by buds, but generally or
-invariably revert to their parent forms by seed. So, also,
-hybridized plants can be multiplied to any extent by buds,
-but are continually liable to reversion by seed,—that is, to
-the loss of their hybrid or intermediate character. I can
-offer no satisfactory explanation of these facts. Plants with
-variegated leaves, phloxes with striped flowers, barberries
-with seedless fruit, can all be securely propagated by buds
-taken from the stem or branches; but buds from the roots of
-these plants almost invariably lose their character and revert
-to their former condition. This latter fact is also inexplicable,
-unless buds developed from the roots are as distinct from
-those on the stem, as is one bud on the stem from another,
-and we know that these latter behave like independent organisms.”
-As Darwin here states, these facts appear to be
-directly contradictory to his hypothesis, and he makes no
-effort to account for them.</p>
-
-<p class='c010'>The entire question of the possibility of the inheritance of
-acquired characters is itself at present far from being on a
-<span class='pageno' id='Page_240'>240</span>satisfactory basis, as we shall try to show; and Darwin’s
-attempt at an explanation, in his chapter on pangenesis, does
-not put the matter in a much more satisfactory condition.</p>
-<h3 class='c014'><span class='sc'>The Neo-Lamarckian School</span></h3>
-
-<p class='c015'>Let us now turn our attention to a school that has grown
-up in modern times, the members of which call themselves
-Neo-Lamarckians. Let us see if they have supplied the
-essential evidence that is required to establish the Lamarckian
-view, namely, that characters acquired by the individual
-are transmitted to the offspring.</p>
-
-<p class='c010'>Lamarck’s views were adopted by Herbert Spencer, and
-play an important rôle in his “Principles of Biology” (1866-1871),
-and even a more conspicuous part in his later writings.
-In the former he cites, amongst other cases, that of “a puppy
-taken from its mother at six weeks old who, although never
-taught ‘to beg’ (an accomplishment his mother had been
-taught), spontaneously took to begging for everything he
-wanted when about seven or eight months old.” If tricks
-like this are inheritable is it not surprising that more puppies
-do not stand on their hind-legs?</p>
-
-<p class='c010'>The larger hands of the laboring classes in England are
-supposed to be inherited by their children, and the smaller
-hands of the leisure classes are supposed to be the result of
-the disuse of the hands by their ancestors; but even if these
-statements in regard to size are true, there are many other
-conceivable causes that may have led to this result.</p>
-
-<p class='c010'>Short-sightedness appears more often, it is said, in those
-classes of society that make most use of their eyes in reading
-and in writing; but if we ask for experimental evidence to
-show that this is due to inheritance, and not due to the children
-spoiling their eyes at school, there is none forthcoming.
-The problem is by no means so simple as the uninitiated may
-be led to believe.</p>
-
-<p class='c010'><span class='pageno' id='Page_241'>241</span>Spencer thinks that “some of the best illustrations of
-functional heredity are furnished by mental characteristics.”
-He cites the musical faculty as one that could not have been
-acquired by natural selection, and must have arisen through
-the inheritance of acquired modifications. The explanation
-offered is “that the habitual association of certain cadences
-of speech with certain emotions has clearly established in
-the race an organized and inherited connection between
-such cadences and such emotions, ... and that by the continued
-hearing and practice of melody there has been gained
-and transmitted an increasing musical sensibility.” But a
-statement that the results have been acquired in this way
-does not supply the proof which the theory is in need of;
-neither does it follow that, because the results cannot be
-explained by the theory of natural selection, therefore, they
-must be explained by the Lamarckian theory.</p>
-
-<p class='c010'>The clearest proofs that Spencer finds of the inheritance
-of acquired characters are in the well-known experiments of
-Brown-Séquard. These experiments will be more fully discussed
-below. Amongst the other morbid processes that
-Spencer thinks furnish evidence in favor of this view, are
-cases of a tendency to gout, the occurrence of mental tricks,
-musical prodigies, liability to consumption, in all of which
-cases the fundamental distinction between the inheritance of
-an acquired character and the inherited tendency toward a
-particular malady is totally ignored.</p>
-
-<p class='c010'>Twenty-seven years later (in 1893) Spencer took up the
-open challenge of the anti-Lamarckian writers, and by bringing
-forward a number of new <i>arguments</i> attempted to reinstate
-the principle of the inheritance of acquired characters.
-His first illustration is drawn from the distribution of the
-sense of touch in different parts of our bodies. Weber’s experiments
-have shown that if the sharp points of a pair of
-compasses are applied to the tips of the forefingers, the sensation
-of two separate points is given when the points are
-<span class='pageno' id='Page_242'>242</span>only one-twelfth of an inch apart, and if the points are moved
-nearer together, they give the sensation of only one point.
-The inner surfaces of the second joints of the fingers can
-only distinguish two points when they are one-sixth of an
-inch apart. The innermost joints are less discriminating,
-and are about equal in the power of discrimination to the tip
-of the nose. The end of the big toe, the palm of the hand,
-and the cheek discriminate only about one-fifth as well as do
-the tips of the fingers. The back of the hand and the top
-of the head distinguish only about one-fifteenth as well as
-the finger-tips. The front of the thigh, near the knee, is
-somewhat less sensitive than the back of the hand. On the
-breast the points of the compasses must be separated by more
-than an inch and a half in order to give two sensations. In
-the middle of the back the points must be separated by two
-and a half inches, or more, in order to give two separate
-impressions.</p>
-
-<p class='c010'>What is the meaning of these differences, Spencer asks.
-If natural selection has brought about the result, then it must
-be shown that “these degrees of endowment have advantaged
-the possessor to such an extent that not infrequently
-life has been directly or indirectly preserved by it.” He
-asks if this, or anything approaching this, result could have
-occurred.</p>
-
-<p class='c010'>That the superior perceptiveness of the forefinger-tip
-might have arisen through selection is admitted by Spencer,
-but how could this have been the case, he asks, for the middle
-of the back, and for the face? The tip of the nose has
-three times more power of discrimination than the lower
-part of the forehead. Why should the front of the thigh
-near the knee be twice as perceptive as in the middle of
-the thigh; and why should the middle of the back and of
-the neck and the middle of the forearm and of the thigh
-stand at such low levels? Is it possible, Spencer asks again,
-that natural selection has determined these relations, and
-<span class='pageno' id='Page_243'>243</span>if not, how can they be explained? His reply is that the
-differences can all be accounted for on the theory of the
-inheritance of use, for it is evident that “these gradations
-in tactile perceptiveness correspond with the gradations in
-the tactual exercise of the parts.” Except from contact
-with the clothing the body receives hardly any touch sensations
-from outside, and this accounts for its small power
-of discrimination. The greater sensitiveness of the chest
-and abdomen, as compared with the back, is due to these
-regions being more frequently touched by the hands, and
-is also owing to inheritance from more remote ancestors,
-in which the lower surface of the body was more likely to
-have come in contact with foreign objects than was the back.
-The middle of the forearm and of the thigh are also less exposed
-than the knee and the hand, and have correspondingly
-the power of tactile discrimination less well developed.</p>
-
-<p class='c010'>Weber showed that the tip of the tongue is more sensitive
-than any other part of the body, for it can distinguish between
-two points only one twenty-fourth of an inch apart.
-Obviously, Spencer says, natural selection cannot account
-for such extreme delicacy of touch, because, even if it were
-useful for the tongue to distinguish objects by touch, this
-power could never be of vital importance to the animal. It
-cannot even be supposed that such delicacy is necessary for
-the power of speech.</p>
-
-<p class='c010'>The sensitiveness of the tongue can be accounted for,
-however, Spencer claims, as the result of the constant use
-of the tongue in exploring the cavity of the mouth. It is
-continually moving about, and touching now one part, and
-now another, of the mouth cavity. “No advantage is gained.
-It is simply that the tongue’s position renders perpetual exploration
-almost inevitable.” No other explanation of the
-facts seemed possible to Spencer.</p>
-
-<p class='c010'>Two questions will at once suggest themselves. First, can
-it be shown that the sensitiveness to touch in various parts of
-<span class='pageno' id='Page_244'>244</span>the body is the result of individual experience? Have we
-learned to discriminate in those parts of the body that are
-most often brought into contact with surrounding objects?
-Even the power of discrimination in the tips of the fingers
-can be improved, as Spencer himself has shown, in the case
-of the blind, and of skilled compositors. Can we account in
-this way for the power of discrimination in various parts of
-the body? In other words, if, beginning in infancy, the middle
-of the back constantly came into contact with surrounding
-objects, would this region become as sensitive as the tips of
-the fingers? The experiment has not, of course, been carried
-out, but it is not probable that it would succeed. I venture
-this opinion on the ground of the relative number of the
-nerves and of the organs of touch on the back, as compared
-with those of the finger-tips. But, it will be asked, will not
-the number of the sense-organs become greater if a part is
-continually used by the individual? It is improbable that
-much improvement could be brought about in this way. The
-improvement that takes place through experience is probably
-not so much the result of the development of more sense-organs,
-as of better discrimination in the sensation, because
-the increased power can be very quickly acquired.</p>
-
-<p class='c010'>An examination of the relative abundance of touch-spots in
-the skin shows that they are much more numerous in regions
-of greater sensitiveness. The following table, taken from
-Sherrington’s account of sense-organs in Schaefer’s “Textbook
-of Physiology,” gives the smallest distance that two
-points, simultaneously applied, can be recognized as such (and
-not simply as one impression) in different regions.</p>
-<div class='fs80'>
-
-<table class='table2' summary=''>
-<colgroup>
-<col width='81%' />
-<col width='18%' />
-</colgroup>
-  <tr>
-    <td class='c011'>&nbsp;</td>
-    <td class='c012'>Mm.</td>
-  </tr>
-  <tr>
-    <td class='c011'>Tip of tongue</td>
-    <td class='c012'>1.1</td>
-  </tr>
-  <tr>
-    <td class='c011'>Volar surface of ungual phalanx of finger</td>
-    <td class='c012'>2.3</td>
-  </tr>
-  <tr>
-    <td class='c011'>Red surface of lip</td>
-    <td class='c012'>4.5</td>
-  </tr>
-  <tr>
-    <td class='c011'>Volar face of second phalanx</td>
-    <td class='c012'>4.5</td>
-  </tr>
-  <tr>
-    <td class='c011'>Dorsal face of third phalanx</td>
-    <td class='c012'>6.8</td>
-  </tr>
-  <tr>
-    <td class='c011'>Side of tongue</td>
-    <td class='c012'>9.0</td>
-  </tr>
-  <tr>
-    <td class='c011'>Third line of tongue, 27 mm. from tip</td>
-    <td class='c012'>9.0</td>
-  </tr>
-  <tr>
-    <td class='c011'><span class='pageno' id='Page_245'>245</span>Plantar face of ungual phalanx of first toe</td>
-    <td class='c012'>11.3</td>
-  </tr>
-  <tr>
-    <td class='c011'>Palm</td>
-    <td class='c012'>11.3</td>
-  </tr>
-  <tr>
-    <td class='c011'>Back of second phalanx of finger</td>
-    <td class='c012'>11.3</td>
-  </tr>
-  <tr>
-    <td class='c011'>Forehead</td>
-    <td class='c012'>22.6</td>
-  </tr>
-  <tr>
-    <td class='c011'>Back of ankle</td>
-    <td class='c012'>22.6</td>
-  </tr>
-  <tr>
-    <td class='c011'>Back of hand</td>
-    <td class='c012'>31.6</td>
-  </tr>
-  <tr>
-    <td class='c011'>Forearm, leg</td>
-    <td class='c012'>40.6</td>
-  </tr>
-  <tr>
-    <td class='c011'>Dorsum of foot</td>
-    <td class='c012'>40.6</td>
-  </tr>
-  <tr>
-    <td class='c011'>Outer sternum</td>
-    <td class='c012'>45.1</td>
-  </tr>
-  <tr>
-    <td class='c011'>Back of neck</td>
-    <td class='c012'>54.1</td>
-  </tr>
-  <tr>
-    <td class='c011'>Middle of back</td>
-    <td class='c012'>67.1</td>
-  </tr>
-  <tr>
-    <td class='c011'>Upper arm, thigh</td>
-    <td class='c012'>67.1</td>
-  </tr>
-</table>
-
-</div>
-<p class='c009'>The great difference in the sensitiveness of the skin in
-the different regions is very striking, and if, as seems probable,
-about the same proportionate difference is found at birth, then
-the degree of sensibility of the different regions is inborn,
-and is not the result of each individual experience. Until it
-can be shown that more of the sense-organs develop in any
-special part, as the result of the increased use of the part, we
-have no real basis on which to establish, even as probable,
-the Lamarckian view.</p>
-
-<p class='c010'>But, after all, is the distribution of the sense-organs exactly
-that which we should expect on the Lamarckian theory?
-Has not Spencer taken too much for granted in this direction?
-The lower part of the forearm (represented by 15) we
-should expect to be more sensitive than the protected surface
-of the eyelid (11.3), but this is not the case. The forehead
-(22.6) is much less sensitive than the forearm, and only half
-as sensitive as the eyelid. The knee (36.1) is still less sensitive
-than any of these other parts, and this does not in the
-least accord with the theory, since in its constant moving
-forward it must be continually coming into contact with foreign
-bodies. The fact that the back is as insensitive as the upper
-arm (67.7) can hardly be accredited in favor of the theory.
-The great difference between the lower third of the forearm
-on the ulnar surface (15) and the upper arm (67.7) seems
-<span class='pageno' id='Page_246'>246</span>out of all proportion to what we should expect on the theory.
-And is it not a little odd that the end of the nose should be
-so highly sensitive?</p>
-
-<p class='c010'>There is another point that we cannot afford to neglect in
-this connection. It is known that in addition to touch-spots
-there are warm and cold spots in the skin, which produce,
-when touched, the sensation of warmth, or of cold, respectively,
-and not the sensation of touch. The degree of
-sensitiveness of different regions of the body throws an
-interesting side-light on Spencer’s argument.</p>
-
-<p class='c010'>The warm spots are much fewer than the cold spots. The
-spots are arranged in short lines radiating from centres
-which coincide with hairs. The number of these spots
-varies a good deal, even in the same region of the skin. If
-the sensitiveness of the skin is tested, the following results
-will be obtained. The list includes twelve grades of sensitiveness,
-beginning with the places giving the lowest maximum
-of intensity. About one hundred square areas were tested
-in each region.</p>
-
-<div class='nf-center-c0'>
-<div class='nf-center c022'>
-    <div>COLD SENSATIONS</div>
-  </div>
-</div>
-
-<div class='lg-container-l c023'>
-  <div class='linegroup'>
-    <div class='group'>
-      <div class='line'>1. Tips of fingers and toes, malleoli, ankle.</div>
-      <div class='line'>2. Other parts of digits, tip of nose, olecranon.</div>
-      <div class='line'>3. Glabella, chin, palm, gums.</div>
-      <div class='line'>4. Occiput, patella, wrist.</div>
-      <div class='line'>5. Clavicle, neck, forehead, tongue.</div>
-      <div class='line'>6. Buttocks, upper eyelid.</div>
-      <div class='line'>7. Lower eyelid, popliteal space, sole, cheek.</div>
-      <div class='line'>8. Inner aspect of thigh, arm above elbow.</div>
-      <div class='line'>9. The intercostal spaces along axillary line.</div>
-      <div class='line'>10. Mammary areola.</div>
-      <div class='line'>11. Nipple, flank.</div>
-      <div class='line'>12. Certain areas of the loins and abdomen.</div>
-    </div>
-  </div>
-</div>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div>WARMTH SENSATIONS</div>
-  </div>
-</div>
-
-<div class='lg-container-l c023'>
-  <div class='linegroup'>
-    <div class='group'>
-      <div class='line'>0. Lower gum, mucosa of cheek, cornea.</div>
-      <div class='line'>1. Tips of fingers and toes, cavity of mouth, conjunctiva, and patella.</div>
-      <div class='line'><span class='pageno' id='Page_247'>247</span>2. Remaining surface of digits, middle of forehead, olecranon.</div>
-      <div class='line'>3. Glabella, chin, clavicle.</div>
-      <div class='line'>4. Palm, buttock, popliteal space.</div>
-      <div class='line'>5. Neck.</div>
-      <div class='line'>6. Back.</div>
-      <div class='line'>7. Lower eyelid, cheek.</div>
-      <div class='line'>8. Nipple, loin.</div>
-    </div>
-  </div>
-</div>
-
-<p class='c009'>These two tables show the great differences in the range
-of sensitiveness to cold and to warmth in different parts of
-the body. I doubt if any one will attempt to show that
-these differences of range of sensation can be accounted for
-either by natural selection or by the Lamarckian hypothesis.</p>
-
-<p class='c010'>Of course, it does not necessarily follow that, because this
-is true for the warm and cold spots, that it must also be true
-for the tactile organs; but I think that the fact of such a great
-difference in the responsiveness to cold and to warmth in
-different parts of the body should put us on our guard against
-a too ready acceptation of Spencer’s argument. More especially
-is this seen to be necessary, when, as has been shown
-above, the distribution of the touch-organs themselves by no
-means closely corresponds to what we should expect, if they
-have developed in response to contact, as Spencer maintains.</p>
-
-<p class='c010'>The other main argument advanced by Spencer to fortify
-the theory of the inheritance of acquired characters, and at
-the same time to show the inadequacy of the theory of natural
-selection, is based on the idea of what he calls the “coöperation
-of the parts” that is required in order to carry out
-any special act. Spencer contends that “the relative powers
-of coöperative parts cannot be adjusted solely by the survival
-of the fittest, and especially where the parts are numerous
-and the coöperation complex.”</p>
-
-<p class='c010'>Spencer illustrates his point by the case of the extinct
-Irish elk, whose immensely developed horns weighed over
-a hundredweight. The horns, together with the massive
-skull, could not have been supported by the outstretched
-<span class='pageno' id='Page_248'>248</span>neck without many and great changes of the muscles and
-bones of the neck and of the fore-part of the body. Unless,
-for instance, the fore-legs had been also strengthened, there
-would be failure in fighting and in locomotion. Since “we
-cannot assume spontaneous increase of all these parts proportionate
-to the additional strains, we cannot suppose them
-to increase by variations one at once, without supposing the
-creature to be disadvantaged by the weight and nutrition of
-the parts that were for a time useless,—parts, moreover,
-which would revert to their original sizes before the other
-needful variations occurred.”</p>
-
-<p class='c010'>The answer made to this argument was that coördinating
-parts vary together. In reply to which Spencer points to
-the following cases, which show that this is not so: The
-blind crayfish in the Kentucky caves have lost their eyes,
-but not the stalks that carry them. Again, the normal
-relation between the length of tongue and of beak in some
-varieties of pigeons is lost. The greater decrease in the
-jaws in some species of pet dogs than of the number of
-their teeth has caused the teeth to become crowded.<a id='r18' /><a href='#f18' class='c017'><sup>[18]</sup></a> “I
-then argued that if coöperative parts, small in number,
-and so closely associated as these are, do not vary together,
-it is unwarrantable to allege that coöperative parts, which are
-very numerous and remote from one another, vary together.”
-Spencer puts himself here into the position of seriously maintaining
-that, because some coöperative parts do not vary together,
-therefore no coöperative parts have ever done so, and
-he has taken this position in the face of some well-known
-cases in which certain parts have been found to vary together.</p>
-
-<div class='footnote c018' id='f18'>
-<p class='c019'><span class='label'><a href='#r18'>18</a>.&nbsp;&nbsp;</span>It is curious that Spencer does not see that this case is as much against his
-point as in favor of it, since the <i>unused</i> teeth did not also degenerate.</p>
-</div>
-
-<p class='c010'>In this same connection Spencer brings up the familiar
-<i>pièce de résistance</i> of the Lamarckian school, the giraffe. He
-recognizes that the chief traits in the structure of this animal
-are the result of natural selection, since its efforts to reach
-<span class='pageno' id='Page_249'>249</span>higher branches could not be the cause of the lengthening of
-the legs. But “the coadaptation of the parts, required to make
-the giraffe’s structure useful, is much greater than at first
-appears.” For example, the bones and the muscles of the
-hind-legs have been also altered, and Spencer argues that it
-is “impossible to believe” that all parts of the hind-quarters
-could have been coadapted to one another, and to all parts
-of the fore-quarters. A lack of coadaptation of a single muscle
-“would cause fatal results when high speed had to be maintained
-while escaping from an enemy.”</p>
-
-<p class='c010'>Spencer claims that, since 1886, when he first published
-this argument, nothing like an adequate response has been
-made; and I think he might have added that an adequate
-answer is not likely to be forthcoming, since nothing short
-of a demonstration of how the giraffe really evolved is
-likely to be considered as sufficient. Wallace’s reply, that
-the changes in question could have been brought about
-by natural selection, since similar changes have been brought
-about by artificial selection, is regarded as inadequate by
-Spencer, since it assumes a parallel which does not exist.
-Nevertheless, Wallace’s reply contains, in my opinion, the
-kernel of the explanation, in so far as it assumes that congenital
-variation<a id='r19' /><a href='#f19' class='c017'><sup>[19]</sup></a> may suffice to account for the origin of
-a form even as bizarre as that of the giraffe. The ancon
-ram and the turnspit dog were marked departures from the
-normal types, and yet their parts were sufficiently coördinated
-for them to carry out the usual modes of progression.
-It would not have been difficult, if we adopted Spencer’s
-mode of arguing, to show that these new forms could not
-possibly have arisen as the result of congenital variations.</p>
-
-<div class='footnote c018' id='f19'>
-<p class='c019'><span class='label'><a href='#r19'>19</a>.&nbsp;&nbsp;</span>Wallace assumes fluctuating variation to suffice, but in this I cannot agree
-with him.</p>
-</div>
-
-<p class='c010'>Again, it might be argued that the large, powerful dray-horse
-could not have arisen through a series of variations
-from the ordinary horse, because, even if variations in the
-<span class='pageno' id='Page_250'>250</span>right direction occurred in the fore-quarters, it is unlikely that
-similar variations would occur in the hind-quarters, etc. Yet
-the feat has been accomplished, and while it is difficult to
-prove that the inheritance of acquired characters has not had
-a hand in the process, it is improbable that this has been the
-case, but rather that artificial selection of some kind of variations
-has been the factor at work.</p>
-
-<p class='c010'>So long as the Lamarckian theory is supported by arguments
-like these, it can never hope to be established with anything
-more than a certain degree of probability. If it is
-correct, then its demonstration must come from experiment.
-This brings us to a consideration of the experimental evidence
-which has been supposed by some writers to give conclusive
-proof of the validity of the theory.</p>
-
-<p class='c010'>The best direct evidence in favor of the Lamarckian argument
-is that furnished by the experiments of Brown-Séquard.
-He found, as the result of injury to the nervous system of
-guinea-pigs, that epilepsy appeared in the adult animal, and
-that young born from these epileptic parents became also epileptic.
-Still more important was his discovery that, after an
-operation on the nerves, as a result of which certain organs,
-the ear or the leg, for instance, are affected, the same affection
-appears in the young born from such parents. These
-results of Brown-Séquard have been vouched for by two of
-his assistants, and his results in regard to the inheritance of
-epilepsy have been confirmed by Obersteiner, and by Luciani
-on dogs. Equally important is their later confirmation, as
-far as the main facts go, by Romanes.</p>
-
-<p class='c010'>Brown-Séquard gives the following summary of his results.
-I follow Romanes’ translation in his book on “Darwin and
-after Darwin,” where there is also given a careful analysis of
-Brown-Séquard’s results, as well as the outcome of the experiments
-of Romanes himself. The summary is as follows:—</p>
-
-<p class='c010'>1. “Appearance of epilepsy in animals born of parents which
-had been rendered epileptic by an injury to the spinal cord.</p>
-
-<p class='c010'><span class='pageno' id='Page_251'>251</span>2. Appearance of epilepsy also in animals born of parents
-which had been rendered epileptic by section of the sciatic
-nerve.</p>
-
-<p class='c010'>3. A change in the shape of the ear in animals born of
-parents in which such a change was the effect of a division
-of the cervical sympathetic nerve.</p>
-
-<p class='c010'>4. Partial closure of the eyelids in animals born of parents
-in which that state of the eyelids had been caused either by
-section of the cervical sympathetic nerve, or the removal of
-the superior cervical ganglion.</p>
-
-<p class='c010'>5. Exophthalmia in animals born of parents in which an
-injury to the restiform body had produced that protrusion of
-the eyeball. This interesting fact I have witnessed a good
-many times, and seen the transmission of the morbid state of
-the eye continue through four generations. In these animals
-modified by heredity, the two eyes generally protruded,
-although in the parents usually only one showed exophthalmia,
-the lesion having been made in most cases only on one of
-the corpora restiformia.</p>
-
-<p class='c010'>6. Hæmatoma and dry gangrene of the ears in animals
-born of parents in which these ear alterations had been caused
-by an injury to the restiform body near the nib of the calamus.</p>
-
-<p class='c010'>7. Absence of two toes out of the three of the hind-leg, and
-sometimes of the three, in animals whose parents had eaten
-up their hind-leg toes, which had become anæsthetic from a
-section of the sciatic nerve alone, or of that nerve and also of
-the crural. Sometimes, instead of complete absence of
-the toes, only a part of one or two or three was missing in the
-young, although in the parent not only the toes, but the
-whole foot was absent (partly eaten off, partly destroyed by
-inflammation, ulceration, or gangrene).</p>
-
-<p class='c010'>8. Appearance of various morbid states of the skin and
-hair of the neck and face in animals born of parents having
-had similar alterations in the same parts as effects of an
-injury to the sciatic nerve.”</p>
-
-<p class='c010'><span class='pageno' id='Page_252'>252</span>Romanes, who later went over the same ground, in part
-under the immediate direction of Brown-Séquard himself, has
-made some important observations in regard to these results,
-many of which he was able to confirm.</p>
-
-<p class='c010'>He did not repeat the experiment of cutting the cord, but
-he found that, to produce epilepsy, it was only necessary to
-cut the sciatic nerve. The “epileptiform habit” does not
-appear in the animal until some time after the operation; it
-lasts for some weeks or months, and then disappears. The
-attacks are not brought on spontaneously, but by “irritating
-a small area of the skin behind the ear on the same side of
-the body as that on which the sciatic nerve had been divided.”
-The attack lasts for only a few minutes, and during it the
-animal is convulsed and unconscious. Romanes thinks that
-the injury to the sciatic nerve, or to the spinal cord, produces
-some sort of a change in the cerebral centres, “and that it is
-this change—whatever it is, and in whatever part of the
-brain it takes place—which causes the remarkable phenomena
-in question.”</p>
-
-<p class='c010'>In regard to Brown-Séquard’s statements, made in the 3d
-and the 4th paragraphs, in respect to the results of the
-operation of cutting the cervical sympathetic, Romanes had
-not confirmed the results when his manuscript went to press;
-but soon afterward, after Romanes’ death, a note was printed
-in <i>Nature</i> by Dr. Hill, announcing that two guinea-pigs from
-Romanes’ experiment had been born, “both of which exhibited
-a well-marked droop of the upper eyelid. These
-guinea-pigs were the offspring of a male and female in both
-of which I had produced for Dr. Romanes, some months
-earlier, a droop of the left upper eyelid by division of the
-left cervical sympathetic nerve. This result is a corroboration
-of the series of Brown-Séquard experiments on the inheritance
-of acquired characters.”</p>
-
-<p class='c010'>Romanes states that he also found that injury to a particular
-spot of the restiform bodies is quickly followed by a
-<span class='pageno' id='Page_253'>253</span>protrusion of the eye on the same side, and further, that he
-had “also had many cases in which some of the progeny of
-parents thus affected have shown considerable protrusion
-of the eyeballs of both sides, and this seemingly abnormal
-protrusion has occasionally been transmitted to the next generation.
-Nevertheless, I am far from satisfied that this latter
-fact is anything more than an accidental coincidence.” This
-reservation is made on the ground that the protrusion in the
-young is never so great as in the parents, and also because
-there is amongst guinea-pigs a considerable amount of individual
-variation in the degree of prominence of the eyeballs.
-Romanes, while unwilling to deny that an “obviously
-abnormal amount of protrusion, due to the operation, may be
-inherited in lesser degree,” is also unwilling to affirm so
-important a conclusion on the basis of these experiments
-alone.</p>
-
-<p class='c010'>In regard to Brown-Séquard’s 6th statement, Romanes found
-after injury to the restiform body that hæmatoma and dry
-gangrene may supervene, either several weeks after the
-operation, or at any subsequent time, even many months
-afterward. The disease usually affects the upper parts of
-both ears, and may then gradually extend downward until
-nearly the whole ear is involved. “As regards the progeny
-of animals thus affected in some cases, but by no means in
-all, a similarly morbid state of the ears may arise apparently
-at any time in the life history of the individual. But I have
-observed that in cases where two or more individuals <i>of the
-same litter</i> develop this diseased condition, they usually do so
-at about the same time, even though this may be months after
-birth, and therefore after the animals are fully grown.” Moreover,
-the morbid process never extends so far in the young as
-it does in the parents, and “it almost always affects the middle
-third of the ear.” Several of the progeny from this first generation,
-which had apparently inherited the disease, but had not
-themselves been directly operated upon, showed a portion of
-<span class='pageno' id='Page_254'>254</span>the ear consumed apparently by the same disease. Romanes
-then gives the following significant analysis of this result.
-Since a different part of the ear of the progeny is affected,
-and also a “very much less quantity thereof,” it might seem
-that the result was due either to a mere coincidence, or to
-the transmission of microbes. But he goes on to say, that he
-fairly well excluded both of these possibilities, for, in the first
-place, he has never observed “the very peculiar process in
-the ears, or in any other parts of guinea-pigs which have
-neither themselves had the restiform bodies injured, nor
-been born of parents thus mutilated.” In regard to microbes,
-Romanes tried to infect the ears of normal guinea-pigs
-by first scarifying these parts, and then rubbing them
-with the diseased surfaces of the ears of affected guinea-pigs.
-In not a single case was the disease produced.</p>
-
-<p class='c010'>Romanes concludes that these “results in large measure
-corroborate the statements of Brown-Séquard; and it is only
-fair to add that he told me they were the results which he
-had himself obtained most frequently, but that he had also
-met with many cases where the diseased condition of the
-ears in parents affected the same parts in their progeny and
-also occurred in more equal degrees.”</p>
-
-<p class='c010'>We come now to the remarkable conclusion given in
-Brown-Séquard’s 7th statement, in regard to the absence of
-toes in animals whose parents had eaten off their own hind
-toes and even parts of their legs. Romanes got neuroses in
-the animals operated upon, and found that the toes might be
-eaten off; but none of the young showed any defect in these
-parts. Furthermore, Romanes repeated the same operation
-upon the descendants through six successive generations, so
-as to produce, if possible, a cumulative effect, but no inheritance
-of the mutilation was observed. “On the other hand,
-Brown-Séquard informed me that he had observed this inherited
-absence of toes only in about one or two per cent of
-cases.” It is possible, therefore, Romanes adds, that his
-<span class='pageno' id='Page_255'>255</span>own experiments were not sufficiently numerous to have
-obtained such cases.</p>
-
-<p class='c010'>In this connection I may give an account of some observations
-that I made while carrying out some experiments in
-telegony with mice. I found in one litter of mice that when
-the young came out of the nest they were tailless. The same
-thing happened again when the second litter was produced,
-but this time I made my observations sooner, and examined
-the young mice immediately after birth. I found that the
-mother had bitten off, and presumably eaten, the tails of her
-offspring at the time of birth. Had I been carrying on a
-series of experiments to see if, when the tails of the parents
-were cut off, the young inherit the defect, I might have been
-led into the error of supposing that I had found such a case
-in these mice. If this idiosyncrasy of the mother had reappeared
-in any of her descendants, the tails might have disappeared
-in succeeding generations. This perversion of the
-maternal instincts is not difficult to understand, when we
-recall that the female mouse bites off the navel-string of each
-of her young as they are born, and at the same time eats the
-afterbirth. Her instinct was carried further in this case, and
-the projecting tail was also removed.</p>
-
-<p class='c010'>Is it not possible that something of this sort took place in
-Brown-Séquard’s experiment? The fact that the adults had
-eaten off their own feet might be brought forward to indicate
-the possibility of a perverted instinct in this case also. At least
-my observation shows a possible source of error that must be
-guarded against in future work on this subject.</p>
-
-<p class='c010'>In regard to the 8th statement of Brown-Séquard, as
-to various morbid states of the skin, Romanes did not test
-this, because the facts which it alleges did not seem of a
-sufficiently definite character.</p>
-
-<p class='c010'>These experiments of Brown-Séquard, and of those who
-have repeated them, may appear to give a brilliant experimental
-confirmation of the Lamarckian position; yet I think,
-<span class='pageno' id='Page_256'>256</span>if I were a Lamarckian, I should feel very uncomfortable to
-have the best evidence in support of the theory come from
-this source, because there are a number of facts in the results
-that make them appear as though they might, after all, be the
-outcome of a transmitted disease, as Weismann claims, rather
-than the inheritance of an acquired character. Until we
-know more of the pathology of epilepsy, it may be well not
-to lay too great emphasis on these experiments. It should
-not be overlooked that during the long time that the embryo
-is nourished in the uterus of the mother, there is ample opportunity
-given for the transmission of material, or possibly
-even of bacteria. If it should prove true that epilepsy is due
-to some substance present in the nervous system, such substances
-could get there during the uterine life of the embryo.
-Even if this were the case, it may be claimed that it does
-not give an explanation of the local reappearance of the
-disease in the offspring. But here also we must be on our
-guard, for it is possible that only certain regions of the body
-are susceptible to a given disease; and it has by no means
-been shown that the local defect itself is inherited, but only
-the disease. Romanes insists that a very special operation is
-necessary to bring about certain forms of transmission.</p>
-
-<p class='c010'>It is well also to keep in mind the fact, that if this sort of
-effect is inherited, then we must be prepared to accept as a
-possibility that other kinds of injury to the parent may be
-transmitted to the offspring. It would be of great disadvantage
-to animals if they were to inherit the injuries that their
-parents have suffered in the course of their lives. In fact,
-we might expect to find many plants and animals born in a
-dreadful state of mutilation as a result of inheritances of this
-sort. Thus, while the Lamarckians try to show that, on their
-principle, characters for the good of the species may be
-acquired, they must also be prepared, if they accept this
-kind of evidence, to grant that immense harm may also result
-from its action. I do not urge this as an argument against
-<span class='pageno' id='Page_257'>257</span>the theory itself, but point it out simply as one of the consequences
-of the theory.</p>
-
-<p class='c010'>It has been shown quite recently, by Charrin, Delamare,
-and Moussu, that when, after the operation of laparotomy on
-a pregnant rabbit or guinea-pig, the kidney or the liver has
-become diseased, the offspring sometimes show similar affections
-in the corresponding organs (kidney or liver). The
-result is due, the authors think, to some substance set free
-from the diseased kidney of the parent that affects the kidney
-of the young in the uterus. By injecting into the blood of a
-pregnant animal fresh extracts from the kidney of another
-animal, the authors believe that the kidney of the young are
-also affected. It will be observed that this transmission of
-an acquired character appears to be different from that of
-transmission through the egg; for it is the developing, or
-developed organ itself, that is acted upon. The results throw
-an interesting light on the cases of epilepsy described by
-Brown-Séquard, since they show that the diseased condition
-of the parent may be transmitted to the later embryonic
-stages. May not, therefore, Brown-Séquard’s results be also
-explained as due to direct transmission from the organs of the
-parent to the similar organs of the young in the uterus?</p>
-
-<p class='c010'>There is another series of experiments of a different sort
-that has been used as an argument in favor of the Lamarckian
-view. These are the results that Cunningham has obtained
-on young flatfish. He put the very young fish,
-while still bilaterally symmetrical (in which stage the pigment
-is equally developed on both sides of the body) into aquaria
-lighted from below. He found that when the young fish
-begins to undergo its metamorphosis, the pigment gradually
-disappears on one side, as it would have done under normal
-conditions, <i>i.e.</i> when they are lighted from above. If, however,
-the fish are kept for some time longer, lighted from
-below, the pigment begins to come back again. “The first
-fact proves that the disappearance of the pigment-cells from
-<span class='pageno' id='Page_258'>258</span>the lower side in the metamorphosis is an hereditary character,
-and not a change produced in each individual by the
-withdrawal of the lower side from the action of light. On
-the other hand, the experiments show that the absence of
-pigment-cells from the lower side throughout life is due to
-the fact that light does not act upon that side, for, when it is
-allowed to act, pigment-cells appear. It seems to me that
-the only reasonable conclusion from these facts is, that the
-disappearance of pigment-cells was originally due to the
-absence of light, and that the change has now become
-hereditary. The pigment-cells produced by the action of
-light on the lower side are in all respects similar to those
-normally present on the upper side of the fish. If the disappearance
-of the pigment-cells were due entirely to a
-variation of the germ-plasm, no external influence could
-cause them to reappear, and, on the other hand, if there
-were no hereditary tendency, the coloration of the lower
-side of the flatfish when exposed would be rapid and
-complete.”<a id='r20' /><a href='#f20' class='c017'><sup>[20]</sup></a></p>
-
-<div class='footnote c018' id='f20'>
-<p class='c019'><span class='label'><a href='#r20'>20</a>.&nbsp;&nbsp;</span><i>Natural Science</i>, October, 1893.</p>
-</div>
-
-<p class='c010'>This evidence might be convincing were it not weakened
-by two or three assumptions. In the first place, it is not
-shown that if the loss of color on the lower side had been
-the result of the inheritance of an acquired character that
-the results seen in Cunningham’s experiment would follow
-as a consequence. Thus one of the starting-points of the
-argument really begs the whole question. In the second
-place, it is unproven that, had the loss of color of the lower
-side been the result of a variation of the germ-plasm, no external
-influence could cause it to reappear. In this connection
-there is another fact that has a bearing on the point here
-raised. In some species of flatfish the right side is turned
-down, and in other species the left. Occasionally an individual
-is found in a right-sided species that is left-sided, and
-in such cases the color is also reversed. Now, to explain this
-<span class='pageno' id='Page_259'>259</span>in the way suggested by Cunningham, we should be obliged
-to assume that some of the ancestors acquired the loss of
-pigment on one side of the body, and others on the other
-side according to which side was turned down. This supposition
-might be appealed to to give us an explanation of the
-occasional reversal of the symmetry as a rare occurrence
-at the present time; but the argument is so transparently
-improbable that, I believe, the Lamarckian school would
-hesitate to make use of it, yet, in principle, it is about the
-same as that Cunningham has followed above.</p>
-
-<p class='c010'>If, on the other hand, we suppose the difference in color of
-the two sides to have been the result of a germ-variation, we
-need only suppose that this was of such a kind that the color
-of the under side is only in a latent condition, and if an
-external factor can cause a reaction to take place on the light
-side, it is not surprising that this should call forth the latent
-color patterns. The result can be given at least a formal
-explanation on the theory that the original change was a
-germ-variation.</p>
-
-<p class='c010'>We come now to the evidence derived from paleontology.
-A number of evolutionists, more especially of the American
-school, have tried to show that the evolution of a number of
-groups can best be accounted for on the theory of the
-inheritance of acquired characters. A point that we must
-always bear in mind is that evolution in a direct line need not
-necessarily be the outcome of Lamarckian factors. Some of
-our leading paleontologists, Cope, Hyatt, Scott, Osborn, have
-been strongly impressed by the paleontological evidence in
-favor of the view that evolution has often been in direct
-lines; and some, at least, of these investigators have been
-led to conclude that only the Lamarckian factor of the inheritance
-of acquired characters can give a sufficient explanation
-of the facts. Paleontologists have been much impressed
-by the fact that evolution has been along the lines which we
-might imagine that it would follow if the effects of use and
-<span class='pageno' id='Page_260'>260</span>of disuse are inherited. There is, however, no proof that
-this is the case, although there are a number of instances to
-which this mode of explanation appears to give the readiest
-solution. But, as has been said before, it is not this kind
-of evidence that the theory is in need of, since Lamarck himself
-gave an ample supply of illustrations. What we need is
-clear evidence that this sort of inheritance is possible, and,
-from the very nature of the case, it is just this evidence that
-fossil remains can never supply.</p>
-
-<p class='c010'>The same criticism may be made of the work of Ryder,
-Packard, Dali, Jackson, Eimer, Cunningham, Semper, De
-Varigny, and others of the Lamarckian school. Despite the
-large number of cases that they have collected, which appear
-to them to be most easily explained on the assumption of
-the inheritance of acquired characters, the proof that such
-inheritance is possible is not forthcoming. Why not then
-spend a small part of the energy, that has been used to
-expound the theory, in demonstrating that such a thing is
-really possible? One of the chief virtues of the Lamarckian
-theory is that it is capable of experimental verification or contradiction,
-and who can be expected to furnish such proof if
-not the Neo-Lamarckians?</p>
-
-<p class='c010'>We may fairly sum up our position in regard to the theory
-of the inheritance of acquired characters in the verdict of
-“not proven.” I am not sure that we should not be justified
-at present in claiming that the theory is unnecessary and
-even improbable.</p>
-<div class='pbb'>
- <hr class='pb c006' />
-</div>
-<div class='chapter'>
-  <span class='pageno' id='Page_261'>261</span>
-  <h2 class='c008'>CHAPTER VIII<br /> <br /><span class='c013'>CONTINUOUS AND DISCONTINUOUS VARIATION AND HEREDITY</span></h2>
-</div>
-<p class='c009'><span class='sc'>The</span> two terms <i>continuous</i> and <i>discontinuous variation</i> refer
-to the succession or inheritance of the variations rather than
-to the actual conditions amongst a group of individuals living
-at the same time; but this distinction has only a subordinate
-value. The term <i>fluctuating</i>, or <i>individual variation</i>,
-expresses more nearly the conditions of the individuals of a
-species at any one time, and the continuation of this sort of
-difference is the continuous variation spoken of above. The
-discontinuous variations are probably of the same nature as
-those that have been called mutations, and what Darwin sometimes
-called sports, or single variations, or definite variations.</p>
-<h3 class='c014'><span class='sc'>Continuous Variation</span></h3>
-
-<p class='c015'>If we examine a number of individuals of the same species,
-we find that no two of them are exactly alike in all particulars.
-If, however, we arrange them according to some one character,
-for example, according to the height, we find that there is a
-gradation more or less perfect from one end of the series to the
-other. Thus, if we were to take at random a hundred men, and
-stand them in line arranged according to their height, the
-tops of their heads, if joined, would form a nearly continuous
-line; the line will, of course, incline downward from the
-tallest to the shortest man. This illustrates individual variation.
-An arrangement of this kind fails to bring out one of
-the most important facts connected with individual differences.
-<span class='pageno' id='Page_262'>262</span>If the line is more carefully examined, it will be found that
-somewhere near the middle the men are much more nearly
-of the same height, or rather there are more men having
-about the same height than there are near the ends of the
-line. Another arrangement will bring this out better. If we
-stand in a line all the men from 60 to 61.9 inches, and in another
-parallel line all those between 62 and 63.9, then those
-between 64 and 65.9, then between 66 and 67.9 inches in<i></i>
-height, etc., it will be found that there are more men in some
-of these lines than in others. The longest line will be that
-containing the men of about 65 inches; the two lines formed
-out of men on each side of this one will contain somewhat
-fewer men, and the next ones fewer still, and so on. If we
-looked at our new group of men from above, we should have
-a figure triangular in outline, the so-called frequency polygon,
-Figure <a href='#fig-3'>3 B</a>. With a larger amount of data of this sort it is
-possible to construct a curve, the curve of frequency, Figure <a href='#fig-3'>3 A</a>.
-In order to obtain this curve of frequency, it is of
-course not necessary to actually put the individuals in line,
-but the curve can be drawn on paper from the measurements.
-We sort out the measurements into classes as in the case
-given above. The classes are laid off at regular intervals
-along a base-line by placing points at definite intervals.
-Perpendiculars are then erected at each point, the height of
-each being proportional to the frequency with which each
-class occurs. If now we join the tops of these perpendiculars,
-the curve of frequency is the result.</p>
-<div id='fig-3'  class='figcenter id005'>
-<img src='images/i263.jpg' alt='' class='ig001' />
-<div class='ic003'>
-<p><span class='sc'>Fig. 3.</span>—Curves of frequency, etc.<br />A, normal curve.<br />B, showing the method of arranging individuals in lines containing similar kinds of individuals.<br />C, curve that is skew to the right.<br />D, polygon of frequencies of horns of rhinoceros beetles.<br />(After Davenport.)</p>
-</div>
-</div>
-
-<p class='c009'>“In arranging the individuals it will be found, as has been
-said, that certain groups contain more individuals. They
-will form the longest line. This value that occurs with the
-greatest frequency is called the mode. The position of this
-modal class in the polygon is one of the points of importance,
-and the spread of the polygon at its base is another. A
-polygon with a low mode and a broad range means great
-variability. The range may, however, be much affected by a
-<span class='pageno' id='Page_263'>263</span>single individual standing far removed from the rest, so that
-a polygon containing such an individual might appear to
-show greater variation than really exists. Therefore we need
-a measure of variability that shall take into account the
-departures of all the individuals from the mode. One such
-measure is the arithmetical average of all the departures from
-the mean in both directions; and this measure has been
-widely employed. At present another method is preferred,
-namely, the square root of the squared departures. This
-measure is called the standard deviation. The standard
-<span class='pageno' id='Page_264'>264</span>deviation is of great importance, because it is the index of
-variability.”<a id='r21' /><a href='#f21' class='c017'><sup>[21]</sup></a></p>
-
-<div class='footnote c018' id='f21'>
-<p class='c019'><span class='label'><a href='#r21'>21</a>.&nbsp;&nbsp;</span>Davenport, C. B., “The Statistical Study of Biological Problems,” <i>Popular
-Science Monthly</i>, September, 1900.</p>
-</div>
-
-<p class='c010'>Of the different kinds of polygons there are two main
-sorts, the simple and the complex. The former have only a
-single mode, the latter have more than one mode. Some
-simple polygons lie symmetrically on each side of the mode,
-Figure <a href='#fig-3'>3 A</a>; others are unsymmetrical or skew, Figure <a href='#fig-3'>3 B</a>.
-The skew polygon generally extends out on one side farther
-than on the other. It has been suggested that when a polygon
-is symmetrical the species is not changing, and when
-skew that the species is evolving in the direction of the
-longer base. This assumes that the sort of variation measured
-by these curves is of the kind of which evolution is
-made up, but this is a question that we must further consider.
-How far the change indicated by the skew curve
-may be carried is also another point for further examination.</p>
-
-<p class='c010'>A complex polygon of variation, Figure <a href='#fig-3'>3 D</a>, has been sometimes
-interpreted to mean that two subgroups exist in a
-species, as is well shown in the case of the rhinoceros beetle
-described by Bateson. Two kinds of male individuals exist,
-some with long horns, others with short horns; each with a
-mode of its own, the two polygons overlapping. Other complex
-polygons may be due to changes occurring at different
-times in the life of the individual, as old age, for example.</p>
-
-<p class='c010'>If, instead of examining the variations of the individuals of
-the race, we study the variations in the different organs of the
-same individual, we find in many cases that certain organs
-vary together. Thus the right and the left leg nearly always
-vary in the same direction, also the first joints of the index
-and middle fingers, and the stature and the forearm. On the
-other hand, the length of the clavicle and that of the humerus
-do not vary together to the same extent; and the breadth and
-height of the skull even less so.</p>
-<div><span class='pageno' id='Page_265'>265</span></div>
-<div class='fs80'>
-
-<table class='table3' summary=''>
-<colgroup>
-<col width='18%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-</colgroup>
-  <tr>
- <td class='bttd bbt c024'>No. of Veins</td>
- <td class='bttd bbt blt c025'>10</td>
- <td class='bttd bbt blt c025'>11</td>
- <td class='bttd bbt blt c025'>12</td>
- <td class='bttd bbt blt c025'>13</td>
- <td class='bttd bbt blt c025'>14</td>
- <td class='bttd bbt blt c025'>15</td>
- <td class='bttd bbt blt c025'>16</td>
- <td class='bttd bbt blt c025'>17</td>
- <td class='bttd bbt blt c025'>18</td>
- <td class='bttd bbt blt c025'>19</td>
- <td class='bttd bbt blt c025'>20</td>
- <td class='bttd bbt blt c025'>21</td>
- <td class='bttd bbt blt c025'>22</td>
-  </tr>
-  <tr>
-    <td class='c024'>First Tree</td>
- <td class='blt c025'>—</td>
- <td class='blt c025'>—</td>
- <td class='blt c025'>—</td>
- <td class='blt c025'>—</td>
- <td class='blt c025'>—</td>
- <td class='blt c025'>1</td>
- <td class='blt c025'>4</td>
- <td class='blt c025'>7</td>
- <td class='blt c025'>9</td>
- <td class='blt c025'>4</td>
- <td class='blt c025'>1</td>
- <td class='blt c025'>—</td>
- <td class='blt c025'>—</td>
-  </tr>
-  <tr>
- <td class='bbtd c024'>Second Tree</td>
- <td class='bbtd blt c025'>—</td>
- <td class='bbtd blt c025'>—</td>
- <td class='bbtd blt c025'>—</td>
- <td class='bbtd blt c025'>3</td>
- <td class='bbtd blt c025'>4</td>
- <td class='bbtd blt c025'>9</td>
- <td class='bbtd blt c025'>8</td>
- <td class='bbtd blt c025'>2</td>
- <td class='bbtd blt c025'>—</td>
- <td class='bbtd blt c025'>—</td>
- <td class='bbtd blt c025'>—</td>
- <td class='bbtd blt c025'>—</td>
- <td class='bbtd blt c025'>—</td>
-  </tr>
-</table>
-
-</div>
-<p class='c009'>We may also study those cases in which a particular
-organ is repeated a number of times in the same individual,
-as are the leaves of a tree. If the leaves of the same tree are
-examined in respect, for example, to the number of veins that
-each contains, we find that the number varies, and that the
-results give a variation polygon exactly like that when different
-individuals are compared with one another. Let us take
-the illustration given by Pearson. He counted the veins on
-each side of the midrib of the leaves of the beech. If a
-number of leaves be collected from one tree, and the same
-number from another, and if all those having fifteen veins are
-put in one vertical column, and all those with sixteen in another,
-as shown in the following table, it will be found that
-each tree has a mode of its own. Thus in the first tree the
-mode is represented by nine individuals having eighteen
-veins, and in the second by nine individuals having fifteen
-veins. So far as this character is concerned we might have
-interchanged certain of the individual leaves, but we could
-not have interchanged the two series. They are <i>individual</i>
-to the two trees. Now in what does this individuality consist?
-Clearly there are most leaves in one tree with eighteen
-ribs, and most in the other with fifteen ribs.</p>
-
-<p class='c010'>If we contrast these results with those obtained by picking
-at random a large number of leaves from different beech trees,
-we have no longer types of individuals, but racial characters.
-Pearson has given the following table to illustrate these points:</p>
-<h3 class='c014'><span class='sc'>Frequency of Different Types of Beech Leaves</span></h3>
-<div class='fs80'>
-
-<table class='table4' summary=''>
-<colgroup>
-<col width='18%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-<col width='6%' />
-</colgroup>
-  <tr>
- <td class='bttd bbt c024'>No. of Veins</td>
- <td class='bttd bbt blt c025'>10</td>
- <td class='bttd bbt blt c025'>11</td>
- <td class='bttd bbt blt c025'>12</td>
- <td class='bttd bbt blt c025'>13</td>
- <td class='bttd bbt blt c025'>14</td>
- <td class='bttd bbt blt c025'>15</td>
- <td class='bttd bbt blt c025'>16</td>
- <td class='bttd bbt blt c025'>17</td>
- <td class='bttd bbt blt c025'>18</td>
- <td class='bttd bbt blt c025'>19</td>
- <td class='bttd bbt blt c025'>20</td>
- <td class='bttd bbt blt c025'>21</td>
- <td class='bttd bbt blt c025'>22</td>
-  </tr>
-  <tr>
- <td class='bbtd c024'>Frequency</td>
- <td class='bbtd blt c025'>1</td>
- <td class='bbtd blt c025'>7</td>
- <td class='bbtd blt c025'>34</td>
- <td class='bbtd blt c025'>110</td>
- <td class='bbtd blt c025'>318</td>
- <td class='bbtd blt c025'>479</td>
- <td class='bbtd blt c025'>595</td>
- <td class='bbtd blt c025'>516</td>
- <td class='bbtd blt c025'>307</td>
- <td class='bbtd blt c025'>181</td>
- <td class='bbtd blt c025'>36</td>
- <td class='bbtd blt c025'>15</td>
- <td class='bbtd blt c025'>1</td>
-  </tr>
-</table>
-
-</div>
-<p class='c009'><span class='pageno' id='Page_266'>266</span>Thus the mode for beech trees in general is sixteen; but, as
-shown in the other table, this mode does not correspond with
-either of the two individual modes here ascertained. The
-illustration shows that the racial mode may differ from the
-individual mode. There are also cases known in which
-the mode of a group of individuals living in one locality is
-different from that of another group living in another locality.
-This difference may be a constant one from year to year,
-although so slight, that unless actual measurements are made,
-the difference cannot be detected, because of the overlapping
-of the individuals from different localities. If evolution took
-place by slow changes of this sort, it might be possible to detect
-its action, even when very slow, by means of measurements
-made on a large number of individuals. At least this
-has been suggested by those who believe new species may
-result from changes of this sort.</p>
-
-<p class='c010'>There is some evidence showing that by selecting particular
-individuals of a series, and breeding from them, the mode
-may be changed in the direction of selection. Thus it has
-been stated by Davenport that the descendants of twelve-
-and thirteen-rayed daisies give a polygon with a skewness of
-+1.92; while the descendants of twenty-one-rayed plants
-give a polygon with a skewness of -.13.</p>
-
-<p class='c010'>Pearson has described very concisely the possibilities involved
-in the selective action of the environment. He states
-that if we examine the frequency distribution of a set of
-organisms that have just become mature, and later make a
-similar examination on the same number of individuals (but
-not the same individuals) during the period of reproduction,
-we shall probably find that a change has taken place which
-may have been due to selection of some sort. The same
-thing might be found in the next generation, and, if it did,
-this would indicate that “selection does not necessarily mean
-a permanent or a progressive change.” The selection in this
-imaginary case would be purely periodic and suffice only to
-<span class='pageno' id='Page_267'>267</span>maintain a given race under given conditions. “Each new
-adolescent generation is not the product of the entire preceding
-generation, but only of selected individuals. This is certainly
-the case for civilized man, in which case twenty-six per
-cent of the married population produce fifty per cent of the
-next generation.”</p>
-
-<p class='c010'>Pearson believes that “if a race has been long under the
-same environment it is probable that only periodic selection
-is at work, maintaining its stability. Change the environment
-and a secular change takes place, the deviations from
-the mode previously destroyed giving the requisite material.”
-“Clearly periods of rapidly changing environment, of great
-climatological and geological change, are likely to be associated
-with most marked secular selection. To show that
-there is little or no change year by year in the types of rabbit
-and wild poppy in our English fields, or of daphnia in our
-English ponds, is to put forward no great argument for the
-inefficiency of natural selection. Take the rabbit to Australia,
-the wild poppy to the Cape, the daphnia into the laboratory,
-and change their temperature, their food supply, and the
-chemical constituents of water and air, and then the existence
-of no secular selection would indeed be a valid argument
-against the Darwinian theory of evolution.” In regard to
-the last point, it should be noted that, even if under the
-changed conditions a change in the mode took place, as
-Pearson assumes, it does not follow necessarily that selection
-has had anything to do with it, but the environment may have
-directly changed the forms. Furthermore, and this is the
-essential point, even if selection does act to the extent of
-changing the mode, we should not be justified in concluding
-that this sort of change could go on increasing as long as the
-selection lasts. All that might happen would be to keep the
-species up to the highest point to which fluctuating variation
-can be held. This need not lead to the formation of new
-species, or direct the course of evolution.</p>
-
-<p class='c010'><span class='pageno' id='Page_268'>268</span>Pearson points out further that, even if we suppose that a
-secular change is produced in a new environment, we cannot
-explain how species may break up into two or more races
-that are relatively infertile. Suppose two groups of individuals,
-subjected to different environments, become isolated
-geographically. Two local races will be produced. “Isolation
-may account for the origin of local races, but never for
-the origin of species unless it is accompanied by a differential
-fertility.” In other words, Pearson thinks that, unless
-the reproductive organs are correlated with other organs, in
-such a way that as these organs change the interracial fertility
-of the germ-cells is altered, so that in the two changed
-groups the individuals are no longer interfertile, new species
-cannot be accounted for, since their mutual infertility is one
-of their most characteristic features. “Without a barrier to
-intercrossing during differentiation the origin of species
-seems inexplicable.”</p>
-
-<p class='c010'>We need not discuss the various suggestions that have
-been made to explain this difficulty, none of which, as Pearson
-points out, have been satisfactory. He himself believes
-that a process of segregation of like individuals must occur,
-during the incipient stages at least, in the formation of species.
-Afterwards a correlation may exist between the new organs
-and the germ-cells, of such a sort that a relative or an absolute
-sterility between the incipient species is attained. After
-this condition has been reached the two new species may
-freely intermix without a return to the primitive type, since
-they are no longer fertile <i>inter se</i>. It seems to me, also, that
-this would be an essential requisite if we assume that species
-are slowly formed out of races from individual differences, as
-Pearson supposes to be the case. There are, however, other
-possibilities that Pearson does not take into account, namely,
-that from the very beginning the change may be so great
-that the new form is not fertile with the original one; and
-there is also another possibility as well, that, although the
-<span class='pageno' id='Page_269'>269</span>new and the old forms are fertile, the hybrids may be like
-one or the other parent, as in several cases to be given later.
-Not that I mean to say that in either of these two ways can we
-really offer a solution of the question of infertility, for, from
-the evidence that we possess, it appears improbable that the
-infertility of species <i>inter se</i> has been the outcome of either
-of these causes.</p>
-
-<p class='c010'>In support of his main thesis Pearson gives certain data in
-respect to preferential mating in the human race. By this is
-meant that selection of certain types of individuals is more
-likely to take place, and also that the fertility of certain types
-of individuals is greater than that of other types. The calculations
-are based on stature, color of hair, and of eyes.
-The results appear to show in all cases examined that there
-is a slight tendency to form new races as the result of the
-more frequent selection of certain kinds of individuals. But
-even if this is the case, what more do the results show than
-that local races may be formed,—races having a certain
-mode for height, for color of eyes or of hair? That changes
-of this kind can be brought about we knew already without
-any elaborate measurements, yet we should not conclude from
-this that new species will be formed by a continuation of the
-process.</p>
-
-<p class='c010'>Pearson writes: “As to the problem of evolution itself we
-are learning to see it under a new light. Natural selection,
-combined with sexual selection [by which Pearson means
-segregation of certain types through individual selection]
-and heredity, is actually at work changing types. We have
-quantitative evidence of its effects in many directions.” Yes!
-but no evidence that selection of this sort can do anything
-more than keep up the type to the upper limit attained in
-each generation by fluctuating variations. Pearson adds,
-“Variations do not occur accidentally, or in isolated instances;
-autogamic and assortive mating are realities, and the problem
-of the near future is not whether Darwinism is a reality, but
-<span class='pageno' id='Page_270'>270</span>what is quantitively the rate at which it is working and has
-worked.” This statement expresses no more than Pearson’s
-conviction that the process of evolution has taken place by
-means of selection. He ignores other possibilities, which if
-established may put the whole question in a very different
-light.</p>
-<h3 class='c014'><span class='sc'>Heredity and Continuous Variation</span></h3>
-
-<p class='c015'>It has been to a certain extent assumed in the preceding
-pages that both parents are alike, or, if different, that they
-have an equal influence on the offspring. This may be true
-in many cases for certain characteristics. Thus a son from
-a tall father and a short mother may be intermediate in
-height, or if the father is white and the mother black, the
-children are mulattoes. But other characters rarely or never
-blend. In such cases the offspring is more like one or the
-other parent, in which case the inheritance is said to be
-exclusive. Thus if one parent has blue eyes and the other
-black, some of the children may have black eyes and others
-blue. There are also cases of particular inheritance where
-there may be patches of color, some like the color of one
-parent, some like that of the other parent. The latter two
-kinds of inheritance will be more especially considered in the
-subsequent part of this chapter; for the present we are here
-chiefly concerned with blended characters.</p>
-
-<p class='c010'>How much in such cases does each parent contribute to the
-offspring? This has been expressed by Galton in his law of
-ancestral heredity. This law takes into account not only the
-two parents, but also the four grandparents, and the eight
-great-grandparents, etc. There will be 1024 in the tenth
-generation. These 1024 individuals may be taken as a fair
-sample of the general population, provided there has not been
-much interbreeding. Are we then to look upon the individual
-as the fused or blended product of the population a few
-generations back? If this were true, should we not expect
-<span class='pageno' id='Page_271'>271</span>to find all the individuals of a community very much alike,
-except for the fluctuating variations close around the mode?</p>
-
-<p class='c010'>As a result of his studies on the stature of man, and on
-the coat color of the Basset hounds, Galton has shown that
-the inheritance from the parents can be represented by the
-fraction 1/2; that is one-half of the peculiarities of the individual
-comes from the two parents. The four grandparents
-together count for 1/4 of the total inheritance, the great-grandparents
-1/8, and so on, giving the series 1/2, 1/4, 1/8. Pearson, taking
-certain other points into consideration, believes the following
-series more fully represents the inheritance from the ancestors,
-.3, .15, .075, .0375, etc. He concludes that, “if Darwinism
-be the true view of evolution, <i>i.e.</i> if we are to describe
-evolution by natural selection combined with heredity, then
-the law which gives us definitely and concisely the type of
-the offspring in terms of the ancestral peculiarities is at
-once the foundation stone of biology and the basis upon
-which heredity becomes an exact branch of science.”</p>
-
-<p class='c010'>The preceding statements give some idea of what would
-occur in a community in which no selection was taking
-place. The results will be quite different, although the same
-general law of inheritance will hold, if selection takes place in
-each generation. If, for instance, selection takes place, the
-offspring after four generations will have .93 of the selected
-character, and without further selection will not regress, but
-breed true to this type.<a id='r22' /><a href='#f22' class='c017'><sup>[22]</sup></a> “After six generations of selection
-the offspring will, selection being suspended, breed true to
-under two per cent divergence from the previously selected
-type.”</p>
-
-<div class='footnote c018' id='f22'>
-<p class='c019'><span class='label'><a href='#r22'>22</a>.&nbsp;&nbsp;</span>In this statement the earlier ancestors are assumed to be identical with the
-general type of the population.</p>
-</div>
-
-<p class='c010'>If, however, we do not assume that the ancestors were
-mediocre, it is found that after six generations of selection the
-offspring will breed true to the selected type within one per
-cent of its value. Thus, if selection were to act on a race
-<span class='pageno' id='Page_272'>272</span>of men having a mode of 5 feet 9 inches, and the 6-foot men
-were selected in each generation, then in six generations this
-type would be permanently established, and this change
-could be effected in two hundred years.<a id='r23' /><a href='#f23' class='c017'><sup>[23]</sup></a></p>
-
-<div class='footnote c018' id='f23'>
-<p class='c019'><span class='label'><a href='#r23'>23</a>.&nbsp;&nbsp;</span>Quoted from Pearson’s “Grammar of Science.”</p>
-</div>
-
-<p class='c010'>Thus we have exact data as to what will happen on the
-average when blended, fluctuating variations are selected.
-Important as such data must always be to give us accurate
-information as to what will occur if things are left to
-“chance” variations, yet if it should prove true that evolution
-has not been the outcome of chance, then the method is
-entirely useless to determine how evolution has occurred.</p>
-
-<p class='c010'>More important than a knowledge of what, according to
-the theory of chances, fluctuating variations will do, will be
-information that would tell us what changes will take place
-in each individual. In this field we may hope to obtain data
-no less quantitative than those of chance variations, but of a
-different kind. A study of some of the results of discontinuous
-variation will show my meaning more clearly.</p>
-<h3 class='c014'><span class='sc'>Discontinuous Variation</span></h3>
-
-<p class='c015'>Galton, in his book on “Natural Inheritance,” points out
-that “the theory of natural selection might dispense with
-a restriction for which it is difficult to see either the need
-or the justification, namely, that the course of evolution always
-proceeds by steps that are severally minute and that
-become effective only through accumulation.” An apparent
-reason, it is suggested, for this common belief “is founded on
-the fact that whenever search is made for intermediate forms
-between widely divergent varieties, whether they are of plants
-or of animals, of weapons or utensils, of customs, religion, or
-language, or of any other product of evolution, a long and
-orderly series can usually be made out, each member of which
-differs in an almost imperceptible degree from the adjacent
-<span class='pageno' id='Page_273'>273</span>specimens. But it does not at all follow because these intermediate
-forms have been found to exist, that they were the
-very stages that were passed through in the course of evolution.
-Counter evidence exists in abundance, not only of the
-appearance of considerable sports, but of their remarkable
-stability in hereditary transmission.” Comparing such an
-apparently continuous series with machines, Galton concludes,
-“If, however, all the variations of any machine that
-had ever been invented were selected and arranged in a
-museum, each would differ so little from its neighbors as to
-suggest the fallacious inference that the successive inventions
-of that machine had progressed by means of a very
-large number of hardly discernible steps.”</p>
-
-<p class='c010'>Bateson, also, in his “Materials for the Study of Variation,”
-speaks of the two possible ways in which variations may arise.
-He points out that it has been tacitly assumed that the transitions
-have been continuous, and that this assumption has
-introduced many gratuitous difficulties. Chief of these is
-the difficulty that in their initial and imperfect stages many
-variations would be useless. “Of the objections that have
-been brought against the Theory of Natural Selection, this
-is by far the most serious.” He continues: “The same
-objection may be expressed in a form which is more correct
-and comprehensive. We have seen that the differences between
-species on the whole are Specific, and are differences
-of kind forming a discontinuous Series, while the diversities
-of environment to which they are subject are, on the whole,
-differences of degree, and form a continuous Series; it is,
-therefore, hard to see how the environmental differences can
-thus be made in any sense the directing cause of Specific
-differences, which by the Theory of Natural Selection they
-should be. This objection of course includes that of the
-utility of minimal Variations.”</p>
-
-<p class='c010'>“Now the strength of this objection lies wholly in the supposed
-continuity of the process of Variation. We see all
-<span class='pageno' id='Page_274'>274</span>organized nature arranged in a discontinuous series of groups
-differing from each other by differences which are Specific;
-on the other hand, we see the diverse environments to which
-these forms are subject passing insensibly into each other.
-We must admit, then, that if the steps by which the diverse
-forms of life have varied from each other have been insensible,—if,
-in fact, the forms ever made up a continuous series,—these
-forms cannot have been broken into a discontinuous
-series of groups by a continuous environment, whether acting
-directly as Lamarck would have, or as selective agent as Darwin
-would have. This supposition has been generally made
-and admitted, but in the absence of evidence as to Variation
-it is nevertheless a gratuitous assumption, and, as a matter of
-fact, when the evidence as to Variation is studied, it will be
-found to be in a great measure unfounded.”</p>
-
-<p class='c010'>There is a fair number of cases on record in which discontinuous
-variations have been seen to take place. Darwin himself
-has given a number of excellent examples, and Bateson,
-in the volume referred to above, has brought together a large
-and valuable collection of facts of this kind.</p>
-
-<p class='c010'>Some of the most remarkable of these instances have been
-already referred to and need only be mentioned here. The
-black-shouldered peacock, the ancon ram, the turnspit dog,
-the merino sheep, tailless and hornless animals, are all cases
-in point. In several of these it has been discovered that the
-young inherit the peculiarities of their parents if the new
-variations are bred together; and what is more striking, if
-the new variation is crossed with the parent form, the young
-are like one or the other parent, and not intermediate in
-character. This latter point raises a question of fundamental
-importance in connection with the origin of species.</p>
-
-<p class='c010'>Darwin states that he knows of <i>no cases in which, when
-different species or even strongly marked varieties are crossed,
-the hybrids are like one form or the other</i>. They show, he believes,
-always a blending of the peculiarities of the two parents.
-<span class='pageno' id='Page_275'>275</span>He then makes the following significant statement: “All
-the characters above enumerated which are transmitted in
-a perfect state to some of the offspring and not to others—such
-as distinct colors, nakedness of skin, smoothness of
-leaves, absence of horns or tail, additional toes, pelorism,
-dwarfed structure, etc., have all been known to appear suddenly
-in individual animals or plants. From this fact, and
-from the several slight, aggregated differences which distinguish
-domestic races and species from each other, not
-being liable to this peculiar form of transmission, we may
-conclude that it is in some way connected with the sudden
-appearance of the characters in question.”</p>
-
-<p class='c010'>Darwin has, incidentally, raised here a question of the most
-far-reaching import. If it should prove true, as he believes,
-that inheritance of this kind of discontinuous variation is also
-discontinuous, and that we do not get the same result when
-distinct species are intercrossed, or even when well-marked
-domestic races are interbred, then he has, indeed, placed a
-great obstacle in the path of those who have tried to show
-that new species have arisen through discontinuous variation
-of this sort.</p>
-
-<p class='c010'>If wild species, when crossed, give almost invariably intermediate
-forms, then it may appear that we are going against
-the only evidence that we can hope to obtain if we claim
-that discontinuous variation, of the kind that sports are made
-of, has supplied the material for evolution. If, furthermore,
-when distinct races of domesticated animals are crossed, we
-do not get discontinuous inheritance, it might, perhaps, with
-justness be claimed that this instance is paralleled by what
-takes place when wild species are crossed. And if domesticated
-forms have been largely the result of the selection of
-fluctuating variations, as Darwin believes, then a strong case
-is apparently made out in favor of Darwin’s view that continuous
-variation has given the material for the process of
-evolution in nature. Whether selection or some other factor
-<span class='pageno' id='Page_276'>276</span>has directed the formation of the new species would not, of
-course, be shown, nor would it make any difference in the
-present connection.</p>
-
-<p class='c010'>Before we attempt to reach a conclusion on this point let
-us analyze the facts somewhat more closely.</p>
-
-<p class='c010'>In the first place, a number of these cases of discontinuous
-variation are of the nature of abnormalities. The appearance
-of extra fingers or toes in man and other mammals is an example
-of this sort. This abnormality is, if inherited at all,
-inherited completely; that is, if present the extra digit is perfect,
-and never appears in an intermediate condition, even
-when one of the parents was without it. The most obvious
-interpretation of this fact is that when the material out of
-which the fingers are to develop is divided up, or separated
-into its component parts, one more part than usual is laid
-down. Similarly, when a flower belonging to the triradiate
-type gives rise to a quadriradiate form,—as sometimes
-occurs,—the new variation seems to depend simply on the
-material being subdivided once more than usual; perhaps
-because a little more of it is present, or because it has a
-somewhat different shape. My reasons for making a surmise
-of this sort are based on certain experimental facts in
-connection with the regeneration of animals. It has been
-shown in several cases that it is possible to produce more
-than the normal number of parts by simply dividing the material
-so that each part becomes more or less a new whole,
-and the total number of parts into which the material becomes
-subdivided is increased. It seems not improbable that phenomena
-of this sort have occurred in the course of evolution,
-although it is, of course, possible that those characters that
-define species do not belong to this class of variation. To
-take an example. There are nine neck-vertebræ in some
-birds, but in the swan the number is twenty-five. We cannot
-suppose that the ancestor of the swan gradually added enough
-materially to make up one new vertebra and then another,
-<span class='pageno' id='Page_277'>277</span>but at least one new whole vertebra was added at a time;
-and we know several cases in which the number of vertebræ
-in the neck has suddenly been increased by the addition
-of one more than normal, and the new vertebra is perfectly
-formed from the first.</p>
-
-<p class='c010'>In cases of this sort we can easily understand that the
-inheritance must be either of one kind or the other, since
-intermediate conditions are impossible, when it comes to
-the question of one or not one; but if one individual had
-one and another six vertebræ, then it would be theoretically
-possible for the hybrid to have three.</p>
-
-<p class='c010'>This brings us to a question that should have been spoken
-of before in regard to the inheritance of discontinuous variation.
-It sometimes occurs that a variation, which appears
-in other respects to be discontinuous, is inherited in a blended
-form. Thus the two kinds of variation may not always be
-so sharply separated as one might be led to believe. There
-may be two different kinds of discontinuous variation in respect
-to inheritance, or there may be variations that are only
-to a greater or a less extent inherited discontinuously; and
-it seems not improbable that both kinds occur.</p>
-
-<p class='c010'>This diversion may not appear to have brought us any
-nearer to the solution of the difficulty that Darwin’s statement
-has emphasized, except in so far as it may show that
-the lines are not so sharply drawn as may have seemed to be
-the case. The solution of the difficulty is, I believe, as
-follows:—</p>
-
-<p class='c010'><i>The discontinuity referred to by Darwin relates to cases in
-which only a single step (or mutation) has been taken, and it
-is a question of inheritance of one or not one. If, however, six
-successive steps should be taken in the same direction, then
-when such a form is crossed with the original form, the hybrid
-may inherit only three of the steps and stand exactly midway
-between the parent forms; or it may inherit four, or five, or
-three, or two steps and stand correspondingly nearer to the one</i>
-<span class='pageno' id='Page_278'>278</span><i>or to the other parent. Thus while it may not be possible to
-halve a single step (hence one-sided inheritance), yet when more
-than one step has been taken the inheritance may be divided.
-There is every evidence that most of the Linnæan (wild)
-species that Darwin refers to have diverged from the parent
-form, and from each other, by a number of successive steps;
-hence on crossing, the hybrid often stands somewhere between
-the two parent forms. On this basis not only can we meet
-Darwin’s objection, but the point of view gives an interesting
-insight into the problem of inheritance and the formation of
-species.</i></p>
-
-<p class='c010'>The whole question of inheritance has assumed a new
-aspect; first on account of the work of De Vries in regard
-to the appearance of discontinuous variation in plants; and
-secondly, on account of the remarkable discoveries of Gregor
-Mendel as to the laws of inheritance of discontinuous variations.
-Mendel’s work, although done in 1865, was long
-neglected, and its importance has only been appreciated in
-the last few years. We shall take up Mendel’s work first,
-and then that of De Vries.</p>
-<h3 class='c014'><span class='sc'>Mendel’s Law</span><a id='r24' /><a href='#f24' class='c017'><sup>[24]</sup></a></h3>
-
-<div class='footnote c026' id='f24'>
-<p class='c019'><span class='label'><a href='#r24'>24</a>.&nbsp;&nbsp;</span>Bateson, in his book on “Mendel’s Principles of Heredity,” has given an
-admirable presentation of Mendel’s results. I have relied largely on this in my
-account.</p>
-</div>
-
-<p class='c010'>The importance of Mendel’s results and their wide application
-is apparent from the results in recent years of De Vries,
-Correns, Tschermak, Bateson, Castle, and others. Mendel
-carried out his experiments on the pea, <i>Pisum sativum</i>.
-Twenty-two varieties were used, which had been proven by
-experiment to be pure breeds. When crossed they gave perfectly
-fertile offspring. Whether they all have the value of
-varieties of a single species, or are different subspecies, or
-even independent species, is of little consequence so far as
-<span class='pageno' id='Page_279'>279</span>Mendel’s experiments are concerned. The flower of the pea
-is especially suitable for experiments of this kind. It cannot
-be accidentally fertilized by foreign pollen, because the reproductive
-organs are inclosed in the keel of the flower, and, as
-a rule, the anthers burst and cover the stigma of the same
-flower with its own pollen before the flower opens. In order
-to cross-fertilize the plants it is necessary to open the young
-buds before the anthers are mature and carefully remove all
-the anthers. Foreign pollen may be then, or later, introduced.</p>
-
-<p class='c010'>The principle involved in Mendel’s law may be first stated
-in a theoretical case, from which a certain complication that
-appears in the actual results may be removed.</p>
-
-<p class='c010'>If <i>A</i> represent a variety having a certain character, and
-<i>B</i> another variety in which the same character is different,
-let us say in color, and if these two individuals, one of each
-kind, are crossed, the hybrid may be represented by <i>H</i>. If
-a number of these hybrids are bred together, their descendants
-will be of three kinds; some will be like the grandparent,
-<i>A</i>, in regard to the special character that we are following,
-some will be like the other grandparent, <i>B</i>, and others will be
-like the hybrid parent, <i>H</i>. Moreover, there will be twice as
-many with the character <i>H</i>, as with <i>A</i>, or with <i>B</i>.</p>
-<div  class='figcenter id006'>
-<img src='images/i279.jpg' alt='' class='ig001' />
-</div>
-<p class='c009'>If now we proceed to let these <i>A</i>’s breed together, it will
-be found that their descendants are all <i>A</i>, forever. If the
-<span class='pageno' id='Page_280'>280</span><i>B</i>’s are bred together they produce only <i>B</i>’s. But when the
-<i>H</i>’s are bred together they give rise to <i>H</i>’s, <i>A</i>’s, and <i>B</i>’s, as
-shown in the accompanying diagram. In each generation,
-the <i>A</i>’s will also breed true, the <i>B</i>’s true, but the <i>H</i>’s will
-give rise to the three kinds again, and always in the same
-proportion.</p>
-
-<p class='c010'>Thus it is seen that the hybrid individuals continue to give
-off the pure original forms, in regard to the special character
-under consideration. The numerical relation between the
-numbers is also a striking fact. Its explanation is, however,
-quite simple, and will be given later.</p>
-
-<p class='c010'>In the actual experiment the results appear somewhat more
-complicated because the hybrid cannot be distinguished from
-one of the original parents, but the results really conform
-exactly to the imaginary case given above. The accompanying
-diagram will make clearer the account that follows.</p>
-<div  class='figcenter id006'>
-<img src='images/i280.jpg' alt='' class='ig001' />
-</div>
-<p class='c009'>The hybrid, <i>A</i>(<i>B</i>), produced by crossing <i>A</i> and <i>B</i> is like <i>A</i> so
-far as the special character that we will consider is concerned.
-In reality the character that <i>A</i> stands for is only dominant,
-that is, it has been inherited discontinuously, while the other
-character, represented by <i>B</i>, is latent, or recessive as Mendel
-calls it. Therefore, in the table, it is included in parentheses.
-If the hybrids, represented by this form <i>A</i>(<i>B</i>), are bred
-<span class='pageno' id='Page_281'>281</span>together, there are produced two kinds of individuals, <i>A</i>’s
-and <i>B</i>’s, of which there are three times as many <i>A</i>’s as <i>B</i>’s.
-It has been found, however, that some of these <i>A</i>’s are pure
-forms, as indicated by the <i>A</i> on the left in our table, while
-the others, as shown by their subsequent history, are hybrids,
-<i>A</i>(<i>B</i>). There are also twice as many of these <i>A</i>(<i>B</i>)’s as of
-the pure <i>A</i>’s (or of the <i>B</i>’s). Thus the results are really the
-same as in our imaginary case, only obscured by the fact that
-the <i>A</i>’s and the <i>A</i>(<i>B</i>)’s are exactly alike to us in respect to
-the character chosen. We see also why there appear to be
-three times as many <i>A</i>’s as <i>B</i>’s. In reality the results are
-1 <i>A</i>, 2 <i>A</i>(<i>B</i>), 1 <i>B</i>.</p>
-
-<p class='c010'>In subsequent generations the results are the same as in
-this one, the <i>A</i>’s giving rise only to <i>A</i>, the <i>B</i>’s to <i>B</i>, and the
-<i>A</i>(<i>B</i>)’s continuing to split up into the three forms, as shown in
-our diagram. Mendel found the same law to hold for all the
-characters he examined, including such different ones as the
-form of the seed, color of seed-albumen, coloring of seed-coat,
-form of the ripe pods, position of flowers, and length of stem.</p>
-
-<p class='c010'>Mendel also carried out a series of experiments in which
-several differentiating characters are associated. In the first
-experiment the parental plants (varieties) differed in the form
-of the seed and in the color of the albumen. The two characters
-of the seed plant are designated by the capital letters
-<i>A</i> and <i>B</i>; and of the pollen plant by small <i>a</i> and <i>b</i>. The
-hybrids will be, of course, combinations of these, although
-only certain characters may dominate. Thus in the experiments,
-the parents are <i>AB</i> (seed plant) and <i>ab</i> (pollen plant),
-with the following seed characters:—</p>
-<div class='fs80'>
-
-<table class='table5' summary=''>
-<colgroup>
-<col width='20%' />
-<col width='26%' />
-<col width='26%' />
-<col width='26%' />
-</colgroup>
-  <tr>
-    <td class='c027'>Seed parent</td>
-    <td class='c028'>{A form round</td>
-    <td class='c027'>Pollen parent</td>
-    <td class='c029'>{a form angular</td>
-  </tr>
-  <tr>
-    <td class='c027'><i>AB</i></td>
-    <td class='c028'>{B albumen yellow</td>
-    <td class='c027'><i>ab</i></td>
-    <td class='c029'>{b albumen green</td>
-  </tr>
-</table>
-
-</div>
-<p class='c009'>When these two forms were crossed the seeds appeared round
-and yellow like those of the parent, <i>AB</i>, <i>i.e.</i> these two characters
-dominated in the hybrid.</p>
-
-<p class='c010'><span class='pageno' id='Page_282'>282</span>The seeds were sown, and in turn yielded plants which when
-self-fertilized gave four kinds of seeds (which frequently all
-appeared in the same pod). Thus 556 seeds were produced
-by 15 plants, having the following characters:—</p>
-<div class='lg-container-l c030'>
-  <div class='linegroup'>
-    <div class='group'>
-      <div class='line'><i>AB</i> 315 round and yellow</div>
-      <div class='line'><i>Ab</i> 101 angular and yellow</div>
-      <div class='line'><i>aB</i> 108 round and green</div>
-      <div class='line'><i>ab</i> 32 angular and green</div>
-    </div>
-  </div>
-</div>
-
-<p class='c009'>These figures stand almost in the relation of 9 : 3 : 3 : 1.</p>
-
-<p class='c010'>These seeds were sown again in the following year and
-gave:—</p>
-
-<p class='c010'>From the round yellow seeds:—</p>
-
-<div class='lg-container-l c031'>
-  <div class='linegroup'>
-    <div class='group'>
-      <div class='line'><i>AB</i>    38 round and yellow seeds</div>
-      <div class='line'><i>ABb</i>   65 round yellow and green seeds</div>
-      <div class='line'><i>AaB</i>   60 round yellow and angular yellow seeds</div>
-      <div class='line'><i>AaBb</i> 138 round yellow and green, angular yellow and green seeds</div>
-    </div>
-  </div>
-</div>
-
-<p class='c010'>From the angular yellow seeds:—</p>
-
-<div class='lg-container-l c031'>
-  <div class='linegroup'>
-    <div class='group'>
-      <div class='line'><i>aB</i>  28 angular yellow seeds</div>
-      <div class='line'><i>aBb</i> 68 angular yellow and green seeds</div>
-    </div>
-  </div>
-</div>
-
-<p class='c010'>From the round green seeds:—</p>
-
-<div class='lg-container-l c031'>
-  <div class='linegroup'>
-    <div class='group'>
-      <div class='line'><i>Ab</i>  35 round green seeds</div>
-      <div class='line'><i>Aab</i> 67 round angular seeds</div>
-    </div>
-  </div>
-</div>
-
-<p class='c010'>From the angular green seeds:—</p>
-
-<div class='lg-container-l c031'>
-  <div class='linegroup'>
-    <div class='group'>
-      <div class='line'><i>ab</i> 30 angular green seeds</div>
-    </div>
-  </div>
-</div>
-
-<p class='c010'>Thus there were 9 different kinds of seeds produced.
-There had been separated out at this time 38 individuals
-like the parent seed plant, <i>AB</i>, and 30 like the parent
-pollen plant, <i>ab</i>. Since these had come from similar seeds
-of the preceding generation they may be looked upon as
-pure at this time. The forms <i>Ab</i> and <i>aB</i> are also constant
-<span class='pageno' id='Page_283'>283</span>forms which do not subsequently vary. The remainder are
-still mixed or hybrid in character. By successive self-fertilizations
-it is possible gradually to separate out from these the
-pure types of which they are compounded.</p>
-
-<p class='c010'>Without going into further detail it may be stated that the
-offspring of the parent hybrids, having two pairs of differentiating
-characters, are represented by the series:—</p>
-
-<div class='nf-center-c0'>
-  <div class='nf-center'>
-    <div><i>AB</i> <i>Ab</i> <i>aB</i> <i>ab</i> 2<i>ABb</i> 2<i>aBb</i> 2<i>Aab</i> 2<i>ABa</i> 2<i>AaBb</i></div>
-  </div>
-</div>
-
-<p class='c010'>This series is really a combination of the two series:—</p>
-
-<div class='lg-container-l c031'>
-  <div class='linegroup'>
-    <div class='group'>
-      <div class='line'><i>A</i> + 2<i>Aa</i> + <i>a</i></div>
-      <div class='line'><i>B</i> + 2<i>Bb</i> + <i>b</i></div>
-    </div>
-  </div>
-</div>
-
-<p class='c010'>Mendel even went farther, and used two parent varieties
-having three differentiating characters, as follows:—</p>
-
-<div class='fs80'>
-
-<table class='table6' summary=''>
-<colgroup>
-<col width='50%' />
-<col width='50%' />
-</colgroup>
-  <tr>
-    <td class='c027'><i>ABC seed parent</i></td>
-    <td class='c032'><i>abc pollen plant</i></td>
-  </tr>
-  <tr>
-    <td class='c028'>{ A form round</td>
-    <td class='c029'>{ a form angular</td>
-  </tr>
-  <tr>
-    <td class='c028'>{ B albumen yellow</td>
-    <td class='c029'>{ b albumen green</td>
-  </tr>
-  <tr>
-    <td class='c028'>{ C seed-coat grey brown</td>
-    <td class='c029'>{ c seed-coat white</td>
-  </tr>
-</table>
-
-</div>
-
-<p class='c010'>The results, as may be imagined, were quite complex, but
-can be expressed by combining these series:—</p>
-
-<div class='lg-container-l c031'>
-  <div class='linegroup'>
-    <div class='group'>
-      <div class='line'><i>A</i> + 2<i>Aa</i> + <i>a</i></div>
-      <div class='line'><i>B</i> + 2<i>Bb</i> + <i>b</i></div>
-      <div class='line'><i>C</i> + 2<i>Cc</i> + <i>c</i></div>
-    </div>
-  </div>
-</div>
-
-<p class='c010'>In regard to the two latter experiments, in which two and
-three characters respectively were used, it is interesting to
-point out that the form of the hybrid more nearly approaches
-“to that one of the parental plants which possesses the greatest
-number of dominant characters.” If, for instance, the seed
-plant has short stem, terminal white flowers, and simply
-inflated pods; the pollen plant, on the other hand, a long
-stem, violet-red flowers distributed along the stem, and constricted
-pods,—then the hybrid resembles the seed parent
-only in the form of the pod; in its other characters it agrees
-<span class='pageno' id='Page_284'>284</span>with the pollen plant. From this we may conclude that, if two
-varieties differing in a large number of characters are crossed,
-the hybrid might get some of its dominant characters from
-one parent, and other dominant characters from the other
-parent, so that, unless the individual characters themselves
-were studied, it might appear that the hybrids are intermediate
-between the two parents, while in reality they are only
-combinations of the dominant characters of the two forms.
-But even this is not the whole question.</p>
-
-<p class='c010'>Mendel points out that, from knowing the characters of
-the two parent forms (or varieties), one could not prophesy
-what the hybrid would be like without making the actual
-trial. Which of the characters of the two parent forms
-will be the dominant ones, and which recessive, can only be
-determined by experiment. Moreover, the hybrid characters
-are something peculiar to the hybrid itself, and to itself alone,
-and not simply the combination of the characters of the two
-forms. Thus in one case a hybrid from a tall and a short
-variety of pea was even taller than the taller parent variety.
-Bateson lays much emphasis on this point, believing it to be
-an important consideration in all questions relating to hybridization
-and inheritance.</p>
-
-<p class='c010'>The theoretical interpretation that Mendel has put upon
-his results is so extremely simple that there can be little
-doubt that he has hit on the real explanation. The results
-can be accounted for if we suppose that the hybrid produces
-egg-cells and pollen-cells, each of which is the bearer
-of only one of the alternative characters, dominant or recessive
-as the case may be. If this is the case, and if on an
-average there are the same number of egg-cells and pollen-cells,
-having one or the other of these kinds of characters,
-then on a random assortment meeting of egg-cells and
-pollen-cells, Mendel’s law would follow. For, 25 per cent of
-dominant pollen grains would meet with 25 per cent dominant
-egg-cells; 25 per cent recessive pollen grains would meet with
-<span class='pageno' id='Page_285'>285</span>25 per cent recessive egg-cells; while the remaining 50 per
-cent of each kind would meet each other. Or, as Mendel
-showed by the following scheme:—</p>
-<div  class='figcenter id006'>
-<img src='images/i285a.jpg' alt='' class='ig001' />
-</div>
-<p class='c010'>Or more simply by this scheme:—</p>
-<div  class='figcenter id006'>
-<img src='images/i285b.jpg' alt='' class='ig001' />
-</div>
-
-<p class='c010'>Mendel’s results have received confirmation by a number of
-more recent workers, and while in some cases the results
-appear to be complicated by other factors, yet there can
-remain little doubt that Mendel has discovered one of the
-fundamental laws of heredity.</p>
-
-<p class='c010'>It has been found that there are some cases in which the
-sort of inheritance postulated by Mendel’s law does not seem
-to hold, and, in fact, Mendel himself spoke of such cases.
-He found that some kinds of hybrids do not break up in
-later generations into the parent forms. He also points out
-that in cases of discontinuity the variations in each character
-must be separately regarded. In most experiments in crossing,
-forms are chosen which differ from each other in a
-multitude of characters, some of which are continuous and
-others discontinuous, some capable of blending with their
-contraries while others are not. The observer in attempting
-to discover any regularity is confused by the complications
-thus introduced. Mendel’s law could only appear in such
-cases by the use of an overwhelming number of examples
-which are beyond the possibilities of experiment.<a id='r25' /><a href='#f25' class='c017'><sup>[25]</sup></a></p>
-
-<div class='footnote c018' id='f25'>
-<p class='c019'><span class='label'><a href='#r25'>25</a>.&nbsp;&nbsp;</span>This statement is largely taken from Bateson’s book.</p>
-</div>
-
-<p class='c010'>Let us now examine the bearing of these discoveries on
-<span class='pageno' id='Page_286'>286</span>the questions of variation which were raised in the preceding
-pages. It should be pointed out, however, that it would be
-premature to do more than indicate, in the most general
-way, the application of these conclusions. The chief value
-of Mendel’s results lies in their relation to the theory of inheritance
-rather than to that of evolution.</p>
-
-<p class='c010'>In the first place, Mendel’s results indicate that we cannot
-make any such sharp distinction as Darwin does between
-the results of inheritance of discontinuous and of continuous
-variations. As Mendel’s results show, it is the separate
-characters that must be considered in each case, and not
-simply the sum total of characters.</p>
-
-<p class='c010'>The more general objection that Darwin has made may
-appear to hold, nevertheless. He thinks that the evolution of
-animals and plants cannot rest primarily on the appearance
-of discontinuous variations, because they occur rarely and
-would be swamped by intercrossing. If Mendel’s law applies
-to such cases, that is, if a cross were made between
-such a sport and the original form, the hybrid in this case, if
-self-fertilized, would begin to split up into the two original
-forms. But, on the other hand, it could very rarely happen
-that the hybrid did fertilize its own eggs, and, unless this occurred,
-the hybrid, by crossing with the parent forms in each
-generation, would soon lose all its characters inherited from
-its “sport” ancestor. Unless, therefore, other individuals
-gave rise to sports at the same time, there would be little
-chance of producing new species in this way. We see then
-that discontinuity in itself, unless it involved infertility with
-the parent species, of which there is no evidence, cannot be
-made the basis for a theory of evolution, any more than can
-individual differences, for the swamping effect of intercrossing
-would in both cases soon obliterate the new form. If,
-however, a species begins to give rise to a large number of
-individuals of the same kind through a process of discontinuous
-variation, then it may happen that a new form may
-<span class='pageno' id='Page_287'>287</span>establish itself, either because it is adapted to live under conditions
-somewhat different from the parent form, so that the
-dangers of intercrossing are lessened, or because the new
-form may absorb the old one. It is also clear, from what
-has gone before, that the new form can only cease to be fertile
-with the parent form, or with its sister forms, after it has
-undergone such a number of changes that it is no longer
-able to combine the differences in a new individual. This
-result will depend both on the kinds of the new characters, as
-well as the amounts of their difference. This brings us to
-a consideration of the results of De Vries, who has studied
-the first steps in the formation of new species in the “mutations”
-of the evening primrose.</p>
-<h3 class='c014'><span class='sc'>The Mutation Theory of De Vries</span></h3>
-
-<p class='c015'>De Vries defines the mutation theory as the conception
-that “the characters of the organism are made up of elements
-(‘Einheiten’) that are sharply separated from each other.
-These elements can be combined in groups, and in related
-species the same combinations of elements recur. Transitional
-forms like those that are so common in the external
-features of animals and plants do not exist between the
-elements themselves, any more than they do between the
-elements of the chemist.”</p>
-
-<p class='c010'>This principle leads, De Vries says, in the domain of the
-descent theory to the conception that species have arisen
-from each other, not continuously, but by steps. Each new
-step results from a new combination as compared with the old
-one, and the new forms are thereby completely and sharply
-separated from the species from which they have come. The
-new species is all at once there; it has arisen from the parent
-form without visible preparation and without transitional steps.</p>
-
-<p class='c010'>The mutation theory stands in sharp contrast to the selection
-theory. The latter uses as its starting-point the common
-<span class='pageno' id='Page_288'>288</span>form of variability known as individual or fluctuating
-variation; but according to the mutation theory there are two
-kinds of variation that are entirely different from each other.
-“The fluctuating variation can, as I hope to show, not overstep
-the bounds of the species, even after the most prolonged
-selection,—much less can this kind of variation lead to the
-production of new, constant characters.” Each peculiarity
-of the organism has arisen from a preceding one, not
-through the common form of variation, but through a sudden
-change that may be quite small but is perfectly definite.
-This kind of variability that produces new species, De Vries
-calls mutability; the change itself he calls a mutation. The
-best-known examples of mutations are those which Darwin
-called “single variations” or “sports.”</p>
-
-<p class='c010'>De Vries recognizes the following kinds of variation:—</p>
-
-<p class='c010'>First, the polymorphic forms of the systematists. The
-ordinary groups which, following Linnæus, we call species,
-are according to De Vries collective groups, which are the
-outcome of mutations. Many such Linnæan species include
-small series of related forms, and sometimes even large numbers
-of such forms. These are as distinctly and completely
-separated from each other as are the best species. Generally
-these small groups are called varieties, or subspecies,—varieties
-when they are separated by a single striking character,
-subspecies when they differ in the totality of their
-characters, in the so-called habitus.</p>
-
-<p class='c010'>These groups have already been recognized by some
-investigators as elementary species, and have been given corresponding
-binary names. Thus there are recognized two
-hundred elementary species of the form formerly called <i>Draba
-verna</i>.</p>
-
-<p class='c010'>When brought under cultivation these elementary species
-are constant in character and transmit their peculiarities
-truly. They are not local races in the sense that they are
-the outcome in each generation of special external conditions.
-<span class='pageno' id='Page_289'>289</span>Many other Linnæan species are in this respect like <i>Draba
-verna</i>, and most varieties, De Vries thinks, are really elementary
-species.</p>
-
-<p class='c010'>Second, the polymorphism due to intercrossing is the
-outcome of different combinations of hereditary qualities.
-There are here, De Vries says, two important classes of facts
-to be kept strictly apart,—scientific experiment, and the
-results of the gardener and of the cultivator. The experimenter
-chooses for crossing, species as little variable as possible;
-the gardener and cultivator on the other hand prefer
-to cross forms of which one at least is variable, because the
-variations may be transmitted to the hybrid, and in this way
-a new form be produced.</p>
-
-<p class='c010'>New elementary characters arise in experiments in crossing
-only through variability, not through crossing itself.</p>
-
-<p class='c010'>Third, variability in the ordinary sense, that is, individual
-variability, includes those differences between the individual
-organs that follow Quetelet’s theory of chance. This kind
-of variability is characterized by its presence at all times, in
-all groups of individuals.</p>
-
-<p class='c010'>De Vries recalls Galton’s apt comparison between variability
-and a polyhedron which can roll from one face to another.
-When it comes to rest on any particular face, it is in stable
-equilibrium. Small vibrations or disturbances may make it
-oscillate, but it returns always to the same face. These
-oscillations are like the fluctuating variations. A greater
-disturbance may cause the polyhedron to roll over on to a
-new face, where it comes to rest again, only showing the
-ever present fluctuations around its new centre. The new
-position corresponds to a mutation. It may appear from our
-familiarity with the great changes that we associate with the
-idea of discontinuous variability, that a mutation must also
-involve a considerable change. Such, however, De Vries says,
-is not the case. In fact, numerous mutations are smaller
-than the extremes of fluctuating variation. For example, the
-<span class='pageno' id='Page_290'>290</span>different elementary species of <i>Draba verna</i> are less different
-from each other than the forms of leaves on a tree. The
-essential differences between the two kinds of variation is
-that the mutation is constant, while the continuous variation
-fluctuates back and forth.</p>
-
-<p class='c010'>The following example is given by De Vries to illustrate the
-general point of view in regard to varieties and species. The
-species <i>Oxalis corniculata</i> is a “collective” species that lives
-in New Zealand. It has been described as having seven well-characterized
-varieties which do not live together or have intermediate
-forms. If we knew only this group, there would
-be no question that there are seven good species. But in
-other countries intermediate forms exist, which exactly bridge
-over the differences between the seven New Zealand forms.
-For this reason all the forms have been united in a single
-species.</p>
-
-<p class='c010'>Another example is that of the fern, <i>Lomaria procera</i>, from
-New Zealand, Australia, South Africa, and South America.
-If the forms from only one country be considered, they appear
-to be different species; but if all the forms from the different
-parts of the world be taken into account, they constitute a
-connected group, and are united into one large species.</p>
-
-<p class='c010'>It will be seen, therefore, that the limits of a collective
-species are determined solely by the deficiencies in the genealogical
-tree of the elementary species. If all the elementary
-species in one country were destroyed, then the forms
-living in other countries that had been previously held
-together because of those which have now been destroyed,
-would, after the destruction, become true species. In other
-words: “The Linnæan species are formed by the disappearance
-of other elementary species, which at first connected
-all forms. This mode of origin is a purely historical process,
-and can never become the subject of experimental investigation.”
-Spencer’s famous expression, the “survival of the
-fittest,” is incomplete, and should read the “survival of the
-<span class='pageno' id='Page_291'>291</span>fittest species.” It is, therefore, not the study of Linnæan
-species that has a physiological interest, but it is the study
-of the elementary species of which the Linnæan species are
-made up, that furnishes the all-important problem for experimental
-study.</p>
-
-<p class='c010'>De Vries gives a critical analysis of a number of cases in
-which new races have been formed under domestication. He
-shows very convincingly that, whenever the result has been
-the outcome of the selection of fluctuating variations, the
-product that is formed can only be kept to its highest point
-of development by the most rigid and ever watchful care.
-If selection ceases for only a few generations, the new form
-sinks back at once to its original level. Many of our cultivated
-plants have really arisen, not by selection of this
-sort, but by mutations; and there are a number of recorded
-cases where the first and sudden appearance of a new form
-has been observed. In such cases as these there is no need
-for selection, for if left to themselves there is no return to the
-original form. If, however, after a new mutation has appeared
-in this way, we subject its fluctuating variations to
-selection, we can keep the new form up to its most extreme
-limit, but can do nothing more.</p>
-
-<p class='c010'>Another means, frequently employed, by which new varieties
-have been formed is by bringing together different elementary
-species under cultivation. For instance, there are a
-large number of wild elementary species of apples, and De
-Vries believes that our different races of apples owe their
-origin in part to these different wild forms. Crossing, cultivation,
-and selection have done the rest.</p>
-
-<p class='c010'>De Vries points out some of the inconsistencies of those
-who have attempted to discriminate between varieties and
-species. The only rule that can be adhered to is that a
-variety differs from a species to which it belongs in only one
-or in a few characters. Most so-called varieties in nature are
-really elementary species, which differ from their nearest
-<span class='pageno' id='Page_292'>292</span>relatives, not in one character only, but in nearly all their
-characters. There is no ground, De Vries states, for believing
-them to be varieties. If it is found inconvenient to rank
-them under the names of the old Linnæan species, it will be
-better, perhaps, to treat them as subspecies, but De Vries
-prefers to call them elementary species.</p>
-
-<p class='c010'>In regard to the distribution of species in nature, it may be
-generally stated that the larger the geographical domain so
-much the larger is the number of elementary species. They
-are found to be heaped up in the centre of their area of distribution,
-but are more scattered at the periphery.</p>
-
-<p class='c010'>In any one locality each Linnæan species has as a rule
-only one or a few elementary species. The larger the area
-the more numerous the forms. From France alone Jordan
-had brought together in his garden 50 elementary species of
-<i>Draba verna</i>. From England, Italy, and Austria there could
-be added 150 more. This polymorphism is, De Vries thinks,
-a general phenomenon, although the number of forms is seldom
-so great as in this case.</p>
-
-<p class='c010'>Amongst animals this great variety of forms is not often
-met with, yet amongst the mammalia and birds of North
-America there are many cases of local forms or races, some
-of which at least are probably mutations. This can only be
-proven, however, by actually transferring the forms to new
-localities in order to find out if they retain their original characters,
-or become changed into another form. It seems not
-improbable that many of the forms are not the outcome of
-the external conditions under which the animal now lives,
-but would perpetuate themselves in a new environment.</p>
-
-<p class='c010'>From the evidence that his results have given, De Vries
-believes it is probable that mutation has occurred in all directions.
-In the same way that Darwin supposed that individual
-or fluctuating variations are scattering, so also De Vries
-believes that the new forms that arise through mutation are
-scattering. On this point it seems to me that De Vries may
-<span class='pageno' id='Page_293'>293</span>be too much prejudiced by his results with the evening primrose.
-If, as he supposes, many forms, generally ranked as
-varieties, are really elementary species, it seems more probable
-that the mutation of a form may often be limited to the
-production of one or of only a very few new forms. The
-single variations, or sports, point even more strongly in favor
-of this interpretation. Moreover, the general problem of
-evolution from a purely theoretical point of view is very
-much simplified, if we assume that the kinds of mutating
-forms may often be very limited, and that mutations may
-often continue to occur in a direct line. On this last point,
-De Vries argues that the evidence from paleontology cannot
-be trusted, for all that we can conclude from fossil remains
-is that certain mutations have dominated, and have been sufficiently
-abundant to leave a record. In other words, the conditions
-may have been such that only certain forms could
-find a foothold.</p>
-
-<p class='c010'>De Vries asks whether there are for each species periods
-of mutation when many and great changes take place, and
-periods when relatively little change occurs. The evidence
-upon which to form an opinion is scanty, but De Vries is
-inclined to think that such periods do occur. It is at least
-certain from our experience that there are long periods when
-we do not see new forms arising, while at other times,
-although we know very few of them, epidemics of change may
-take place. The mutative period which De Vries found in
-the evening primrose is the best-known example of such a
-period of active mutation. Equally important for the descent
-theory is the idea that the same mutation may appear time
-after time. There is good evidence to show that this really
-occurs, and in consequence the chances for the perpetuation of
-such a form are greatly increased. Delbœuf, who advocated
-this idea of the repeated reappearance of a new form, has
-also attempted to show that if this occurs the new form may
-become established without selection of any kind taking place,—the
-<span class='pageno' id='Page_294'>294</span>time required depending upon the frequency with
-which the new form appears. This law of Delbœuf, De Vries
-believes, is correct from the point of view of the mutation
-theory. It explains, in a very simple way, the existence of
-numerous species-characters that are entirely useless, such,
-for instance, as exist between the different elementary species
-of <i>Draba verna</i>. “According to the selection theory only
-useful characters can survive; according to the mutation
-theory, useless characters also may survive, and even those
-that may be hurtful to a small degree.”</p>
-
-<p class='c010'>We may now proceed to examine the evidence from which
-De Vries has been led to the general conclusions given in
-the preceding pages. De Vries found at Hilversam, near
-Amsterdam, a locality where a number of plants of the evening
-primrose, <i>Œnothera lamarckiana</i>, grow in large numbers.
-This plant is an American form that has been imported into
-Europe. It often escapes from cultivation, as is the case at
-Hilversam, where for ten years it had been growing wild.
-Its rapid increase in numbers in the course of a few years
-may be one of the causes that has led to the appearance of a
-mutation period. The escaped plants showed fluctuating
-variations in nearly all of their organs. They also had produced
-a number of abnormal forms. Some of the plants
-came to maturity in one year, others in two, or in rare cases
-in three, years.</p>
-
-<p class='c010'>A year after the first finding of these plants De Vries
-observed two well-characterized forms, which he at once recognized
-as new elementary species. One of these was <i>O. brevistylis</i>,
-which occurred only as female plants. The other new
-species was a smooth-leafed form with a more beautiful foliage
-than <i>O. lamarckiana</i>. This is <i>O. lævifola</i>. It was found
-that both of these new forms bred true from self-fertilized
-seeds. At first only a few specimens were found, each form
-in a particular part of the field, which looks as though each
-might have come from the seeds of a single plant.</p>
-
-<div class='nf-center-c0'>
-<div class='nf-center c006'>
-    <div><span class='pageno' id='Page_295'>295</span>ŒNOTHERA LAMARCKIANA</div>
-    <div class='c000'><span class='sc'>Elementary Species</span></div>
-  </div>
-</div>
-
-<div  class='figcenter id007'>
-<img src='images/p309.jpg' alt='' class='ig001' />
-</div>
-<p class='c009'>These two new forms, as well as the common <i>O. lamarckiana</i>,
-were collected, and from these plants there have
-arisen the three groups or families of elementary species that
-De Vries has studied. In his garden other new forms also
-arose from those that had been brought under cultivation.
-The largest group and the most important one is that from
-the original <i>O. lamarckiana</i> form. The accompanying table
-<span class='pageno' id='Page_296'>296</span>shows the mutations that arose between 1887 and 1899
-from these plants. The seeds were selected in each case
-from self-fertilized plants of the <i>lamarckiana</i> form, so that the
-new plants appearing in each horizontal line are the descendants
-in each generation of <i>lamarckiana</i> parents. It will be
-observed that the species, <i>O. oblongata</i>, appeared again and
-again in considerable numbers, and the same is true for
-several of the other forms also. Only the two species, <i>O.
-gigas</i> and <i>O. scintillans</i>, appeared very rarely.</p>
-
-<p class='c010'>Thus De Vries had, in his seven generations, about fifty
-thousand plants, and about eight hundred of these were mutations.
-When the flowers of the new forms were artificially
-fertilized with pollen from the flowers on the same plant, or
-of the same kind of plant, they gave rise to forms like themselves,
-thus showing that they are true elementary species.<a id='r26' /><a href='#f26' class='c017'><sup>[26]</sup></a>
-It is also a point of some interest to observe that all these forms
-differed from each other in a large number of particulars.</p>
-
-<div class='footnote c018' id='f26'>
-<p class='c019'><span class='label'><a href='#r26'>26</a>.&nbsp;&nbsp;</span><i>O. lata</i> is always female, and cannot, therefore, be self-fertilized. When
-crossed with <i>O. lamarckiana</i> there is produced fifteen to twenty per cent of
-pure <i>lata</i> individuals.</p>
-</div>
-
-<p class='c010'>Only one form, <i>O. scintillans</i>, that appeared eight times, is
-not constant as are the other species. When self-fertilized
-its seeds produce always three other forms, <i>O. scintillans</i>,
-<i>O. oblongata</i>, and <i>O. lamarckiana</i>. It differs in this respect
-from all the other elementary species, which mutate not more
-than once in ten thousand individuals.</p>
-
-<p class='c010'>From the seeds of one of the new forms, <i>O. lævifolia</i>,
-collected in the field, plants were reared, some of which were
-<i>O. lamarckiana</i> and others <i>O. lævifolia</i>. They were allowed
-to grow together, and their descendants gave rise to the same
-forms found in the <i>lamarckiana</i> family, described above,
-namely, <i>O. lata</i>, <i>elliptica</i>, <i>nannella</i>, <i>rubrinervis</i>, and also two
-new species, <i>O. spatulata</i> and <i>leptocarpa</i>.</p>
-
-<p class='c010'>In the <i>lata</i> family, only female flowers are produced, and,
-therefore, in order to obtain seeds they were fertilized with
-<span class='pageno' id='Page_297'>297</span>pollen from other species. Here also appeared some of the
-new species, already mentioned, namely, <i>albida</i>, <i>nannella</i>,
-<i>lata</i>, <i>oblongata</i>, <i>rubrinervis</i>, and also two new species, <i>elliptica</i>
-and <i>subovata</i>.</p>
-
-<p class='c010'>De Vries also watched the field from which the original
-forms were obtained, and found there many of the new
-species that appeared under cultivation. These were found,
-however, only as weak young plants that rarely flowered.
-Five of the new forms were seen either in the Hilversam
-field, or else raised from seeds that had been collected there.
-These facts show that the new species are not due to cultivation,
-and that they arise year after year from the seeds of
-the parent form, <i>O. lamarckiana</i>.</p>
-<h3 class='c014'><span class='sc'>Conclusions</span></h3>
-
-<p class='c015'>From the evidence given in the preceding pages it appears
-that the line between fluctuating variations and mutations
-may be sharply drawn. If we assume that mutations
-have furnished the material for the process of evolution, the
-whole problem appears in a different light from that in which
-it was placed by Darwin when he assumed that the fluctuating
-variations are the kind which give the material for evolution.</p>
-
-<p class='c010'>From the point of view of the mutation theory, species are
-no longer looked upon as having been slowly built up through
-the selection of individual variations, but the elementary
-species, at least, appear at a single advance, and fully formed.
-This need not necessarily mean that great changes have suddenly
-taken place, and in this respect the mutation theory is
-in accord with Darwin’s view that <i>extreme</i> forms that rarely
-appear, “sports,” have not furnished the material for the
-process of evolution.</p>
-
-<p class='c010'>As De Vries has pointed out, each mutation may be different
-from the parent form in only a slight degree for each point,
-although all the points may be different. The most unique
-<span class='pageno' id='Page_298'>298</span>feature of these mutations is the constancy with which the
-new form is inherited. It is this fact, not previously fully appreciated,
-that De Vries’s work has brought prominently into
-the foreground. There is another point of great interest in
-this connection. Many of the groups that Darwin recognized
-as varieties correspond to the elementary species of De Vries.
-These varieties, Darwin thought, are the first stages in the formations
-of species, and, in fact, cannot be separated from
-species in most cases. The main difference between the
-selection theory and the mutation theory is that the one supposes
-these varieties to arise through selection of individual
-variations, the other supposes that they have arisen spontaneously
-and at once from the original form. The development
-of these varieties into new species is again supposed, on the
-Darwinian theory, to be the result of further selection, on the
-mutation theory, the result of the appearance of new mutations.</p>
-
-<p class='c010'>In consequence of this difference in the two theories, it
-will not be difficult to show that the mutation theory escapes
-some of the gravest difficulties that the Darwinian theory
-has encountered. Some of the advantages of the mutation
-theory may be briefly mentioned here.</p>
-
-<p class='c010'>1. Since the mutations appear fully formed from the beginning,
-there is no difficulty in accounting for the incipient
-stages in the development of an organ, and since the organ
-may persist, even when it has no value to the race, it may become
-further developed by later mutations and may come to
-have finally an important relation to the life of the individual.</p>
-
-<p class='c010'>2. The new mutations may appear in large numbers, and
-of the different kinds those will persist that can get a foothold.
-On account of the large number of times that the
-same mutations appear, the danger of becoming swamped
-through crossing with the original form will be lessened in
-proportion to the number of new individuals that arise.</p>
-
-<p class='c010'>3. If the time of reaching maturity in the new form is
-different from that in the parent forms, then the new species
-<span class='pageno' id='Page_299'>299</span>will be kept from crossing with the parent form, and since this
-new character will be present from the beginning, the new form
-will have much better chances of surviving than if a difference
-in time of reaching maturity had to be gradually acquired.</p>
-
-<p class='c010'>4. The new species that appear may be in some cases
-already adapted to live, in a different environment from that
-occupied by the parent form; and if so, it will be isolated
-from the beginning, which will be an advantage in avoiding
-the bad effects of intercrossing.</p>
-
-<p class='c010'>5. It is well known that the differences between related
-species consists largely in differences of unimportant organs,
-and this is in harmony with the mutation theory, but one of
-the real difficulties of the selection theory.</p>
-
-<p class='c010'>6. Useless or even slightly injurious characters may appear
-as mutations, and if they do not seriously affect the perpetuation
-of the race, they may persist.</p>
-
-<p class='c010'>In Chapters X and XI, an attempt will be made to point
-out in detail the advantages which the mutation theory has
-over the Darwinian theory.</p>
-
-<div class='pbb'>
- <hr class='pb c006' />
-</div>
-<div class='chapter'>
-  <span class='pageno' id='Page_300'>300</span>
-  <h2 class='c008'>CHAPTER IX<br /> <br /><span class='c013'>EVOLUTION AS THE RESULT OF EXTERNAL AND INTERNAL FACTORS</span></h2>
-</div>
-<p class='c009'><span class='sc'>We</span> come now to a consideration of other theories that
-have been advanced to account for the evolution of new
-forms; and in so far as these new forms are adapted to
-their environment, the theories will bear directly on the
-question of the origin of adaptive variations. One school
-of transformationists has made the external world and the
-changes taking place in it the source of new variations.
-Another school believes that the changes arise within the
-organism itself. We may examine these two points of view
-in turn.</p>
-<h3 class='c014'><span class='sc'>The Effect of External Influences</span></h3>
-
-<p class='c015'>We have already seen that Lamarck held as a part of his
-doctrine of transformation that the changes in the external
-world, the environment, bring about, directly, changes in the
-organism, and he believed that all plants and many of
-the lower animals have evolved as the result of a reaction of
-this sort. This idea did not originate with Lamarck, however,
-since before him Buffon had advanced the same hypothesis,
-and there cannot be much doubt that Lamarck
-borrowed from his patron, Buffon, this part of his theory
-of evolution.</p>
-
-<p class='c010'>This idea of the influence of the external world as a factor
-inducing changes in the organism has come, however, to be
-associated especially with the name of Geoffroy Saint-Hilaire,
-whose period of activity, although overlapping, came after
-<span class='pageno' id='Page_301'>301</span>that of Lamarck. The central idea of Geoffroy’s view was
-that species of animals and plants undergo change as the
-environment changes; and it is important to note, in passing,
-that he did not suppose that these changes were always for
-the benefit of the individual, <i>i.e.</i> they were not always adaptive.
-If they were not, the forms became extinct. So long
-as the conditions remain constant, the species remains constant;
-and he found an answer in this to Cuvier’s argument,
-in respect to the similarity between the animals living at
-present in Egypt and those discovered embalmed along with
-mummies at least two thousand years old. Geoffroy Saint-Hilaire
-said, that since the climatic conditions of Egypt
-had remained exactly the same during all these years, the
-animals of Egypt would also have remained unchanged.</p>
-
-<p class='c010'>Geoffroy’s views were largely influenced by his studies in
-systematic zoology and by his conception of a unity of plan
-running through the entire animal kingdom. His study of
-embryology and paleontology had led him to believe that
-present forms have descended from other organisms living in
-the past, and in this connection his discovery of teeth in the
-jaws of the embryo of the baleen whale and also his discovery
-of the embryonic dental ridges in the upper and in
-the lower jaws of birds, were used with effect in supporting
-the theory of change or evolution. Lastly, his remarkable
-work in the study of abnormal forms prepared the way for
-his conception of sudden and great changes, which he believed
-organisms capable of undergoing. He went so far in
-fact, in one instance, as to suppose that it was not impossible
-that a bird might have issued fully equipped from the egg of
-a crocodile. Such an extreme statement, which seems to us
-nowadays only laughable, need not prejudice us against the
-more moderate parts of his speculation.</p>
-
-<p class='c010'>His study of the fossil gavials found near Caen led him
-to believe that they are quite distinct from living crocodiles.
-He asked whether these old forms may not represent a link
-<span class='pageno' id='Page_302'>302</span>in the chain that connects, without interruption, the older
-inhabitants of the earth with animals living at the present
-time. Without positively affirming that this is the case, he
-did not hesitate to state that a transformation of this sort
-seemed possible to him. He said: “I think that the process
-of respiration constitutes an acquirement so important in the
-‘disposition’ of the forms of animals, that it is not at all
-necessary to suppose that the surrounding respiratory gases
-become modified quickly and in large amount in order that
-the animal may become slowly modified. The prolonged
-action of time would ordinarily suffice, but if combined with
-a cataclysm, the result would be so much the better.”</p>
-
-<p class='c010'>He supposed that in the course of time respiration becomes
-difficult and finally impossible as far as certain systems of
-organs are concerned. The necessity then arises and creates
-another arrangement, perfecting or altering the existing structures.
-Modifications, fortunate or fatal, are created which
-through propagation are continued, and which, if fortunate,
-influence all the rest of the organization. But if the modifications
-are injurious to the animals in which they have appeared,
-the animals cease to exist, and are replaced by others having
-a different form, and one suited to the new circumstances.</p>
-
-<p class='c010'>The comparison between the stages of development of the
-individual and the evolution of the species was strongly impressed
-on the mind of Geoffroy. He says: “We see, each
-year, the spectacle of the transformation in organization from
-one class into another. A batrachian is at first a fish under
-the name of a tadpole, then a reptile (amphibian) under that
-of a frog.” “The development, or the result of the transformation,
-is brought about by the combined action of light
-and of oxygen; and the change in the body of the animal
-takes place by the production of new blood-vessels, whose
-development follows the law of the balancing of organs,
-in the sense, that if the circulating fluids precipitate themselves
-into new channels there remains less in the old
-<span class='pageno' id='Page_303'>303</span>vessels.” By preventing tadpoles from leaving the water,
-Geoffroy claims that it has been shown that they can be
-prevented from changing into frogs. The main point that
-Geoffroy attempts to establish is no doubt fairly clear, but
-the way in which he supposes the change to be effected is
-not so clear, and his ideas as to the way in which new change
-may be perpetuated in the next generation are, from our more
-modern point of view, extremely hazy. It is perhaps not
-altogether fair to judge his view from the standpoint of the
-origin of adaptive structures, but rather as an attempt to
-explain the causes that have brought about the evolution of
-the organic world.</p>
-
-<p class='c010'>During the remainder of the nineteenth century there
-accumulated a large number of facts in relation to the action
-of the external conditions in bringing about changes in
-animals and plants. Much of this evidence is of importance
-in dealing with the question of the origin of organic
-adaptation.</p>
-
-<p class='c010'>The first class of facts in this connection is that of geographical
-variation in animals and plants. It will be impossible
-here to do more than select some of the most
-important cases. De Varigny, in his book on “Experimental
-Evolution,” has brought together a large number of facts of
-this kind, and from his account the following illustrations
-have been selected. He says: “When the small brown
-honey-bee from High Burgundy is transported into Bresse—although
-not very distant—it soon becomes larger and
-assumes a yellow color; this happens even in the second
-generation.” It is also pointed out that the roots of the
-beet, carrot, and radish are colorless in their wild natural
-state, but when brought under cultivation they become red,
-yellow, etc. Vilmorin has noted that the red, yellow, and
-violet colors of carrots appear only some time after the wild
-forms have been brought under cultivation. Moquin-Tandon
-has seen “gentians which are blue in valleys become white
-<span class='pageno' id='Page_304'>304</span>on mountains.” Other cases also are on record in which the
-colors of a plant are dependent on external conditions.</p>
-
-<p class='c010'>The sizes of plants and animals are also often directly traceable
-to certain external conditions; the change is generally
-connected with the amount of food obtainable. “Generally
-speaking,” De Varigny says, “insular animals are smaller
-than their continental congeners. In the Canary Islands
-the oxen of one of the smallest islands are smaller than
-those on the others, although all belong to the same breed,
-and the horses are also smaller, and the indigenous inhabitants
-are in the same case, although belonging to a tall race. It
-would seem that in Malta elephants were very small,—fossil
-elephants, of course,—and that during the Roman period
-the island was noted for a dwarf breed of dogs, which was
-named after its birthplace, according to Strabo. In Corsica,
-also, horses and oxen are very small, and <i>Cervus corsicanus</i>,
-the indigenous deer, is quite reduced in dimensions; ...
-and lastly, the small dimensions of the Falkland horses—imported
-from Spain in 1764—are familiar to all. The
-dwarf rabbits of Porto Santo described by Darwin may also
-be cited as a case in point.”</p>
-
-<p class='c010'>These facts, interesting as they are, will, no doubt, have to
-be more carefully examined before the evidence can have
-great value, for it is not clear what factor or factors have
-produced the decrease in size of these animals.</p>
-
-<p class='c010'>The following cases show more clearly the immediate
-effect of the environment: “Many animals, when transferred
-to warm climates, lose their wool, or their hairy covering
-is much reduced. In some parts of the warmer regions
-of the earth, sheep have no wool, but merely hairs like those
-of dogs. Similarly, as Roulin notices, poultry have, in
-Columbia, lost their feathers, and while the young are at first
-covered with a black and delicate down, they lose it in great
-part as they grow, and the adult fowls nearly realize Plato’s
-realistic description of man—a biped without feathers.
-<span class='pageno' id='Page_305'>305</span>Conversely, many animals when transferred from warm to
-cold climates acquire a thicker covering; dogs and horses, for
-instance, becoming covered with wool.”</p>
-
-<p class='c010'>A number of kinds of snails that were supposed to belong
-to different species have been found, on further examination,
-to be only varieties due to the environment. “Locard has
-discovered through experiments that <i>L. turgida</i> and <i>elophila</i>
-are mere varieties—due to environment—of the common
-<i>Lymnæa stagnalis</i>.” He says, “These are not new species,
-but merely common aspects of a common type, which is
-capable of modification and of adaptation according to the
-nature of the media in which it has to live.” It has also
-been shown by Bateson that similar changes occur in
-<i>Cardium edule</i>, and other lamellibranchs are known to vary
-according to the nature of the water in which they live.</p>
-
-<p class='c010'>In regard to plants, the influence of the environment has
-long been known to produce an effect on the form, color,
-etc., of the individuals. “The common dandelion (<i>Taraxacum
-densleonis</i>) has in dry soil leaves which are much more
-irregular and incised, while they are hardly dentate in marshy
-stations, where it is called <i>Taraxacum palustre</i>.</p>
-
-<p class='c010'>“Individuals growing near the seashore differ markedly
-from those growing far inland. Similarly, species such as
-some Ranunculi, which can live under water as well as in
-air, exhibit marked differences when considered in their
-different stations, as is well known to all. These differences
-may be important enough to induce botanists to believe in
-the existence of two different species when there is only
-one.”</p>
-
-<p class='c010'>An interesting case is that of <i>Daphnia rectirostris</i>, a small
-crustacean living sometimes in fresh water, at other times
-in water containing salt and also in salt lakes. There are
-two forms, corresponding to the conditions under which they
-live, and it is said that the differences are of a kind that
-suffice to separate species from each other. In another
-<span class='pageno' id='Page_306'>306</span>crustacean, <i>Branchipus ferox</i>, the form differs in a number
-of points, according to whether it lives in salt or in fresh
-water. Schmankewitsch says that, had he not found all
-transitional forms, and observed the transformation in
-cultures, he would have regarded the two forms as separate
-species. The oft-quoted case of Artemia furnishes a very
-striking example of the influence of the environment.
-<i>Artemia salina</i> lives in water whose concentration varies
-between 5 and 12 degrees of saltness. When the amount
-of salt is increased to 12 degrees, the animal shows certain
-characteristics like those of <i>Artemia milhausenii</i>, which
-may live in water having 24 to 25 degrees of saltness. The
-form <i>A. salina</i> may be further completely changed into that
-of <i>A. milhausenii</i> by increasing the amount of salt to the latter
-amount.</p>
-
-<p class='c010'>Among domesticated animals and plants—a few instances
-of which have been already referred to—we find a large
-number of cases in which a change in the environment
-produces definite changes in the organism. Darwin has
-made a most valuable collection of facts of this kind in his
-“Animals and Plants under Domestication.” He believes
-that domesticated forms are much more variable than wild
-ones, and that this is due, in part, to their being protected
-from competition, and to their having been removed from
-their natural conditions and even from their native country.
-“In conformity with this, all our domesticated productions
-without exception vary far more than natural species. The
-hive-bee, which feeds itself, and follows in most respects
-its natural habits of life, is the least variable of all domesticated
-animals.... Hardly a single plant can be named,
-which has long been cultivated and propagated by seed, that
-is not highly variable.” “Bud-variation ... shows us that
-variability may be quite independent of seminal reproduction,
-and likewise of reversion to long-lost ancestral characters.
-No one will maintain that the sudden appearance of
-<span class='pageno' id='Page_307'>307</span>a moss-rose on a Provence rose is a return to a former
-state, ... nor can the appearance of nectarines on peach
-trees be accounted for on the principle of reversion.” It is
-said that bud-variations are also much more frequent on
-cultivated than on wild plants.</p>
-
-<p class='c010'>Darwin adds: “These general considerations alone render
-it probable that variability of every kind is directly or indirectly
-caused by changed conditions of life. Or to put the
-case under another point of view, if it were possible to expose
-all the individuals of a species during many generations to
-absolutely uniform conditions of life, there would be no
-variability.”</p>
-
-<p class='c010'>In some cases it has been observed that, in passing from
-one part of a continent to another, many or all of the forms
-of the same group and even of different groups change in
-the same way. Allen’s account of the variations in North
-American birds and mammals furnishes a number of striking
-examples of this kind of change. He finds that, as
-a rule, the birds and mammals of North America increase
-in size from the south northward. This is true, not only
-for the individuals of the same species, but generally the
-largest species of each genus are in the north. There
-are some exceptions, however, in which the increase in size
-is in the opposite direction. The explanation of this is
-that the largest individuals are almost invariably found in
-the region where the group to which the species belongs
-receives its greatest numerical development. This Allen
-interprets as the hypothetical “centre of distribution of the
-species,” which is in most cases doubtless also its original
-centre of dispersal. If the species has arisen in the north,
-then the northern forms are the largest; but if it arose in
-the south, the reverse is the case. Thus, most of the species
-of North America that live north of Mexico are supposed
-to have had a northern origin, as shown by the circumpolar
-distribution of some of them and by the relationship of
-<span class='pageno' id='Page_308'>308</span>others to Old World species; and in these the largest individuals
-of the species of a genus are northern. Conversely,
-in the exceptional cases of increase in size toward the south,
-it can be shown that the forms have probably had a southern
-origin.</p>
-
-<p class='c010'>The Canidæ (wolves and foxes) have their largest representatives,
-the world over, in the north. “In North America
-the family is represented by six species, the smallest of which
-(speaking generally) are southern and the largest northern.”
-The three species that have the widest ranges (the gray
-wolf, the common fox, and the gray fox) show the most
-marked differences in size. The skull, for instance, of “the
-common wolf is fully one-fifth larger in the northern parts
-of British America and Alaska than it is in northern
-Mexico, where it finds the southern limit of its habitat.
-Between the largest northern skull and the largest southern
-skull there is a difference of about thirty-five per cent of
-the mean size. Specimens from the intermediate region
-show a gradual intergradation between the extremes, although
-many of the examples from the upper Missouri country are
-nearly as large as those from the extreme north.” The
-common fox is about one-tenth larger, on the average, in
-Alaska than it is in New England. The gray fox, whose
-habitat extends from Pennsylvania southward to Yucatan,
-has an average length of skull of about five inches in the
-north, and less than four in Central America—about ten
-per cent difference.</p>
-
-<p class='c010'>The Felidæ, or cats, “reach their greatest development as
-respects both the number and the size of the species in the
-intertropical regions. This family has sent a single typical
-representative, the panther (<i>Felis concolor</i>), north of Mexico,
-and this ranges only to about the northern boundary of the
-United States. The other North American representatives
-of the family are the lynxes, which in some of their varieties
-range from Alaska to Mexico.” Although they vary greatly
-<span class='pageno' id='Page_309'>309</span>in different localities in color and in length and texture of
-pelage, they do not vary as to the size of their skulls. On
-the other hand the panther (and the ocelots) greatly increases
-in size southward, “or toward the metropolis of the family.”</p>
-
-<p class='c010'>Other carnivora that increase in size northward are the
-badger, the marten, the fisher, the wolverine, and the ermine,
-which are all northern types.</p>
-
-<p class='c010'>Deer are also larger in the north; in the Virginia deer the
-annually deciduous antlers of immense size reach their greatest
-development in the north. The northern race of flying
-squirrels is one-half larger than the southern, “yet the two
-extremes are found to pass so gradually one into the other,
-that it is hardly possible to define even a southern and a
-northern geographical race.” The species ranges from the
-arctic regions to Central America.</p>
-
-<p class='c010'>In birds also similar relations exist, but there is less often
-an increase in size northward. In species whose breeding
-station covers a wide range of latitude, the northern birds
-are not only smaller, but have quite different colors, as is
-markedly the case in the common quail, the meadow-lark,
-the purple grackle, the red-winged blackbird, the flicker, the
-towhee bunting, the Carolina dove, and in numerous other
-species. The same difference is also quite apparent in the
-blue jay, the crow, in most of the woodpeckers, in the titmice,
-numerous sparrows, and several warblers and thrushes.
-The variation often amounts to from ten to fifteen per cent
-of the average size of the species.</p>
-
-<p class='c010'>Allen also states that certain parts of the animal may vary
-proportionately more than the general size, there being an
-apparent tendency for peripheral parts to enlarge toward the
-warmer regions, <i>i.e.</i> toward the south. “In mammals which
-have the external ears largely developed—as in the wolves,
-foxes, some of the deer, and especially the hares—the larger
-size of this organ in southern as compared with northern individuals
-of the same species, is often strikingly apparent.”
-<span class='pageno' id='Page_310'>310</span>It is even more apparent in species inhabiting open plains.
-The ears of the gray rabbit of the plains of western Arizona
-are twice the size of those of the Eastern states.</p>
-
-<p class='c010'>In birds the bill especially, but also the claws and tail,
-is larger in the south. In passing from New England
-southward to Florida the bill in slender-billed forms becomes
-larger, longer, more attenuated, and more decurved;
-while in short-billed forms the southern individuals have
-thicker and larger bills, although the birds themselves are
-smaller.</p>
-
-<p class='c010'>The remarkable changes and gradations of color in birds
-in different parts of North America are very instructive, and
-the important results obtained by American ornithologists
-form an interesting chapter in zoology. The evidence would
-convince the most sceptical of the difficulty of distinguishing
-between Linnæan species. It is not surprising to find in this
-connection a leading ornithologist exclaiming, “if there really
-are such things as species.” The differences here noted are
-mainly from east to west. We may briefly review here a
-few striking cases selected from Coues’s “Key to North
-American Birds.”</p>
-
-<p class='c010'>The flicker, or golden-winged woodpecker (<i>Colaptes auratus</i>),
-has a wide distribution in eastern North America. It
-is replaced in western North America (from the Rocky
-Mountains to the Pacific) by <i>C. mexicanus</i>. In the intermediate
-regions, Missouri and the Rocky Mountain region,
-the characters of the two are blended in every conceivable
-degree in different specimens. “Perhaps it is a hybrid, and
-perhaps it is a transitional form, and doubtless there are no
-such things as species in Nature.... In the west you will
-find specimens <i>auratus</i> on one side of the body, <i>mexicanus</i>
-on the other.” There is a third form, <i>C. chrysoides</i>, with
-the wings and tail as in <i>auratus</i>, and the head as in <i>mexicanus</i>,
-that lives in the valley of the Colorado River, Lower
-California, and southward.</p>
-
-<p class='c010'><span class='pageno' id='Page_311'>311</span>In regard to the song-sparrow (<i>Melospiza</i>), Coues writes:
-“The type of the genus is the familiar and beloved song-sparrow,
-a bird of constant characters in the east, but in the
-west is split into numerous geographical races, some of them
-looking so different from typical <i>fasciata</i> that they have been
-considered as distinct species, and even placed in other
-genera. This differentiation affects not only their color, but
-the size, relative proportions of parts, and particularly the
-shape of the bill; and it is sometimes so great, as in the case
-of <i>M. cinerea</i>, that less dissimilar looking birds are commonly
-assigned to different genera. Nevertheless the gradation is
-complete, and affected by imperceptible degrees.... The
-several degrees of likeness and unlikeness may be thrown
-into true relief better by some such expressions as the following,
-than by formal antithetical phrases: (1) The common
-eastern bird commonly modified in the interior into the duller
-colored (2) <i>fallax</i>. This in the Pacific watershed, more decidedly
-modified by deeper coloration,—broader black
-streaks in (3) <i>hermanni</i>, with its diminutive local race
-(4) <i>samuelis</i>, and more ruddy shades in (5) <i>guttata</i> northward,
-increasing in intensity with increased size in (6) <i>rafina</i>.
-Then the remarkable (7) <i>cinerea</i>, insulated much further
-apart than any of the others. A former American school
-would probably have made four ‘good species,’ (1) <i>fasciata</i>,
-(2) <i>samuelis</i>, (3) <i>rafina</i>, (4) <i>cinerea</i>.”</p>
-
-<p class='c010'>Somewhat similar relations are found in three other genera
-of finches. Thus Passerella is “imperfectly differentiated”;
-Junco is represented by one eastern species, but in
-the west the stock splits up into numerous forms, “all of
-which intergrade with each other and with the eastern bird.
-Almost all late writers have taken a hand at Junco, shuffling
-them about in the vain attempt to decide which are ‘species’
-and which ‘varieties.’ All are either or both, as we may
-elect to consider them.” In the distribution of the genus
-Pipilo similar relations are found. There is an eastern form
-<span class='pageno' id='Page_312'>312</span>much more distinct from the western forms than these are
-from each other.</p>
-
-<p class='c010'>Finally may be mentioned the curious variations in
-screech-owls of the genus Scops. This owl has two strikingly
-different plumages—a mottled gray and a reddish
-brown, which, although very distinct when fully developed,
-yet “are entirely independent of age, season, or sex.” There
-is an eastern form, <i>Scops asio</i>, that extends west to the
-Rocky Mountains. There is a northwestern form, <i>S. kennicotti</i>,
-which in its red phase is quite different from <i>S. asio</i>,
-but in its gray plumage is very similar. The California form,
-<i>S. benderii</i>, is not known to have a red phase, and the gray
-phase is quite different from that of <i>S. asio</i>, but like the last
-form. The Colorado form, <i>S. maxwellæ</i>, has no red phase,
-“but on the contrary the whole plumage is very pale, almost
-as if bleached, the difference evident in the nestlings even.”
-The Texas form, <i>S. maselli</i>, has both phases, and is very
-similar to <i>S. asio</i>. The Florida form is smaller and colored
-like <i>S. asio</i>. The red phase is the frequent, if not the
-usual, one. The flammulated form, <i>S. fiammula</i>, is “a very
-<i>small species</i>, with much the general aspect of an ungrown
-<i>S. asio</i>.” This is the southwestern form, easily distinguished
-on account of its small size and color from the other forms.</p>
-
-<p class='c010'>These examples might be greatly increased, but they will
-suffice, I think, to convince one of the difficulty of giving a
-sharp definition to “species.” The facts speak strongly in
-favor of the transmutation theory, and show us how a species
-may become separated under different conditions into a number
-of new forms, which would be counted as new different
-species, if the intermediate forms were exterminated.</p>
-
-<p class='c010'>In discussing the nature of the changes that bring about
-variability, Darwin remarks: “From a remote period to the
-present day, under climates and circumstances as different
-as it is possible to conceive, organic beings of all kinds, when
-domesticated or cultivated, have varied. We see this with
-<span class='pageno' id='Page_313'>313</span>the many domestic races of quadrupeds and birds belonging
-to different orders, with goldfish and silkworms, with plants
-of many kinds, raised in various quarters of the world. In
-the deserts of northern Africa the date-palm has yielded
-thirty-eight varieties; in the fertile plains of India it is notorious
-how many varieties of rice and of a host of other plants
-exist; in a single Polynesian island, twenty-four varieties of
-the breadfruit, the same number of the banana, and twenty-two
-varieties of the arum, are cultivated by the natives. The
-mulberry tree of India and Europe has yielded many varieties
-serving as food for the silkworm; and in China sixty-three
-varieties of the bamboo are used for various domestic
-purposes. These facts, and innumerable others which could
-be added, indicate that a change of almost any kind in the
-conditions of life suffices to cause variability—different
-changes acting on different organisms.”</p>
-
-<p class='c010'>Darwin thinks that a change in climate alone is not one of
-the potent causes of variability, because the native country
-of a plant, where it has been longest cultivated, is where it
-has oftenest given rise to the greatest number of varieties.
-He thinks it also doubtful that a change in food is an important
-source of variability, since the domestic pigeon has
-varied more than any other species of fowl, yet the food has
-been always nearly the same. This is also true for cattle
-and sheep, whose food is probably much less varied in kind
-than in the wild species.</p>
-
-<p class='c010'>Another point of interest is raised by Darwin. He thinks,
-as do others also, that the influence of a change in the conditions
-is cumulative, in the sense that it may not appear
-until the species has been subjected to it for several generations.
-Darwin states that universal experience shows that
-when new plants are first introduced into gardens they do
-not vary, but after several generations they will begin to
-vary to a greater or less extent. In a few cases, as in that
-of the dahlia, the zinnia, the Swan River daisy, and the
-<span class='pageno' id='Page_314'>314</span>Scotch rose, it is known that the new variations only appeared
-after a time. The following statement by Salter is then
-quoted, “Every one knows that the chief difficulty is in
-breaking through the original form and color of the species,
-and every one will be on the lookout for any natural sport,
-either from seed or branch; that being once obtained, however
-trifling the change may be, the result depends on himself.”
-Jonghe is also quoted to the effect that “there is
-another principle, namely, that the more a type has entered
-into a state of variation, the greater is the tendency to continue
-doing so, and the more it has varied from the original
-type, the more is it disposed to vary still further.” Darwin
-also quotes with approval the opinion of the most celebrated
-horticulturist of France, Vilmorin, who maintained that “when
-any particular variation is desired, the first step is to get the
-plant to vary in any manner whatever, and to go on selecting
-the most variable individuals, even though they vary in
-the wrong direction; for the fixed character of the species
-being once broken, the desired variation will sooner or later
-appear.”</p>
-
-<p class='c010'>Darwin also cites a few cases where animals have changed
-quite quickly when brought under domestication. Turkeys
-raised from the eggs of wild species lose their metallic tints,
-and become spotted with white in the third generation. Wild
-ducks lose their true plumage after a few generations. “The
-white collar around the neck of the mallard becomes much
-broader and more irregular, and white feathers appear in
-the duckling’s wings. They increase also in size of body.”
-In these cases it appears that several generations were
-necessary in order to bring about a marked change in the
-original type, but the Australian dingoes, bred in the Zoological
-Gardens, produced puppies which were in the first
-generation marked with white and other colors.</p>
-
-<p class='c010'>The following cases from De Varigny are also very striking.
-The dwarf trees from Japan, for the most part conifers, which
-<span class='pageno' id='Page_315'>315</span>may be a hundred years old and not be more than three feet
-high, are in part the result “of mechanical processes which
-prevent the spreading of the branches, and in part of a starving
-process which consists in cutting most roots and in keeping
-the plant in poor soil.”</p>
-
-<p class='c010'>As an example of the sudden appearance of a new variation
-the following case is interesting. A variety of begonia
-is recorded as having appeared quite suddenly at a number of
-places at the same time. In another case a narcissus which
-had met with adverse circumstances, and had then been
-supplied with a chemical manure in some quantity, began to
-bear double flowers.</p>
-
-<p class='c010'>Amongst animals the following cases of the appearance of
-sudden variations are pointed out by De Varigny. “In Paraguay,
-during the last century (1770), a bull was born without
-horns, although his ancestry was well provided with these
-appendages, and his progeny was also hornless, although at
-first he was mated with horned cows. If the horned and the
-hornless were met in fossil state, we would certainly wonder
-at not finding specimens provided with semi-degenerate horns,
-and representing the link between both, and if we were told
-that the hornless variety may have arisen suddenly, we should
-not believe it and we should be wrong. In South America
-also, between the sixteenth and eighteenth centuries the niata
-breed of oxen sprang into life, and this breed of bulldog
-oxen has thriven and become a new race. So in the San
-Paulo provinces of Brazil, a new breed of oxen suddenly
-appeared which was provided with truly enormous horns, the
-breed of franqueiros, as they are called. The mauchamp
-breed of sheep owes its origin to a single lamb that was born
-in 1828 from merino parents, but whose wool, instead of being
-curly like that of its parents, remained quite smooth. This
-sudden variation is often met with, and in France has been
-noticed in different herds.”</p>
-
-<p class='c010'>The ancon race of sheep originated in 1791 from a ram
-<span class='pageno' id='Page_316'>316</span>born in Massachusetts having short crooked legs and a long
-back. From this one ram by crossing, at first with common
-sheep, the ancon race has been produced. “When crossed
-with other breeds the offspring, with rare exception, instead
-of being intermediate in character, perfectly resemble either
-parent; even one of twins has resembled one parent and the
-second the other.”</p>
-
-<p class='c010'>Two especially remarkable cases remain to be described.
-These are the Porto Santo rabbit and the japanned peacock.
-Darwin has given a full account of both of these cases.
-“The rabbits which have become feral on the island of Porto
-Santo, near Madeira, deserve a fuller account. In 1418 or
-1419 J. Gonzales Zarco happened to have a female rabbit on
-board which had produced young during the voyage, and he
-turned them all out on the island. These animals soon
-increased so rapidly that they became a nuisance, and actually
-caused the abandonment of the settlement. Thirty-seven
-years subsequently, Cada Mosto describes them as innumerable;
-nor is this surprising, as the island was not inhabited by
-any beast of prey, or by any terrestrial mammal. We do not
-know the character of the mother rabbit; but it was probably
-the common domestic kind. The Spanish peninsula, whence
-Zarco sailed, is known to have abounded with the common
-wild species at the most remote historical period; and as these
-rabbits were taken on board for food, it is improbable that
-they should have been of any peculiar breed. That the breed
-was well domesticated is shown by the doe having littered
-during the voyage. Mr. Wollaston, at my request, brought
-two of these feral rabbits in spirits of wine; and, subsequently,
-Mr. W. Haywood sent home three more specimens in brine
-and two alive. These seven specimens, though caught at
-different periods, closely resemble each other. They were
-full-grown, as shown, by the state of their bones. Although
-the conditions of life in Porto Santo are evidently highly
-favorable to rabbits, as proven by their extraordinarily rapid
-<span class='pageno' id='Page_317'>317</span>increase, yet they differ conspicuously in their small size from
-the wild English rabbit.... In color the Porto Santo
-rabbit differs considerably from the common rabbit; the
-upper surface is redder, and is rarely interspersed with any
-black or black-tipped hairs. The throat and certain parts of
-the under surface, instead of being pure white, are generally
-gray or leaden color. But the most remarkable difference
-is in the ears and tail. I have examined many fresh English
-rabbits, and the large collection of skins in the British Museum
-from various countries, and all have the upper surface of the
-tail and the tips of the ears clothed with blackish gray fur;
-and this is given in most works as one of the specific characters
-of the rabbit. Now in the seven Porto Santo rabbits
-the upper surface of the tail was reddish brown, and the tips
-of the ears had no trace of the black edging. But here we
-meet with a singular circumstance: in June, 1861, I examined
-two of these rabbits recently sent to the Zoological Gardens
-and their tails and ears were colored as just described; but
-when one of their dead bodies was sent to me in February, 1863,
-the ears were plainly edged, and the upper surface of the tail
-was covered with blackish gray fur, and the whole body was
-much less red; so that under the English climate this individual
-rabbit had recovered the proper color of its fur in rather
-less than four years.”</p>
-
-<p class='c010'>Another striking case of sudden variation is found in the
-peacock. It is all the more remarkable because this bird has
-hardly varied at all under domestication, and is almost exactly
-like the wild species living in India to-day. Darwin states:
-“There is one strange fact with respect to the peacock,
-namely, the occasional appearance in England of the ‘japanned’
-or ‘black-shouldered’ kind. This form has lately
-been named, on the high authority of Mr. Slater, as a distinct
-species, viz. <i>Pavo nigripennis</i>, which he believes will hereafter
-be found wild in some country, but not in India, where
-it is certainly unknown. The males of these japanned birds
-<span class='pageno' id='Page_318'>318</span>differ conspicuously from the common peacock in the color
-of their secondary wing-feathers, scapulars, wing-coverts, and
-thighs, and are, I think, more beautiful; they are rather
-smaller than the common sort, and are always beaten by
-them in their battles, as I hear from the Hon. A. S. G. Canning.
-The females are much paler-colored than those of
-the common kind. Both sexes, as Mr. Canning informs me,
-are white when they leave the egg, and they differ from the
-young of the white variety only in having a peculiar pinkish
-tinge on their wings. These japanned birds, though appearing
-suddenly in flocks of the common kind, propagate their
-kind quite truly.”</p>
-
-<p class='c010'>In two cases, in which these birds had appeared quite suddenly
-in flocks of the ordinary kind, it is recorded that
-“though a smaller and weaker bird, it increased to the extinction
-of the previously existing breed.” Here we have
-certainly a remarkable case of a new species suddenly
-appearing and replacing the ordinary form, although the
-birds are smaller, and <i>are beaten in their battles</i>.</p>
-
-<p class='c010'>Darwin has given an admirably clear statement of his
-opinion as to the <i>causes of variability</i> in the opening paragraph
-of his chapter dealing with this topic in his “Animals
-and Plants.” Some authors, he says, “look at variability as a
-necessary contingent on reproduction, and as much an original
-law as growth or inheritance. Others have of late encouraged,
-perhaps unintentionally, this view by speaking of inheritance
-and variability as equal and antagonistic principles. Pallas
-maintained, and he has had some followers, that variability
-depends exclusively on the crossing of primordially distinct
-forms. Other authors attribute variability to an excess of
-food, and with animals, to an excess relatively to the amount
-of exercise taken, or again, to the effects of a more genial
-climate. That these causes are all effective is highly probable.
-But we must, I think, take a broader view, and conclude that
-organic beings, when subjected during several generations to
-<span class='pageno' id='Page_319'>319</span>any change whatever in their condition, tend to vary; the
-kind of variation which ensues depending in most cases in a
-far higher degree on the nature of the constitution of the
-being, than on the nature of the changed conditions.”</p>
-
-<p class='c010'>Most naturalists will agree, in all probability, with this conclusion
-of Darwin’s. The examples cited in the preceding
-pages have shown that there are several ways in which the
-organisms may respond to the environment. In some cases
-it appears to affect all the individuals in the same way; in
-other cases it appears to cause them to fluctuate in many
-directions; and in still other cases, without any recognizable
-change in the external conditions, new forms may suddenly
-appear, often of a perfectly definite type, that depart widely
-from the parent form.</p>
-
-<p class='c010'>For the theory of evolution it is a point of the first importance
-to determine which of these modes of variation has
-supplied the basis for evolution. Moreover, we are here
-especially concerned with the question of how adaptive variations
-arise. Without attempting to decide for the present
-between these different kinds of variability, let us examine
-certain cases in which an immediate and adaptive response
-to the environment has been described as taking place.</p>
-<h3 class='c014'><span class='sc'>Responsive Changes in the Organism that adapt it to the New Environment</span></h3>
-
-<p class='c015'>There is some experimental evidence showing that sometimes
-organisms respond directly and adaptively to certain
-changes in the environment. Few as the facts are, they
-require very careful consideration in our present examination.
-The most striking, perhaps, is the acclimatization to different
-temperatures. It has been found that while few active organisms
-can withstand a temperature over 45 degrees C., and that
-for very many 40 degrees is a fatal point, yet, on the other
-hand, there are organisms that live in certain hot springs
-<span class='pageno' id='Page_320'>320</span>where the temperature is very high. Thus, to give a few
-examples, there are some of the lower plants, nostocs and
-protococcus forms, that live in the geysers of California at a
-temperature of 93 degrees C., or nearly that of boiling water.
-Leptothrix is found in the Carlsbad springs, that have a temperature
-of 44 to 54 degrees. Oscillaria have been found in
-the Yellowstone Park in water between 54 and 68 degrees,
-and in the hot springs in the Philippines at 71 degrees, and
-on Ischia at 85 degrees, and in Iceland at 98 degrees.</p>
-
-<p class='c010'>It is probable from recent observations of Setchel that
-most of the temperatures are too high, since he finds that
-the water at the edge of hot springs is many degrees lower
-than that in the middle parts.</p>
-
-<p class='c010'>The snail, <i>Physa acuta</i>, has been found in France living at
-a temperature of 35 to 36 degrees; another snail, Paludina,
-at Abano, Padua, at 50 degrees. Rotifers have been found at
-Carlsbad at 45 to 54 degrees; Anguillidæ at Ischia at 81 degrees;
-<i>Cypris balnearia</i>, a crustacean at Hammam-Meckhoutin,
-at 81 degrees; frogs at the baths of “Pise” at 38 degrees.</p>
-
-<p class='c010'>Now, there can be little doubt that these forms have had
-ancestors that were like the other members of the group, and
-would have been killed had they been put at once into water
-of these high temperatures, therefore it seems highly probable
-that these forms have become specially adapted to live
-in these warm waters. It is, therefore, interesting to find that
-it has been possible to acclimatize animals experimentally to
-a temperature much above that which would be fatal to them
-if subjected directly to it. Dutrochet (in 1817) found that if
-the plant, nitella, was put into water at 27 degrees, the currents
-in the protoplasm were stopped, but soon began again.
-If put now into water at 34 degrees they again stopped moving,
-but in a quarter of an hour began once more. If then
-put into water at 40 degrees the currents again slowed down,
-but began again later.</p>
-
-<p class='c010'>Dallinger (in 1880) made a most remarkable series of experiments
-<span class='pageno' id='Page_321'>321</span>on flagellate protozoans. He kept them in a warm
-oven, beginning at first at a temperature of 16.6 degrees C.
-“He employed the first four months in raising the temperature
-5.5 degrees. This, however, was not necessary, since
-the rise to 21 degrees can be made rapidly, but for success
-in higher temperatures it is best to proceed slowly from the
-beginning. When the temperature had been raised to 23
-degrees, the organisms began dying, but soon ceased, and
-after two months the temperature was raised half a degree
-more, and eventually to 25.5 degrees. Here the organisms
-began to succumb again, and it was necessary repeatedly to
-lower the temperature slightly, and then to advance it to
-25.5 degrees, until, after several weeks, unfavorable appearances
-ceased. For eight months the temperature could not
-be raised from this <i>stationary point</i> a quarter of a degree
-without unfavorable appearances. During several years,
-proceeding by slow stages, Dallinger succeeded in raising
-the organisms up to a temperature of 70 degrees C., at which
-the experiment was ended by an accident.”<a id='r27' /><a href='#f27' class='c017'><sup>[27]</sup></a></p>
-
-<div class='footnote c018' id='f27'>
-<p class='c019'><span class='label'><a href='#r27'>27</a>.&nbsp;&nbsp;</span>Quoted from Davenport’s “Experimental Morphology.”</p>
-</div>
-
-<p class='c010'>Davenport and Castle carried out a series of experiments
-on the egg of the toad, in which they tried to acclimatize
-the eggs to a temperature higher than normal. Recently
-laid eggs were used; one lot kept at a temperature of 15
-degrees C., the other at 24-25 degrees C. Both lots developed
-normally. At the end of four weeks the temperature
-point at which the tadpoles were killed was determined.
-Those reared at a temperature of 15 degrees C. died at 41
-degrees C., or below; those reared at 24-25 degrees C. sustained
-a temperature 10 degrees higher; no tadpole dying
-in this set under 43 degrees C. “This increased capacity
-for resistance was not produced by the dying off of the less
-resistant individuals, for no death occurred in these experiments
-during the gradual elevation of the temperatures in
-the cultures.” The increased resistance was due, therefore,
-<span class='pageno' id='Page_322'>322</span>to a change in the protoplasm of the individuals. It was
-also determined that the acquired resistance was only very
-gradually lost (after seventeen days’ sojourn in cooler water).
-The explanation of this result may be due, in part, to the protoplasm
-containing less water at higher temperatures, for it
-is known that while the white of egg (albumen) coagulates
-at 56 degrees C. in aqueous solution; with only 18 per cent
-of water it coagulates between 80 degrees and 90 degrees C.;
-and with 6 per cent, at 145 degrees C.; and without water
-between 100 degrees and 170 degrees C.</p>
-
-<p class='c010'>It has long been known that organisms in the dry condition
-resist a much higher temperature. The damp uredospore
-is killed at 58.5 degrees to 60 degrees C.; but dry
-spores withstand 128 degrees C. It is also known that
-organisms may become acclimatized to cold through loss of
-water, but we lack exact experimental data to show to what
-extent this can be carried.</p>
-
-<p class='c010'>There are also some experiments that go to show that animals
-may become attuned to certain amounts of light, but the
-facts in this connection will be described in another chapter.</p>
-
-<p class='c010'>Some important results have been obtained by accustoming
-organisms to solutions containing various amounts of salts.
-A number of cases of this sort are given by De Varigny. It
-has been found that littoral marine animals that live where
-the water may become diluted by the rain, or by rivers, survive
-better when put into fresh water than do animals living
-farther from the shore. Thus the oyster, the mussel, and the
-snail, Patella, withstand immersion in fresh water better than
-other animals that live farther out at sea. The reverse is
-also true; fresh-water forms, such as Lymnæa, Physa, Paludina,
-and others may be slowly acclimatized to water containing
-more salt. The forms mentioned above could be brought
-by degrees into water containing 4 per cent of salt, which
-would have killed the animals if they had been brought suddenly
-into it. Similar results have been obtained for amœba.</p>
-
-<p class='c010'><span class='pageno' id='Page_323'>323</span>It has been shown that certain rotifers and tardigrades,
-and also some unicellular animals, that live in pools and
-ponds that are liable to become dry, withstand desiccation,
-while other members of the same groups, living in the sea,
-do not possess this power of resistance. Cases of this sort
-are usually explained as cases of adaptation, but it has not
-been shown experimentally that resistance to drying can be
-acquired by a process of acclimatization to this condition.
-The case is also in some respects different from the preceding,
-since intermediate conditions are less likely to be met
-with, or to be of sufficiently long duration for the animal to
-become acclimatized to them. It seems more probable, in
-such cases, that these forms have been able to live in such
-precarious conditions from the beginning because they could
-resist the effects of drying, not that they have slowly acquired
-this power. Finally, there must be discussed the question of
-the acclimatization to poisons, to which an individual may be
-rendered partially immune. The point of special importance
-in this connection is that the animal may be said to respond
-adaptively to a large number of substances, which it has
-never met before in its individual history, or to which its
-ancestors have never been subjected. It may become slowly
-adapted to many different kinds of injurious substances.
-These cases are amongst the most important adaptive individual
-responses with which we are familiar, and the point
-cannot be too much emphasized that organisms have this
-latent capacity without ever having had an opportunity to
-acquire it through experience.</p>
-
-<p class='c010'>The preceding groups of phenomena, included under
-the general heading of individual acclimatization, have one
-striking thing in common, namely, that a physiological
-adaptation is brought about without a corresponding
-change in form, although we must suppose that the structure
-has been altered in certain respects at least. The form
-of the individual remains the same as before, but so far
-<span class='pageno' id='Page_324'>324</span>as its powers of resistance are concerned it is a very different
-being.</p>
-
-<p class='c010'>In regard to the perpetuation of the advantages gained by
-means of this power of adaptation, it is clear in those cases
-in which the young are nourished during their embryonic
-life by the mother, that, in this way, the young may be
-rendered immune to a certain extent, and there are instances
-of this sort recorded, especially in the case of some bacterial
-diseases. Whether this power can also be transmitted through
-the egg, in those instances in which the egg itself is set free
-and development takes place outside the body, has not been
-shown. In any case, the effect appears not to be a permanent
-one and will wear off when the particular poison no
-longer acts. It is improbable, therefore, that any permanent
-contribution to the race could be gained in this way. Adaptations
-of this sort, while of the highest importance to the
-individual, can have produced little direct effect on the evolution
-of new forms, although it may have been often of paramount
-importance to the individuals to be able to adapt
-themselves, or rather to become able to resist the effect of
-injurious substances. The important fact in this connection
-is the wonderful latent power possessed by all animals. So
-many, and of such different kinds, are the substances to
-which they may become immune, that it is inconceivable
-that this property of the organism could ever have been
-acquired through experience, no matter how probable it may
-be made to appear that this might have occurred in certain
-cases of fatal bacterial diseases. And if not, in so many
-other cases, why invent a special explanation for the few
-cases?</p>
-
-<p class='c010'>We may defer the general discussion of the rôle that
-external factors have played in the adaptation of organisms,
-until we have examined some of the theories which attribute
-changes to internal factors. The idea that something innate
-in the living substance itself has served as the basis for evolution
-<span class='pageno' id='Page_325'>325</span>has given rise to a number of different hypotheses. That
-of the botanist Nägeli is one of the most elaborately worked
-out theories of this sort that has been proposed, and may be
-examined by way of illustration.</p>
-<h3 class='c014'><span class='sc'>Nägeli’s Perfecting Principle</span></h3>
-
-<p class='c015'>Nägeli used the term <i>completing principle</i> (“Vervollkommungsprincip”)
-to express a tendency toward perfection
-and specialization. Short-sighted writers, he says, have
-pretended to see in the use of this principle something
-mystical, but on the contrary it is intended that the term
-shall be employed in a purely physical sense. It represents
-the law of inertia in the organic realm. Once set in motion,
-the developmental process cannot stand still, but must
-advance in its own direction. Perfection, or completion,
-means nothing else than the advance to complicated structure,
-“but since persons are likely to attach more meaning
-to the word <i>perfection</i> than is intended, it would perhaps
-be better to replace it with the less objectionable word <i>progression</i>.”</p>
-
-<p class='c010'>Nägeli says that Darwin, having in view only the condition
-of adaptation, designates that as more complete which gives
-its possessor an advantage in the battle for existence. Nägeli
-claims that this is not the only criterion that applies to organisms,
-and it leaves out the most important part of the phenomenon.
-There are two kinds of completeness which we
-should keep distinctly apart: (1) the completeness of organization
-characterized by the complication of the structure and
-the most far-reaching specialization of the parts; (2) the
-completeness of the adaptation, present at each stage in the
-organization, which consists in the most advantageous development
-of the organism (under existing conditions) that is
-possible with a given complication of structure and a given
-division of functions.</p>
-
-<p class='c010'><span class='pageno' id='Page_326'>326</span>The first of these conceptions Nägeli always calls “completeness”
-(Vollkommenheit), for want of a simpler and better
-expression; the second he calls adaptation. By way of
-illustrating the difference between the two, the following
-examples may be given. The unicellular plants and the
-moulds are excellently adapted each to its conditions of life,
-but they are much less complete in structure than an apple
-tree, or a grape vine. The rotifers and the leeches are well
-adapted to their station, but in completeness of structure
-they are much simpler than the vertebrates.</p>
-
-<p class='c010'>If we consider only organization and division of labor as
-the work of the completing principle, and leave for the
-moment adaptation out of account, we may form the following
-picture of the rise of the organic world. From the inorganic
-world there arose the simplest organic being thinkable, being
-little more than a drop of substance. If this underwent any
-change at all, it would have been necessarily in the direction
-of greater complication of structure; and this would constitute
-the first step in the upward direction. In this way Nägeli
-imagines the process once begun would continue. When the
-movement has reached a certain point, it must continue in the
-same direction. The organic kingdom consists, therefore, of
-many treelike branches, which have had a common starting-point.
-Not only does he suppose that organisms were once
-spontaneously generated, and began their first upward course
-of development, but the process has been repeated over and
-over again, and each time new series have been started on
-the upward course. The organic kingdom is made up, therefore,
-of all degrees of organization, and all these have had
-their origins in the series of past forms that arose and began
-their upward course at different times in the past. Those
-that are the highest forms at the present time represent the
-oldest series that successfully developed; the lowest forms
-living at the present time are the last that have appeared on
-the scene of action.</p>
-
-<p class='c010'><span class='pageno' id='Page_327'>327</span>Organisms, as has been said, are distinguished from one
-another, not only in that one is simpler and another more
-complicated, but also in that those standing at the same stage
-of organization are unequally differentiated in their functions
-and in their structure, which is connected primarily with certain
-external relations which Nägeli calls adaptations.</p>
-
-<p class='c010'>Adaptation appears at each stage of the organization, which
-stage is, for a given environment, the most advantageous
-expression of the main type that was itself produced by
-internal causes. For this condition of adaptation, a sufficient
-cause is demanded, and this is, as Nägeli tries to show
-later, the result of the inherited response to the environment.
-In many cases this cause will continue to act until
-complete adaptation is gained; in other cases, the external
-conditions give a direction only, and the organism itself continues
-the movement to its more perfect condition.</p>
-
-<p class='c010'>The difference between the conception of the organic kingdom
-as the outcome of mechanical causes on the one hand, or of
-competition and extermination on the other hand, can be best
-brought out, Nägeli thinks, by the following comparison of
-the two respective methods of action. There might have been
-no competition, and no consequent extermination in the plant
-kingdom, if from the beginning the surface of the earth had
-continually grown larger in proportion as living things
-increased in numbers, and if animals had not appeared to
-destroy the plants. Under these conditions each germ could
-then have found room and food, and have unfolded itself
-without hinderance. If now, as is assumed to be the case
-on the Darwinian theory, individual variations had been in
-all directions, the developmental movement could not have
-gone beyond its own beginnings, and the first-formed plants
-would have remained swinging now on one side and now on
-another of the point first reached. The whole plant kingdom
-would have remained in its entirety at its first stage of evolution,
-that is, it would never have advanced beyond the stage
-<span class='pageno' id='Page_328'>328</span>of a naked drop of plasma with or without a membrane. But,
-according to the further Darwinian conception, competition,
-leading to extermination, is capable of bringing such a condition
-to a higher stage of development, since it is assumed that
-those individuals which vary in a beneficial direction would
-have an advantage over those that have not taken such a
-step, or have made a step backward.</p>
-
-<p class='c010'>If, on the other hand, under the above-mentioned conditions
-of unrestricted development, without competition, variations
-were determined by “<i>mechanical principles</i>,” then, according
-to Nägeli’s view, all plant forms that now exist would still
-have evolved, and would be found living at the present time,
-but along with all those that now exist there would be still
-other forms in countless numbers. These would represent
-those forms which have been suppressed. On Nägeli’s view
-competition and suppression do not produce new forms, but
-only weed out the intermediate forms. He says without competition
-the plant kingdom would be like the Milky Way; in
-consequence of competition the plant kingdom is like the
-firmament studded with bright stars.</p>
-
-<p class='c010'>The plant kingdom may also be compared to a branched
-tree, the ends of whose branches represent living species.
-This tree has an inordinate power of growth, and if left to itself
-it would produce an impenetrable tangle of interwoven
-branches. The gardener prevents this crowding by cutting
-away some of the parts, and thus gives to the tree distinct
-branches and twigs. The tree would be the same without the
-watchful trimming of the gardener, but without definite form.</p>
-
-<p class='c010'>Nägeli states: “From my earlier researches I believe that
-the external influences are small in comparison to the internal
-ones. I shall speak here only of the influences of climate and
-of food, which are generally described as the causes of change,
-without however any one’s having really determined whether
-or not a definite result can be brought about by these factors.
-Later I shall speak of a special class of external influences
-<span class='pageno' id='Page_329'>329</span>which, according to my view, bring forth beyond a doubt
-adaptive changes.”</p>
-
-<p class='c010'>The external influence of climate and of food act only as
-transitory factors. A rich food supply produces fat, lack
-of food leads to leanness, a warm summer makes a plant more
-aromatic, and its fruit sweeter; a cold year means less odor
-and sour fruit. Of two similar seeds the one sown in rich
-soil will produce a plant with many branches and abundance
-of flowers; the other, planted in sandy soil, will produce a
-plant without branches, with few flowers, and with small
-leaves. The seeds from these two plants will behave in
-exactly the same way; they have inherited none of the
-differences of their parents. Influences of this sort, even if
-extending over many generations, have no permanent effect.
-Alpine plants that have lived since the ice age under the
-same conditions, and have the characters of true high-mountain
-plants, lose these characters completely during the
-first summer, if transplanted to the plains. Moreover, it
-makes no difference whether the seed or the whole plant
-itself be transferred. In place of the dwarfed, unbranched
-growth, and the reduced number of organs, the plant when
-transferred to the plains shoots up in height, branches strongly,
-and produces numerous leaves and flowers. The plants retain
-their new characters as long as they live in the plain without
-any other new variation being observed in them.</p>
-
-<p class='c010'>Other characteristics also, which arise from different kinds
-of external influences due to different localities, such as dampness
-and shade, a swampy region, or different geological
-substrata, last only so long as the external conditions last.</p>
-
-<p class='c010'>These transient peculiarities make up the characters of
-local varieties. That they have no permanency is intelligible,
-since they exhibit no new characters, but the change
-consists mainly in the over- or under-development of those
-peculiarities that are dependent on external influences. The
-effect of these influences may be compared to an elastic rod,
-<span class='pageno' id='Page_330'>330</span>which, however much it may be distorted by external circumstances,
-returns again to its original form as soon as released.</p>
-
-<p class='c010'>Besides these temporary changes, due to external influences,
-there are many cases known in which the same plant lives
-under very diverse conditions and yet remains exactly the same.
-For example, the species of <i>Rhododendron ferragineum</i> lives
-on archæan mountains and especially where the soil is poor in
-calcium. Another species, <i>Rhododendron hirsutum</i> is found
-especially on soil rich in calcium. The difference in the two
-species has been supposed to depend on differences in the
-soil, and if so, we would imagine that, if transplanted for a
-long time, the one should change in the direction of the other.
-Yet it is known that the rusty rhododendron may be found in
-all sorts of localities, even on dry, sunny, calcareous rocks of
-the Apennines and of the Jura, and despite its residence in
-these localities, since the glacial epoch, no change whatever
-has taken place.</p>
-
-<p class='c010'>Single varieties of the large and variable genus of <i>Hieracium</i>
-have lived since the glacial period in the high regions
-of the Alps, Carpathians, and in the far north, and also in the
-plains of different geological formations, but these varieties
-have remained exactly the same, although on all sides there
-are transitional forms leading from these to other varieties.</p>
-
-<p class='c010'>Some parasitic species also furnish excellent illustrations of
-the same principle. Besides the several species of Orobanchia
-and of the parasitic moulds, the mistletoe deserves special
-mention. It lives on both birch and apple trees and on both
-presents exactly the same appearance; and even if it is true
-that mistletoe growing on conifers presents certain small deviations
-in its character, it is still doubtful whether, if transferred
-to the birch or apple tree, it would not lose these
-differences, thus indicating that they are not permanent.</p>
-
-<p class='c010'>It is a fact of general observation that, on the one hand,
-the same variety occurs in different localities and under different
-surroundings, and, on the other hand, that slightly
-<span class='pageno' id='Page_331'>331</span>different varieties live together in the same place and therefore
-under the same external conditions. It is evident,
-then, that food conditions have neither originated the differences
-nor kept them up. The rarer cases in which in
-different localities different varieties exist show nothing, because
-competition and suppression keep certain varieties from
-developing where it would be possible otherwise for them
-to exist.</p>
-
-<p class='c010'>Nägeli says his conclusion may be tested from another
-point of view. If food conditions, as is generally supposed,
-have a definite, <i>i.e.</i> a permanent, effect on the organism, then
-all organisms living under the same conditions should show
-the same characters. Indeed, it has been claimed in some
-instances that this is actually the case. Thus it is stated
-that dry localities cause plants to become hairy, and that
-absence of hairiness is met with in shady localities. This
-may apply to certain species, but in other cases exactly the
-reverse is true, and even the same species behaves differently
-in different regions, as in <i>Hieracium</i>. And so it is with all
-characteristics which are ascribed to external influences. As
-soon as it is supposed a discovery has been made in this direction,
-we may rest assured that in other cases the reverse
-will be found to hold. We have had, in respect to the influence
-of the outer world on organisms, the same experience as with
-the rules for the weather,—when we come to examine the
-facts critically there are found to be as many exceptions as
-confirmations of the rule.</p>
-
-<p class='c010'>If climatic influence has a definite effect, the entire flora of
-a special locality ought to have the same peculiarities, but this
-stands in contradiction to all the results of experience. The
-character of the vegetation is not determined by the environment
-of the plants but by their prehistoric origin, and as
-the result of competition. Nägeli concludes his discussion
-with the statement that all of our experience goes to show
-that the effects of external influences (climate and food)
-<span class='pageno' id='Page_332'>332</span>appear at once, and their results last only as long as the
-influences themselves last, and are then lost, leaving nothing
-permanent behind. This is true even when the external
-influences have lasted for a long time,—since the glacial
-epoch, for instance. We find, he claims, nothing that supports
-the view that such influences are inherited.</p>
-
-<p class='c010'>If we next examine the question of changes from <i>internal
-causes</i>, Nägeli claims that here also observation and research
-fail to show the origin of a new species, or even of a new
-variety from external causes. In the organic world little
-change has taken place, he believes, since the glacial epoch.
-Many varieties have even remained the same throughout the
-whole intervening time; and while it cannot be doubted that
-new varieties have also been formed, yet the cause of their
-origin cannot be empirically demonstrated. The permanent,
-hereditary characters, of whose origin we know something
-from experience, belong to the individual changes which
-have appeared under cultivation in the formation of domestic
-races. These are for the most part the result of crossing.
-So far as we have any definite information as to the origin of
-the changes, they are the result of inner, and never of external,
-causes. We recognize that this must be the case, since
-under the same external conditions individuals behave differently—in
-the same flower-bud some seeds give rise to plants
-like the parent, others to altered ones. The strawberry with a
-single leaflet, instead of three, arose in the last century in a
-single individual amongst many other ordinary plants. From
-the ten seeds of a pear Van Mons obtained as many different
-kinds of pears. The most conclusive proof of the action
-of inner causes is most clearly seen when the branches of
-the same plant differ. In Geneva a horse-chestnut bore
-a branch with “filled” flowers, and from this branch, by
-means of cuttings, this variation has been carried over all
-Europe. In the Botanic Garden at Munich there is a beech
-with small divided leaves; but one of its branches produces
-<span class='pageno' id='Page_333'>333</span>the common broad undivided leaves. Many such examples
-have been recorded which can only be explained by assuming
-that a cell, or a group of cells, like those from which the
-other branches arose, have become changed in some unknown
-way as the result of inner causes. The properties that are
-permanent and inherited are contained in the idioplasm,
-which the parent transmits to its offspring. A cause that permanently
-transforms the organism must also transform the
-idioplasm. How powerless, in comparison to internal causes,
-the external causes are is shown most conclusively in grafting.
-The graft, although it receives its nourishment through the
-stock, which may be another species, remains itself unchanged.</p>
-
-<p class='c010'>Nägeli makes the following interesting comparison
-between the development of the individual from an egg, and
-the evolution, or development, of the phylum. No one will
-doubt that the egg during the entire time of its process of
-transformation is guided by internal factors. Each successive
-stage follows with mechanical necessity from the preceding.
-If an animal can develop from inner causes from
-a drop of plasma, why should not the entire evolutionary
-process have also been the outcome of developmental inner
-causes? He admits that there is a difference in the two
-cases in that the plasma that forms the egg has come from
-another animal, and contains all the properties of the individual
-in a primordial condition. In the other case we must
-suppose that the original drop of plasma did not contain at
-first the primordium of definite structures, but only the
-ability to form such. Logically the difference is unimportant.
-The main point is that in the primordium of the germ
-a special peculiarity of the substance is present which by
-forming new substances grows, and changes as it grows, and
-the one change of necessity excites the next until finally a
-highly organized being is the result.</p>
-
-<p class='c010'>Nägeli discusses a question in this connection, which, he
-says, has been unnecessarily confused in the descent theory.
-<span class='pageno' id='Page_334'>334</span>Since we are entirely in the dark as to how much time has
-been required for the formation of phyla, so also are we
-ignorant as to how long it may have taken for each step in
-advance. We may err equally in ascribing too much and
-too little time to the process. It is, moreover, not necessary
-that for every step the same amount of time should have
-been required. On the contrary, the probability is that
-recognizable changes may at times follow each other rapidly,
-and then for a time come to a standstill,—just as in the
-development of the individual there are periods of more rapid
-and others of less rapid change.</p>
-
-<p class='c010'>A more difficult problem than that relating to the sort of
-changes the external influences bring about in the organism,
-is the question as to how they effect the organism, or how
-they act on it mechanically. This, as is well known, was
-answered by Darwin, who regards all organization as a problem
-of adaptation: only those chance variations surviving
-which are capable of existence, the others being destroyed.
-On this theory external influences have only a negative or a
-passive action, namely, in setting aside the unadapted individuals.
-Nägeli, on the other hand, looks upon some kinds
-of external conditions as directly giving rise to the adaptive
-characters of the organism. This is accomplished, he supposes,
-in the following ways: two kinds of influence are
-recognized; <i>the direct action</i>, which, as in inorganic nature,
-comes to an end when the external influences come to an
-end, as when cold diminishes the chemical actions in the
-plant; and <i>the indirect action</i>, generally known as a stimulus,
-which starts a series of molecular motions, invisible to us,
-but which we recognize only in their effects. Very often
-the stimulus starts only a reflex action, usually at the place
-of application.</p>
-
-<p class='c010'>A stimulus acting for but a short time produces no lasting
-effect on the idioplasm. A person stung by a wasp
-suffers no permanent effect from the injury. But if a stimulus
-<span class='pageno' id='Page_335'>335</span>acts for a long time, and through a large number of
-generations, then it may, even if of small strength, so change
-the <i>idioplasm</i>, that a tendency or disposition capable of being
-seen may be the result. This appears to be the case in
-regard to the action of light, which causes certain parts of
-the plant to turn toward it and others away from it; also
-for the action of gravity, which determines the downward
-direction of the roots. It may be claimed, perhaps, that
-these are the results of direct influence and not of an
-internal response, but this is not the case; for some plants
-act in exactly the opposite way, and send a stem downward,
-as in the case of the cleistogamous flowers of <i>Cardamine
-chenopodifolia</i>; and other plants turn away from the light.
-This means that the idioplasm behaves differently in different
-plants in response to the same stimulus.</p>
-
-<p class='c010'>Concerning the more visible effects of adaptation, Nägeli
-states that in regard to some of them there can be no question
-as to how they must have arisen. Protection against
-cold, by the formation of a thick coat of hair, is the direct
-result of the action of the cold on the skin of the animal.
-The different weapons of offence and of defence, horns,
-spurs, tusks, etc., have arisen, he maintains, through stimulus
-to those parts of the body where these structures arise.</p>
-
-<p class='c010'>The causes of the other adaptations, especially of those
-occurring in plants, are less obvious. Land plants protect
-themselves from drying by forming a layer of cork over the
-surface. The most primitive plants were water plants, which
-acclimated themselves little by little to moist, and then to dry,
-air. When they first emerged from the water the drying
-acted as a stimulus on the surface, and caused it to harden
-in the same way as a drop of glue hardens. This hardening
-in turn acted as a stimulus, causing a chemical transformation
-of the surface into a corky substance. This effect
-was inherited, and in this way the power to form cork originated.</p>
-
-<p class='c010'><span class='pageno' id='Page_336'>336</span>Land plants have, in addition to the soft parts, the hard
-bast and wood which serves the mechanical purpose of supporting
-the soft tissues and protecting them from being
-injured. The arrangement of the hard parts is such as to
-suggest that they are the result of the action of pressures
-and tensions on the plant, for the strongest cells are found
-where there is most need for them. It is easy to imagine,
-Nägeli adds, that this important arrangement of the tissues
-is the result of external forces which brought about the result
-in these parts.</p>
-
-<p class='c010'>Nägeli accounts for the origin of twining plants as follows.
-Being overshadowed by other plants, the stem will grow
-rapidly in the damp air. Coming in contact with the stems
-of other plants, the delicate stem is stimulated on one side,
-and grows around the point of contact. This tendency
-becomes inherited, and the habit to twine is ultimately
-established.</p>
-
-<p class='c010'>The difference in the two sides of leaves is explained by
-Nägeli as the result of the difference in the illumination of the
-two sides. This influence of light on the leaf has been inherited.
-The formation of the tubular corolla that is seen in
-many plants visited by insects is explained as the result of the
-stimulus produced by the insects in looking for the pollen.
-The increase in the length of the proboscis of the insect is
-the result of the animal straining to reach the bottom of the
-ever elongating tube of the corolla. “The tubular corolla
-and the proboscis of the insect appear as though made for
-each other. Both have slowly developed to their present
-condition, the long tube from a short tube and the long
-proboscis from a short one.” Thus, by purely Lamarckian
-principles, Nägeli attempts to account for many of the adaptations
-between the organism and the outer world. But if
-this takes place, where is there left any room for the action
-for his so-called perfecting principle? Nägeli proceeds to
-show how he supposes that the two work together.</p>
-
-<p class='c010'><span class='pageno' id='Page_337'>337</span>As a result of inner causes the organism would pass
-through a series of perfectly definite stages, J, J<sup>1</sup>, J<sup>2</sup>. But
-if, at any stage, external influences produced an effect on
-the organism so that the arrangement of the idioplasm
-changes in response, a new adaptation is produced. In this
-way new characters, not inherent in the idioplasm, may be
-added, and old ones be changed or lost. “In order not to
-be misunderstood in regard to the completing or perfecting
-principle I will add, that I ascribe to it no determinate action
-in the organism, neither in producing the long neck of the
-giraffe, nor the prehensile tail of the ape, neither the claws
-of the crab, nor the decoration of the bird of paradise.
-These structures are the outcome of both factors. I cannot
-picture to myself how external causes alone, and just as little
-how internal causes alone, could have changed a monad into
-a man.” But Nägeli goes on to say, that if at any stage
-of organization one of the two causes should cease to act,
-the other could only produce certain limited results. Thus,
-if external causes alone acted, the organization would remain
-at the same stage of completeness, but might become adapted
-to all kinds of external conditions—a worm, for instance,
-would not develop into a fish, but would remain a worm forever,
-although it might change its worm structure in many
-ways in response to external stimuli. If, on the other hand,
-only the completing principle acted, then without changing
-its adaptations the number of the cells and the size of the
-organs might be increased, and functions that were formerly
-united might become separated. Thus, without altering the
-character of the organism, a more highly developed (in the
-sense of being more specialized) organism would appear.</p>
-
-<p class='c010'>Nägeli, as we have just seen, has attempted to build up a
-conception of nature based on two assumptions, neither of
-which has been demonstrated to be an actual principle of
-development. His hypothesis appears, therefore, entirely
-arbitrary and speculative to a high degree. Even if it were
-<span class='pageno' id='Page_338'>338</span>conceivable that two such principles as these control the evolution
-of organisms, it still requires a good deal of imagination
-to conceive how the two go on working together. Moreover,
-it is highly probable that whole groups have evolved in the
-direction of greater simplification, as seen especially in the
-case of those groups that have become degenerate. To
-what principle can we refer processes of this sort?</p>
-
-<p class='c010'>It is certainly a strange conclusion this, at which Nägeli
-finally arrives, for, after strenuously combating the idea that
-the external factors of climate and of food have influence in
-producing new species, he does not hesitate to ascribe all
-sorts of imaginary influences to other external causes. The
-apparent contradiction is due, perhaps, to the fact that his
-experience with actual species led him to deny that the direct
-action of the environment produces permanent changes, while
-in theory he saw the necessity of adding to his perfecting
-principle some other factor to explain the adaptations of the
-new forms produced by inner causes. Nägeli seems to have
-felt strongly the impossibility of explaining the process of
-evolution and of adaptation as the outcome of the selection
-of chance variations, now in this direction, now in that. He
-seems to have felt that there must be something within the
-organism that is driving it ever upward, and he attempts to
-avoid the teleological element, which such a conception is
-almost certain to introduce, by postulating the inheritance of
-the effects of long-continued action of the environment, in so
-far as certain factors in the environment produce a response
-in the organism. Nevertheless, this combination is not one
-that is likely to commend itself, aside from the fact that the
-assumptions have no evidence to support them. Despite
-Nägeli’s protest that his principles are purely physical, and
-that there is nothing mystical in his point of view, it must be
-admitted that his conception, as a whole, is so vague and
-difficult in its application that it probably deserves the neglect
-which it generally receives.</p>
-
-<p class='c010'><span class='pageno' id='Page_339'>339</span>Nägeli’s wide experience with living plants convinced him
-that there is something in the organism over and beyond the influence
-of the external world that causes organisms to change;
-and we cannot afford, I think, to despise his judgment on
-this point, although we need not follow him to the length of
-supposing that this internal influence is a “force” driving
-the organism forward in the direction of ever greater complexity.
-A more moderate estimate would be that the organism
-often changes through influences that appear to us to be
-internal, and while some of the changes are merely fluctuating
-or chance variations, there are others that appear to be
-more limited in number, but perfectly definite and permanent
-in character. It is the latter, which, I believe, we can safely
-accredit to internal factors, and which may be compared to
-Nägeli’s internal causes, but this is far from assuming that
-these changes are in the direction of greater completeness or
-perfection, or that evolution would take place independently
-of the action of external agencies.</p>
-
-<div class='pbb'>
- <hr class='pb c006' />
-</div>
-<div class='chapter'>
-  <span class='pageno' id='Page_340'>340</span>
-  <h2 class='c008'>CHAPTER X<br /> <br /><span class='c013'>THE ORIGIN OF THE DIFFERENT KINDS OF ADAPTATIONS</span></h2>
-</div>
-<p class='c009'><span class='sc'>In</span> the present chapter we may first consider, from the
-point of view of discontinuous variations as contrasted with
-the theory of the selection of individual variations, the
-structural adaptations of animals and plants, <i>i.e.</i> those
-cases in which the organism has a definite form that adapts
-it to live in a particular environment. In the second place,
-we may consider those adaptations that are the result of the
-adjustment of each individual to its surroundings. In subsequent
-chapters the adaptations connected with the
-responses of the nervous system and with the process of
-sexual reproduction will be considered.</p>
-
-<p class='c010'>It should be stated here, at the outset, that the term
-<i>mutation</i> will be used in the following chapters in a very
-general way, and it is not intended that the word shall
-convey only the idea which De Vries attaches to it; it is
-used rather as synonymous with <i>discontinuous and also definite
-variation</i> of all kinds. The term will be used to include
-“the single variations” of Darwin, “sports,” and even orthogenic
-variation, if this has been definite or discontinuous.</p>
-<h3 class='c014'><span class='sc'>Form and Symmetry</span></h3>
-
-<p class='c015'>Almost without exception, animals and plants have definite
-and characteristic forms. In other words, they are
-not amorphous masses of substance. The members of each
-species conform, more or less, to a sort of ideal type. Our
-<span class='pageno' id='Page_341'>341</span>first problem is to examine in what sense the form itself
-may be looked upon as an adaptation to the surroundings.</p>
-
-<p class='c010'>It is a well-recognized fact that the forms of many animals
-appear to stand in a definite relation to the environment.
-For instance, animals that move in definite directions in
-relation to their structure have the anterior and the posterior
-ends quite different, and it is evident that these ends
-stand in quite different relations to surrounding objects;
-while, on the other hand, the two sides of the body which
-are, as a rule, subjected to the same influences are nearly
-exactly alike. The dorsal and the ventral surfaces of the
-body are generally exposed to very different external conditions,
-and are quite different in structure.</p>
-
-<p class='c010'>The relation is so obvious in most cases that it might
-lead one quite readily to conclude that the form of the animal
-had been moulded by its surroundings. Yet this first
-impression probably gives an entirely wrong conception of
-how such a relation has been acquired. Before we attempt to
-discuss this question, let us examine some typical examples.</p>
-
-<p class='c010'>A radial type of structure is often found in fixed forms,
-and in some floating forms, like the jellyfish. In a fixed
-form, a sea-anemone, for instance, the conditions around the
-free end and the fixed end of the body are entirely different,
-and we find that these two ends are also different. The
-free end contains the special sense-organs, the mouth, tentacles,
-etc.; while the fixed end contains the organ for attachment.
-It is evident that the free end is exposed to the same
-conditions in all directions, and it may seem probable that
-this will account for the radial symmetry of the anemone.
-There are also a few free forms, the sea-urchin for instance,
-that have a radial symmetry. Whether their ancestors were
-fixed forms, for which there is some evidence, we do not
-know definitely; but, even if this is true, it does not affect
-the main point, namely, that, although at present free to
-move, the sea-urchin is radially symmetrical. But when we
-<span class='pageno' id='Page_342'>342</span>examine its method of locomotion, we find that it moves
-indifferently in any direction over a solid surface; that is,
-it keeps its oral face against a solid object, and moves over
-the surface in any direction. Under these circumstances
-the same external conditions will act equally upon all sides
-of the body. In contrast to these common sea-urchins,
-there are two other related groups, in which, although traces
-of a well-marked radial symmetry are found, the external
-form has been so changed that a secondary bilateral form
-has been superimposed on it. These are the groups of the
-clypeasters and the spatangoids, and it is generally supposed
-that their forefathers were radially symmetrical forms like
-the ordinary forms of sea-urchins. These bilateral forms
-move in the direction of their plane of symmetry, but
-we have no means of knowing whether they first became
-bilateral and, in consequence, now move in the direction of
-the median plane, or whether they acquired the habit of moving
-in one direction, and in consequence acquired a bilateral
-symmetry. It seems more probable that the form changed
-first, for otherwise it is difficult to see why a change of movement
-in one direction should ever have taken place.</p>
-
-<p class='c010'>The radially symmetrical form is characteristic of many
-flowers that stand on the ends of their stalks. They also
-will be subjected to similar external influences in all directions.
-Many flowers, on the other hand, are bilaterally
-symmetrical. Some of these forms are of such a sort that
-they are generally interpreted as having been acquired in
-connection with the visits of insects. Be this as it may,
-it is still not clear why, if the flowers are terminal, insects
-should not approach them equally from every direction. If
-the flowers are not terminal, as, in fact, many of them are
-not, their relation to the surroundings is bilateral with respect
-to internal as well as to external conditions. The
-former, rather than the latter, may have produced the
-bilateral form of the flower. Here also we meet with the
-<span class='pageno' id='Page_343'>343</span>problem as to whether the flowers, being lateral in position,
-have assumed a bilateral form because their internal relations
-were bilateral; or whether an external relation, for
-example, the visits of insects, has been the principle cause
-of their becoming bilateral.</p>
-<div id='fig-4'  class='figcenter id008'>
-<img src='images/i343.jpg' alt='' class='ig001' />
-<div class='ic003'>
-<p><span class='sc'>Fig. 4.</span>—A, right and left claws of lobster;<br />B, of the fiddler-crab; and<br />C, of Alpheus.</p>
-</div>
-</div>
-
-<p class='c009'>In some bilateral forms the right and left sides may be
-unsymmetrical in certain organs. Right and left handedness
-in man is the most familiar example, although the structural
-difference on which this rests is not very obvious. More
-striking is the difference in the two big claws of the lobster
-(Fig. <a href='#fig-4'>4 A</a>). One of the two claws is flat and has a fine saw-toothed
-edge. The other is thicker and has rounded knobs
-instead of teeth. It is said that these two claws are used by
-the lobster for different purposes,—the heavy one for crushing
-and for holding on, and the narrower for cutting up the
-<span class='pageno' id='Page_344'>344</span>food. If this is true, then we find a symmetrical organism
-becoming unsymmetrical, and in consequence it takes advantage
-of its asymmetry by using its right and left claws for
-different purposes.</p>
-
-<p class='c010'>More striking still is the difference in the size of the right
-and left claws in a related form, Alpheus—a crayfish-like
-form that lives in the sea. With the larger claw (Fig. <a href='#fig-4'>4 C</a>) it
-makes a clicking sound that can be heard for a long distance.
-In some of the crabs the difference in the size of the two
-claws is enormous, as in the male fiddler-crab, for example
-(Fig. <a href='#fig-4'>4 B</a>). One of the claws is so big and unwieldy that it
-must put the animal at a distinct disadvantage. Its use is
-unknown, although it has been suggested that it is a secondary
-sexual character.</p>
-
-<p class='c010'>The asymmetry of the body of the snail is very conspicuous,
-at least so far as certain organs are concerned. The
-foot on which the animal crawls and the head have preserved
-their bilaterality; but the visceral mass of the animal, contained
-in the spirally wound shell, lying on the middle of the
-upper surface of the foot, is twisted into a spiral form. Many
-of the organs of one side of the body are atrophied. The
-gill, the kidney, the reproductive organ, and one of the
-auricles of the heart have completely, or almost completely,
-disappeared. The cause of this loss seems to be connected
-with the spiral twist of the visceral mass. One of the consequences
-of the twisting has been to bring the organs of the
-left side of the body around the posterior end until they come
-to lie on the right side, the organs of the original right side
-being carried forward and there atrophying.</p>
-
-<p class='c010'>There is another remarkable fact connected with the asymmetry
-of the snail. In some species, <i>Helix pomatia</i>, for
-example, the twist has been toward the right, <i>i.e.</i> in the
-direction which the hands of a watch follow when the face
-is turned upward toward the observer. Individuals twisted
-in this direction are called dextral. Occasionally there is
-<span class='pageno' id='Page_345'>345</span>found an individual with the spiral in the opposite direction
-(sinistral), and in this the conditions of the internal organs
-are exactly reversed. It is the left set of organs that is now
-atrophied, and the right set that is functional. Such changes
-appear suddenly. Organs of one side of the body that have
-not been functional for many generations may become fully
-developed. Moreover, Lang has shown that when a sinistral
-form breeds with a normal dextral form, or even when
-sinistral forms are bred with each other, the young are practically
-all of the ordinary type.</p>
-
-<p class='c010'>An attempt has been made to connect these facts with the
-mode of development of the mollusks. It is known that the
-eggs of a number of gasteropod mollusks segment in a perfectly
-definite manner. A sort of spiral cleavage is followed
-by the formation of a large mesodermal cell from the left
-posterior yolk-cell. From this mesodermal cell nearly all
-the mesodermal organs of the body are formed. Thus it
-may appear that the spiral form of the snail is connected
-with the spiral form of the cleavage. In a few species of
-marine and fresh-water snails the cleavage spiral is reversed,
-and the mesoderm arises from the right posterior yolk-cell.
-It has been shown in several cases that the snail coming
-from such an egg is twisted in the reverse direction from
-that of ordinary snails.</p>
-
-<p class='c010'>It has been suggested, therefore, that the occasional sinistral
-individual of Helix arises from an egg cleaving in the
-reverse direction, and there is nothing improbable in an
-assumption of this kind. No attempt has been made as yet
-to explain why, in some cases, the cleavage spiral is turned
-in one direction, and in other cases in the reverse direction;
-but even leaving this unaccounted for, the assumption of
-the unusual form of Helix being the result of a reversal of the
-cleavage throws some light as to how it is possible for the
-complete reversal of the organs of the adult to arise. If it is
-assumed that in the early embryo the cells on each side of
-<span class='pageno' id='Page_346'>346</span>the median line are alike, and at this time capable of forming
-adult structures, a simple change of the spiral from right to
-left might determine on which side of the middle line the
-mesodermal cell would lie, and its presence on one side rather
-than on the other might determine which side of the embryo
-would develop, and which would not. This possibility removes
-much of the mystery which may appear to surround a sudden
-change of this sort.</p>
-
-<p class='c010'>It seems to me that we shall not go far wrong if we assume
-that it is largely a matter of indifference whether an individual
-snail is a right-handed or a left-handed form, as far as its
-relation to the environment is concerned. One form would
-have as good a chance for existing as the other. If this is
-granted, we may conclude that, while in most species a perfectly
-definite type is found, a right or a left spiral, yet
-neither the one nor the other has been acquired on account
-of its relation to the environment. This conclusion does not,
-of course, commit us in any way as to whether the spiral
-form of the visceral mass has been acquired in relation to
-the environment, but only to the view that, if a spiral form
-is to be produced, it is indifferent which way it turns. From
-the evolutionary point of view this conclusion is of some
-importance, since it indicates that one of the alternatives has
-been adopted and has become practically constant in most
-cases without selection having had anything to do with it.</p>
-
-<p class='c010'>Somewhat similar conditions are found in the flounders
-and soles. As is well known, these fishes lie upon one side of
-the body on the bottom of the ocean. Some species, with the
-rarest exceptions to be mentioned in a moment, lie always on
-the right side, others on the left side. A few species are
-indifferently right or left. At rare intervals a left-sided form
-is found in a right-sided species, and conversely, a right-sided
-form in a left-sided species. In such cases the reversed type
-is as perfectly developed in all respects as the normal form,
-but with a complete reversal of its right and left sides.</p>
-
-<p class='c010'><span class='pageno' id='Page_347'>347</span>When the young flounders leave the egg, they swim in an
-upright position, as do ordinary fishes, with both sides equally
-developed. There cannot be any doubt that the ancestors
-of these fish were bilaterally symmetrical. Therefore, within
-the group, both right-handed and left-handed forms have
-appeared. It seems to me highly improbable that if a right-handed
-form had been slowly evolved through the selection
-of favorable variations in this direction, the end result
-could be suddenly reversed, and a perfect left-sided form
-appear. Moreover, as has been pointed out, the intermediate
-stages would have been at a great disadvantage as compared
-with the parent, and this would lead to their extermination
-on the selection theory. If, however, we suppose that a variation
-of this sort appeared at once, and was fixed,—a mutation
-in other words,—and that whether or not it had an advantage
-over the parent form, it could still continue to exist,
-and propagate its kind, then we avoid the chief difficulty of
-the selection theory. Moreover, we can imagine, at least,
-that if this variation appeared in the germ and was, in its
-essential nature, something like the relation seen in the snail,
-the occasional reversal of the relations of the parts presents
-no great difficulty.</p>
-
-<p class='c010'>In this same connection may be mentioned a curious fact
-first discovered by Przibram and later confirmed by others.
-If the leg carrying the large claw of a crustacean be removed,
-then, at the next moult, the leg of the other side that had
-been the smaller first leg becomes the new big one; and the
-new leg that has regenerated from the place where the big
-one was cut off becomes the smaller one.</p>
-
-<p class='c010'>Wilson has suggested that both claws in the young crustacean
-have the power to become either sort. We do not know
-what decides the matter in the adult, after the removal of one
-of the claws. Some slight difference may turn the balance
-one way or the other, so that the smaller claw grows into the
-larger one. At any rate, there is seen a latent power like
-<span class='pageno' id='Page_348'>348</span>that in the egg of the snail. Zeleny has found a similar relation
-to exist for the big and the little opercula of the marine
-worm, Hydroides.</p>
-
-<p class='c010'>Let us consider now the more general questions involved
-in these symmetrical and asymmetrical relations between the
-organism and its environment. In what sense, it may be
-asked, is the symmetry of a form an adaptation to its environment?
-That the kind of symmetry gives to the animal in many
-cases a certain advantage in relation to its environment is so
-evident that I think it will not be questioned. The main
-question is how this relation is supposed to have been attained.
-Three points of view suggest themselves: First, that the form
-has resulted directly from the action of the environment upon
-the organism. This is the Lamarckian point of view, which
-we rejected as improbable. Second, that the form has been
-slowly acquired by selecting those individual variations that
-best suited it to a given set of surrounding conditions. This
-is the Darwinian view, which we also reject. The third,
-that the origin of the form has had nothing to do with the
-environment, but appeared independently of it. Having,
-however, appeared, it has been able to perpetuate itself under
-certain conditions.</p>
-
-<p class='c010'>It should be pointed out that the Darwinian view does not
-suppose that the environment actually produces any of the new
-variations which it selects after they have appeared, but in so
-far as the environment selects individual differences it is supposed
-to determine the direction in which evolution takes
-place. On the theory that evolution has taken place independently
-of selection, this latter is not supposed to be the case;
-the finished products, so to speak, are offered to the environment;
-and if they pass muster, even ever so badly, they may
-continue to propagate themselves.</p>
-
-<p class='c010'>The asymmetrical form of certain animals living in a symmetrical
-environment might be used as an argument to
-show that the relation of symmetry between an animal and
-<span class='pageno' id='Page_349'>349</span>its environment can easily be overstepped without danger.
-The enormous claw of the fiddler-crab must throw the
-animal out of all symmetrical relation with its environment,
-and yet the species flourishes. The snail carries around a
-spiral hump that is entirely out of symmetrical relation with
-the surroundings of a snail.</p>
-
-<p class='c010'>These facts, few though they are, yet suffice to show, I
-believe, that the relation of symmetry between the organism
-and its environment may be, and is no doubt in many cases,
-more perfect than the requirements of the situation demand.
-The fact that animals made unsymmetrical through injuries
-(as when a crab loses several legs on one side, or a worm its
-head) can still remain in existence in their natural environment,
-is in favor of the view that I have just stated. By
-this I do not mean to maintain that a symmetrical form does
-not have, on the whole, an advantage over the same form
-rendered asymmetrical, but that this relation need not have
-in all forms a selective value, and if not, then it cannot be
-the outcome of a process of natural selection.</p>
-
-<p class='c010'>To sum up: it appears probable that the laws determining
-the symmetry of a form are the outcome of internal factors,
-and are not the result either of the direct action of the environment,
-or of a selective process. The finished products
-and not the different imperfect stages in such a process, are
-what the inner organization offers to the environment.
-While the symmetry or asymmetry may be one of the numerous
-conditions which determine whether a form can persist
-or not, yet we find that the symmetrical relations may
-be in some cases more perfect than the environment actually
-demands; and in other cases, although the form may place
-the organism at a certain disadvantage, it may still be able
-to exist in certain localities.</p>
-<div>
-  <span class='pageno' id='Page_350'>350</span>
-  <h3 class='c014'><span class='sc'>Mutual Adaptation of Colonial Forms</span></h3>
-</div>
-
-<p class='c015'>In the white ants, true ants, and bees, we find certain individuals
-of the community specialized in such a way that
-their modifications stand in certain useful relations to other
-members of the community. Amongst the bees, the workers
-collect the food, make the comb, and look after the young.
-The queen does little more than lay eggs, and the drone’s
-only function is to fertilize the queen. In the true ants there
-are, besides the workers and the queen and the males, the
-soldier caste. These have large thick heads and large strong
-jaws. On the Darwinian theory it is assumed that this caste
-must have an important rôle to play, for otherwise their presence
-as a distinct group of forms cannot be accounted for;
-but I do not believe it is necessary to find an excuse for
-their existence in their supposed utility. From the point of
-view of the mutation theory, their real value may be very
-small, but so long as their actual presence is not entirely
-fatal to the community they may be endured.</p>
-
-<p class='c010'>In regard to these forms, Sharp writes:<a id='r28' /><a href='#f28' class='c017'><sup>[28]</sup></a> “The soldiers
-are not alike in any two species of Termitidæ, so far as we
-know, and it seems impossible to ascribe the differences that
-exist between the soldiers of different species of Termitidæ
-to special adaptations for the work they have to perform.”
-“On the whole, it would be more correct to say that the
-soldiers are very dissimilar in spite of their having to perform
-similar work, than to state that they are dissimilar in conformity
-with the different tasks they carry on.” The soldiers
-have the same instincts as the workers, and do the
-same kinds of things to a certain extent. “The soldiers are
-not such effective combatants as the workers are.” Statements
-such as these indicate very strongly that the origin of
-this caste can have very little to do with its importance as a
-specialized part of the community.</p>
-
-<div class='footnote c018' id='f28'>
-<p class='c019'><span class='label'><a href='#r28'>28</a>.&nbsp;&nbsp;</span>“The Cambridge Natural History,” Vol. V, 1895.</p>
-</div>
-
-<p class='c010'><span class='pageno' id='Page_351'>351</span>The differences between the castes have gone so far in
-some of these groups that the majority of the members of the
-community have even lost the power to reproduce their kind,
-and this function has devolved upon the queen, whose sole
-duty is to reproduce the different castes of which the community
-is composed. This specialization carries with it the
-idea of the individuals being adapted to each other, so that,
-taken all together, they form a whole, capable of maintaining
-and reproducing itself. It does not seem that we must necessarily
-look upon this union as the result of competition
-leading to a death struggle between different colonies, so
-that only those have survived in each generation that carried
-the work of specialization one step farther. All that is required
-is to suppose that such specialization has appeared in
-a group of forms living together, and the group has been able
-to perpetuate itself. We do not find that all other members
-of the two great groups to which the white ants and true ants
-belong have been crowded out because these colonial forms
-have been evolved. Neither need we suppose that during
-the evolution of these colonial species there has been a death
-struggle accompanying each stage in the evolution. If the
-members of a colonial group began to give rise to different
-forms through mutations, and if it happened that some of the
-combinations formed in this way were capable of living together,
-and perpetuating the group, this is all that is required
-for such a condition to persist.</p>
-
-<p class='c010'>The relation of the parents to the offspring presents in
-some groups a somewhat parallel case to that of these colonial
-forms. Not only are some of the fundamental instincts of
-the parents changed, but structures may be present in the
-parents whose only use is in connection with the young.
-The marsupial pouch of the kangaroo, in which the immature
-young are carried and suckled, is a case in point, and the
-mammary glands of the Mammalia furnish another illustration.</p>
-
-<p class='c010'>Adaptations of these kinds are clearly connected with the
-<span class='pageno' id='Page_352'>352</span>perpetuation of the race. In the case of the mammals the
-young are born so immature that they are dependent on
-the parental organs, just spoken of, for their existence.
-Could we follow this relation through its evolutionary stages,
-it would no doubt furnish us with important data, but unfortunately
-we can do no more than guess how this relation
-became established. The changes in the young and in the
-parent may have been intimately connected at each stage, or
-more or less independent. If we suppose the mammary
-glands to have appeared first, they might have been utilized
-by the young in order to procure food. Their presence
-would then make it possible for the young to be born in an
-immature condition, as is the case with the young of many
-of the mammals. But this is pure guessing, and until we
-know more of the actual process of evolution in this case, it
-is unprofitable to speculate.</p>
-<h3 class='c014'><span class='sc'>Degeneration</span></h3>
-
-<p class='c015'>In almost every group of the animal kingdom there are
-forms that are recognized as degenerate. This degeneration
-is usually associated with the habitat of the animal. In many
-cases it can be shown with much probability that these degenerate
-forms have descended from members of the group that
-are not degenerate. We find there is a loss of those organs
-that are not useful to the organism in its new environment.
-The degeneration may involve nearly the whole organization
-(except as a rule the reproductive system), as seen in the
-tapeworm, or only certain organs of the body, as the eyes in
-cave animals. A few examples will bring the main facts
-before us.</p>
-
-<p class='c010'>A parasitic existence is nearly always associated with degeneration.
-Under these conditions, food can generally be
-obtained without difficulty, at the expense of the host, and
-apparently associated with this there is a degeneration, and
-<span class='pageno' id='Page_353'>353</span>even a complete loss of so important an organ as the digestive
-tract. Thus the tapeworm has lost all traces of its
-digestive tract, absorbing the already digested matter of its
-host through its body wall. Some of the roundworms, that
-live in the alimentary tracts of other animals, may have their
-digestive organs reduced. In Trichina, this degeneration has
-gone so far that the digestive tract is represented, in part,
-by a single line of endoderm cells, pierced by a cavity. The
-digestive organs are also absent in certain male rotifers,
-which are parasitic on the females, and these organs are
-also very degenerate in the male of <i>Bonellia</i>, a gephyrean
-worm. A parasitic snail, <i>Entoscolax ludwigii</i>, has its digestive
-apparatus reduced to a sucking tube ending in a blind
-sac. The rest of the tract has completely degenerated. The
-remarkable parasitic crustacean, <i>Sacculina carcini</i>, looks like
-a tumor attached to the under surface of the abdomen of a
-crab. It has neither mouth nor digestive tract, and absorbs
-nourishment from the crab through rootlike outgrowths that
-penetrate the body. From its development alone we know
-that it is a degenerate barnacle.</p>
-
-<p class='c010'>There seems to be in all these cases an apparent connection
-between the absence of the digestive tract and the
-presence of an abundant supply of food, that has already
-been partly digested by the host. Put in a different way, we
-may say that the presence of this food has furnished the
-environment in which an animal may live that has a rudimentary
-digestive tract.</p>
-
-<p class='c010'>An interesting case of degeneration is found in the rudimentary
-mouth parts of the insects known as May-flies, or
-ephemerids. Some of these species live in the adult condition
-for only a few hours, only long enough to unite and
-deposit their eggs. In the adult stage the insects do not
-take any food. In this case the degeneration is obviously
-not connected with the presence of food, but apparently
-with the shortness of the adult life.</p>
-
-<p class='c010'><span class='pageno' id='Page_354'>354</span>One of the most familiar cases of degeneration is blindness,
-associated with life in the dark. The most striking
-cases are those of cave animals, but this is only an extreme
-example of what is found everywhere amongst animals that
-live concealed during the day under stones, etc. The blind
-fish and the blind crayfish of the Mammoth Cave, the
-blind proteus of the caves of Carniola, the blind mole that
-burrows underground, the blind larvæ of many insects that
-live in the dark, are examples most often cited. Some nocturnal
-animals, like the earthworm, have no eyes, although
-they are still able to distinguish light; and some of the deep-sea
-animals, that live below the depth to which light penetrates,
-have degenerate eyes. The workers of some ants,
-that remain in the nests, are blind, but the males and the
-queens of these forms have well-developed eyes, although the
-eyes may be of use to them at only one short period of their
-life, namely, at the time of the marriage flight. This fact
-is significant and is underestimated by those who believe
-that disuse accounts for the degeneration of organs.</p>
-
-<p class='c010'>The wings of the ostrich and of the kiwi are rudimentary
-structures no longer used for flight, and many insects, belonging
-to several different orders, have lost their wings, as
-seen in fleas, some kinds of bugs, and moths, and even in
-some grasshoppers.</p>
-
-<p class='c010'>A curious case of degeneration is found in the abdomen of
-the hermit crab, which is protected by the appropriated shell
-of a snail. The appendages of one side of the abdomen
-have nearly disappeared in the male, although in the female
-the abdominal appendages are used to carry the eggs as in
-other decapod crustaceans. The abdomen, instead of being
-covered by a hard cuticle, as in other members of this group,
-is soft and unprotected except by the shell of the snail.</p>
-
-<p class='c010'>Cases of these kinds could be added to almost indefinitely,
-and the explanation of these degenerate structures has been
-a source of contention amongst zoologists for a long time.
-<span class='pageno' id='Page_355'>355</span>The most obvious interpretation is that the degeneration has
-been the result of disuse. But as I have already discussed
-this question, and given my reasons for regarding it as improbable
-that degeneration has arisen in this way, we need
-not further consider this point here.</p>
-
-<p class='c010'>The selectionists have offered several suggestions to
-account for degeneration. In fact, this has been one of the
-difficulties that has given them most concern. They have
-suggested, for example, that when an organ is no longer of
-use to its possessor it would become a source of danger,
-and hence would be removed through natural selection.
-They have also suggested that since such organs draw on the
-general food supply they would place their possessor at a
-disadvantage, and hence would be removed. Weismann has
-attempted to meet the difficulty by his theory of “Panmixia,”
-or universal crossing, by which means the useless structures
-are imagined to be eliminated.</p>
-
-<p class='c010'>These attempts will suffice to point out the straits to
-which the Darwinians have found themselves reduced, and
-we have by no means exhausted the list of suggestions that
-have been made. Let us see, if, on any other view, we can
-avoid some of the difficulties that the selection theory has
-encountered.</p>
-
-<p class='c010'>In the first place we shall be justified, I think, in eliminating
-competition as a factor in the process, since the admission
-that an organ has become useless carries with it the
-idea that it has no longer a selective value. If, in its useless
-condition, it is no longer greatly injurious, as is probably,
-though not necessarily always, the case, then selection cannot
-enter into the problem. If in parasitism we assume that
-an animal finds a lodgement in another animal, where it is
-able to exist, we may have the first stage of the process
-introduced at once. If under these conditions a mutation
-appeared, involving some of the organs that are no longer
-essential to the life of the individual in its new environment,
-<span class='pageno' id='Page_356'>356</span>the new mutation may persist. We need not suppose that
-the original form becomes crowded out, but only that a more
-degenerate form has come into existence. As a matter of
-fact we find in most groups, in which degenerate forms exist,
-a number of different stages in the degeneration in different
-species. Mutation after mutation might follow until many of
-the original organs have disappeared. The connection that
-appears to exist between the degeneration of a special part
-and the environment in which the animal lives finds its
-explanation simply in the fact that the environment makes
-possible the existence of that sort of mutation in it. We do
-not know, as yet, whether through mutative changes an
-organ can completely disappear, although this seems probable
-from the fact that in a few cases mutations are known to
-have arisen in which a given part is entirely functionless.
-If we could assume that, a mutation in the direction of
-degeneration being once established, further mutations in
-the same direction would probably occur, the problem
-would be much simplified; but we lack data, at present, to
-establish this view.</p>
-
-<p class='c010'>In the case of blind animals it seems probable that the
-transition has taken place in such forms as had already
-established themselves in places more or less removed from
-the light. Such forms as had the habit of hiding away under
-stones, or in the ground, living partly in and partly out of
-the light, might, if a mutation appeared of such a sort that
-amongst other changes the eyes were less developed, still be
-capable of leading an existence in the dark, while it might be
-impossible for them to exist any longer with weakened vision
-in the light. If such a process took place, the habitat of the
-new form would be limited, or in other words it would be
-confined to the locality to which it finds itself adapted;
-not that it has become adapted to the environment through
-competition with the original species, or, in fact, with any
-other.</p>
-
-<p class='c010'><span class='pageno' id='Page_357'>357</span>Thus, from the point of view that is here taken, an animal
-does not become degenerate because it becomes parasitic,
-but the environment being given, some forms have found
-their way there; in fact, we may almost say, have been
-forced there, for these degenerate forms can only exist under
-such conditions.</p>
-
-<p class='c010'>In conclusion, this much at least can be claimed for the
-mutation theory; that it meets with no serious difficulty in
-connection with the phenomena of degeneration. It meets
-with no difficulty, because it makes no pretence to explain
-the origin of adaptations, but can account for the occurrence
-of degenerate forms, if it is admitted that these appear as
-mutations, or as definite variations. Let us, however, not
-close our eyes to the fact that there is still much to be
-explained in respect to the degeneration of animals and
-plants. It is far from my purpose to apply the mutation
-theory to all adaptations; in fact, it will not be difficult to
-show that there are many adaptations whose existence can
-have nothing directly to do with the mutation theory.</p>
-<h3 class='c014'><span class='sc'>Protective Coloration</span></h3>
-
-<p class='c015'>That many species of animals are protected by their resemblance
-to their environment no one will probably deny.
-That we are ignorant in all cases as to how far this protection
-is necessary for the maintenance of the species must be
-admitted. That some of the resemblances that have been
-pointed out have been given fictitious value, I believe very
-probable.</p>
-
-<p class='c010'>Resemblance in color between the organism and its environment
-has given to the modern selectionist some of his
-most valuable arguments, but we should be on our guard
-against supposing that, because an animal may be protected
-by its color, the color has been acquired on this account.
-On the supposition that the animal has become adapted by
-<span class='pageno' id='Page_358'>358</span>degrees, and through selection, we meet with all the objections
-that have been urged, in general, against the theory of
-natural selection. But if we assume here also that mutations
-have occurred without relation to the environment, and,
-having once appeared, determined in some cases the distribution
-of the species, we have at least a simple hypothesis that
-appears to explain the facts. If it be claimed that the resemblance
-is, in some cases, too close for us to suppose that
-it has arisen independently of the environment, it may be
-pointed out that it has not been shown that such a close
-resemblance is at all necessary for the continued existence
-of the species, and hence the argument is likely to prove
-too much. For instance, the most remarkable case of resemblance
-is that of Kallima, but in the light of a recent
-statement by Dean it may be seriously asked whether there
-is absolute need of such a close resemblance to a leaf. Even
-if it be admitted that to a certain extent the butterfly is at
-times protected by its resemblance to a leaf, it is not improbable
-that it could exist almost equally well without such a
-close resemblance. If this is true, natural selection could
-never have brought about such a close imitation of a leaf.
-Cases like these of over-adaptation are not unaccountable on
-the theory of mutation, for on this view the adaptation may
-be far ahead of what the actual requirements for protection
-demand. We meet occasionally, I think, throughout the living
-world with resemblances that can have no such interpretation,
-and a number of the kinds of adaptations to be
-described in this chapter show the same relation.</p>
-
-<p class='c010'>Some of the cases of mimicry appear also to fall under this
-head; although I do not doubt that many so-called cases of
-mimicry are purely imaginary, in the sense that the resemblance
-has not been acquired on account of its relation to
-the animal imitated. There is no need to question that in
-some cases animals may be protected by their resemblance to
-other animals, but it does not follow, despite the vigorous
-<span class='pageno' id='Page_359'>359</span>assertions of some modern Darwinians, that this imitation
-has been the result of selection. Until it can be shown that
-the imitating species is dependent on its close imitation for
-its existence, the evidence is unconvincing; and even if, in
-some cases, this should prove to be the case, it does not
-follow that natural selection has brought about the result, or
-even that it is the most plausible explanation that we have
-to account for the results. The mutation theory gives, in
-such cases, an equally good explanation, and at the same time
-avoids some of the difficulties that appear fatal to the selection
-theory.</p>
-
-<p class='c010'>What has been said against the theory of mimicry might
-be repeated in much stronger terms against the hypothesis
-of warning colors.</p>
-
-<p class='c010'>It seems to me, in this connection, that the imagination
-of the selectionist has sometimes been allowed to “run
-wild”; and while it may be true that in some cases the
-colors may serve as a signal to the possible enemies of the
-animal, it seems strange that it has been thought necessary
-to explain the origin of such colors as the result of natural
-selection. Indeed, some of these warning colors appear
-unnecessarily conspicuous for the purpose they have to perform.
-In other words, it does not seem plausible that an
-animal already protected should need to be so conspicuous.
-If we stop for a moment to consider what an enormous
-amount of destruction must have occurred, according to
-Darwin’s theory, in order to bring this warning coloration
-to its supposed state of perfection, we may well hesitate before
-committing ourselves to such an extreme view.</p>
-
-<p class='c010'>That gaudy colors have appeared or been present in animals
-that are protected in other ways is not improbable,
-when we consider the rôle that color plays everywhere in
-nature. That the presence of such colors may, to a certain
-limited extent, protect its possessor may be admitted without
-in any degree supposing that natural selection has directed
-<span class='pageno' id='Page_360'>360</span>the evolution of such color, or that it has been acquired
-through a life and death struggle of the individuals of the
-species.</p>
-<h3 class='c014'><span class='sc'>Sexual Dimorphism<a id='r29' /><a href='#f29' class='c017'><sup>[29]</sup></a> and Trimorphism</span></h3>
-
-<div class='footnote c026' id='f29'>
-<p class='c019'><span class='label'><a href='#r29'>29</a>.&nbsp;&nbsp;</span>This term is used here in the sense employed by Darwin. The same term is
-sometimes used for those cases in which the male departs very greatly from the
-female in form.</p>
-</div>
-
-<p class='c010'>It has been found in a few species of animals and plants
-that two or more forms of one sex may exist, and here we
-find a condition that appears to be far more readily explained
-on the mutation theory than on any other. The most important
-cases, perhaps, are those in plants, but there are also
-similar cases known amongst animals, and these will be given
-first.</p>
-
-<p class='c010'>There is a North American butterfly, <i>Papilio turnus</i>, that
-appears under at least two forms. In the eastern United
-States the male has yellow wings with black stripes. There
-are two kinds of females, one of which resembles the male
-except that she has also an orange “eye-spot”; the other
-female is much blacker, and this variety is found particularly
-in the south and west. The species is dimorphic, therefore,
-mainly in the latter regions.</p>
-
-<p class='c010'>The cases of seasonal dimorphism offer somewhat similar
-illustrations. The European butterfly, <i>Vanessa levana-prorsa</i>,
-has a spring generation (<i>levana</i>) with a yellow and black pattern
-on the upper surface of the wings. The summer generation
-(<i>prorsa</i>) has black wings “with a broad white transverse
-band, and delicate yellow lines running parallel to the margins.”
-These two types are sharply separated, and their differences
-in color do not appear to be associated with any special protection
-that it confers on the bearer. These facts in regard
-to Vanessa seem to indicate that differences may arise that
-are perfectly well marked and sharply defined, which yet
-appear to be without any useful significance.</p>
-
-<p class='c010'><span class='pageno' id='Page_361'>361</span>We meet with cases in which the same animal has at different
-times of year different colors, as seen in the summer
-and winter plumage of the ptarmigan. There is no direct
-evidence to show how this seasonable change has been
-brought about; but from the facts in regard to Vanessa we
-can see that it might have been at least possible for the
-white winter plumage, for instance, to have appeared without
-respect to any advantage it conferred on the animal, but after
-it had appeared it may have been to a certain degree useful to
-its possessor.</p>
-<div id='fig-5'  class='figcenter id009'>
-<img src='images/i362.jpg' alt='' class='ig001' />
-<div class='ic003'>
-<p><span class='sc'>Fig. 5.</span>—A, long-styled, and<br />B, short-styled, forms of <i>Primula veris</i>.<br />C, D, E, the three forms of the trimorphic flower of <i>Lythrum salicaria</i>, with petals and calyx removed on near side. (After Darwin.)</p>
-</div>
-</div>
-
-<p class='c009'>Amongst plants there are some very interesting cases of
-dimorphism and trimorphism in the structure of the flowers.
-Darwin has studied some of these cases with great care, and
-has made out some important points in regard to their powers
-of cross-fertilization.<a id='r30' /><a href='#f30' class='c017'><sup>[30]</sup></a> The common European cowslip, <i>Primula
-veris</i>, var. <i>officinalis</i>, is found under two forms, Figure
-<a href='#fig-5'>5 A and B</a>, which are about equally abundant. In one the style
-is long so that the stigma borne on its end comes to the
-top of the tube of the corolla. The stamens in this form
-stand about halfway up the tube. This is called the long-styled
-form. The other kind, known as the short-styled form,
-has a style only half as long as the tube of the corolla, and
-the stamens are attached around the upper end of the tube
-near its opening. In other words, the position of the end of
-the style (the stigma) and that of the stamens is exactly
-reversed in the two forms. The corolla is also somewhat
-differently shaped in the two forms, and the expanded part
-of the tube above the stamens is larger in the long-styled
-than in the short-styled form. Another difference is found
-in the stigma, which is globular in the long-styled, and
-depressed on its top in the short-styled, form. The papillæ
-<span class='pageno' id='Page_362'>362</span>on the former are twice as long as those on the short-styled
-form. The most important difference is found in the size of
-the pollen grains. These are larger in the long-styled form,
-being in the two cases in the proportion of 100 to 67. The
-shape of the grains is also different. Furthermore, the long-styled
-form tends to flower before the other kind, but the
-short-styled form produces more seeds. The ovules in the
-long-styled form, even when unfertilized, are considerably
-larger than those of the short-styled, and this, Darwin suggests,
-may be connected with the fact that fewer seeds are
-produced, since there is less room for them. The important
-<span class='pageno' id='Page_363'>363</span>point for our present consideration is that intermediate forms
-do not exist, although there are fluctuating variations about
-the two types. Moreover, the two kinds of flowers never
-appear on the same plant.</p>
-
-<p class='c010'>Darwin tried the effect of fertilizing the long-styled flowers
-with the pollen from the same flower or from other long-styled
-flowers. Unions of this sort he calls illegitimate, for
-reasons that will appear later. He also fertilized the long-styled
-flowers with pollen from short-styled forms. A union
-of this sort is called legitimate. Conversely, the short-styled
-forms were fertilized with their own pollen or with that from
-another short-styled form. This is also an illegitimate union.
-Short-styled forms fertilized with pollen from long-styled forms
-give again legitimate unions.</p>
-
-<div class='footnote c018' id='f30'>
-<p class='c019'><span class='label'><a href='#r30'>30</a>.&nbsp;&nbsp;</span>Many of the facts as to the occurrence of
-these cases were known before Darwin worked on them;
-but very little had been ascertained in regard to the
-sexual relation between the dimorphic and trimorphic
-forms, and it was here that Darwin obtained his most
-interesting results.</p>
-</div>
-
-<p class='c010'>The outcome of these different crossings are most curious.
-In the table, page 364, the results of the four combinations
-are given. It will be seen at once that the legitimate unions
-give more capsules, and the seeds weigh more, than in the
-illegitimate unions.</p>
-
-<p class='c010'>The behavior of the offspring from seeds of legitimate and
-illegitimate origin is even more astonishing. Darwin found
-in <i>Primula veris</i> (the form just described) that the seeds from
-the short-styled form fertilized with pollen from the same form
-germinated so badly that he obtained only 14 plants, of which
-9 were short-styled and 5 long-styled. The long-styled form
-fertilized with its own-styled pollen produced “in the first generation
-3 long-styled plants. From their seed 53 long-styled
-grandchildren were produced; from their seed 4 long-styled
-great-grandchildren; from their seed 20 long-styled
-great-great-grandchildren;
-and lastly, from their seed 8 long-styled
-and 2 short-styled great-great-great-grandchildren.”</p>
-<div class='fs80'>
-
-<table class='table7' summary=''>
-<colgroup>
-<col width='23%' />
-<col width='15%' />
-<col width='15%' />
-<col width='15%' />
-<col width='15%' />
-<col width='15%' />
-</colgroup>
-  <tr>
- <th class='bttd bbt c033'><br /><span class='sc'>Nature of Union</span></th>
- <th class='bttd bbt blt c033'><span class='sc'>Number of Flowers Fertilized</span></th>
- <th class='bttd bbt blt c033'><br /><span class='sc'>Number of Seed Capsules</span></th>
- <th class='bttd bbt blt c033'><span class='sc'>Maximum of Seeds in any one Capsule</span></th>
- <th class='bttd bbt blt c033'><span class='sc'>Minimum of Seeds in any one Capsule</span></th>
- <th class='bttd bbt blt c033'><span class='sc'>Average No. of Seeds per Capsule</span></th>
-  </tr>
-  <tr>
- <td class='bbt c034'>Long-styled form by pollen of short-styled form: <i>Legitimate union</i>.</td>
- <td class='bbt blt c033'>10</td>
- <td class='bbt blt c033'>6</td>
- <td class='bbt blt c033'>62</td>
- <td class='bbt blt c033'>34</td>
- <td class='bbt blt c033'>46.5</td>
-  </tr>
-  <tr>
- <td class='bbt c034'>Long-styled form by own-form pollen: <i>Illegitimate union</i>.</td>
- <td class='bbt blt c033'>20</td>
- <td class='bbt blt c033'>4</td>
- <td class='bbt blt c033'>49</td>
- <td class='bbt blt c033'>2</td>
- <td class='bbt blt c033'>27.7</td>
-  </tr>
-  <tr>
- <td class='bbt c034'>Short-styled form by pollen of long-styled form: <i>Legitimate union</i>.</td>
- <td class='bbt blt c033'>10</td>
- <td class='bbt blt c033'>8</td>
- <td class='bbt blt c033'>61</td>
- <td class='bbt blt c033'>37</td>
- <td class='bbt blt c033'>47.7</td>
-  </tr>
-  <tr>
- <td class='bbt c034'>Short-styled form by own-form pollen: <i>Illegitimate union</i>.</td>
- <td class='bbt blt c033'>17</td>
- <td class='bbt blt c033'>3</td>
- <td class='bbt blt c033'>19</td>
- <td class='bbt blt c033'>6</td>
- <td class='bbt blt c033'>12.1</td>
-  </tr>
-  <tr>
- <td class='bbt c034'>The two legitimate unions together.</td>
- <td class='bbt blt c033'>20</td>
- <td class='bbt blt c033'>14</td>
- <td class='bbt blt c033'>62</td>
- <td class='bbt blt c033'>37</td>
- <td class='bbt blt c033'>47.1</td>
-  </tr>
-  <tr>
- <td class='bbtd c034'>The two illegitimate unions together.</td>
- <td class='bbtd blt c033'>30</td>
- <td class='bbtd blt c033'>7</td>
- <td class='bbtd blt c033'>49</td>
- <td class='bbtd blt c033'>2</td>
- <td class='bbtd blt c033'>35.5</td>
-  </tr>
-</table>
-
-</div>
-<p class='c009'>From other long-styled plants, fertilized with their
-own-form pollen, 72 plants were raised, which were made up of
-68 long-styled and 4 short-styled. In all, 162 illegitimate
-unions of this sort produced 156 long-styled and 6 short-styled
-<span class='pageno' id='Page_364'>364</span>plants. It is evident from these results that the long-form
-pistils, fertilized with pollen from flowers of the same
-pistil-form (from other individuals as a rule), tend to produce
-the same form as their parents, although occasionally the
-other form. The fertility of these plants from an illegitimate
-union is found to be very low. Darwin observed that sometimes
-the male and female organs of these plants were in a
-very deteriorated condition. It is interesting to notice, in
-this connection, that in another species, <i>Primula sinensis</i>,
-illegitimate plants from long-styled parents were vigorous,
-but the flowers were small and more like the wild form.
-They were, however, perfectly fertile.</p>
-
-<p class='c010'><span class='pageno' id='Page_365'>365</span>Illegitimate plants from short-styled parents were dwarfed
-in stature, and often had a weakly constitution. They were
-not very fertile <i>inter se</i>, and remarkably infertile when legitimately
-fertilized. This kind of result, where a difference in
-the power of mutual intercrossing exists between two forms,
-recalls in many ways the difference in the results of crossing
-of different species of animals and plants, especially those
-cases in which a cross can be made in one way more successfully
-than in the other.</p>
-
-<p class='c010'>The heterostyled trimorphic plants, of which <i>Lythrum
-salicaria</i>, Figure <a href='#fig-5'>5 C, D, E</a>, may be taken as an example, are
-even more remarkable. There are three different kinds of
-flowers: in one the pistil is long and there is a medium and
-a short set of stamens; in another the pistil is of intermediate
-length and there is a long set and a short set of stamens;
-in the third kind the pistil is short, and there is a
-medium and a long set of stamens. There are possible only
-six sorts of legitimate unions between these three sets of
-flowers. No less than twelve kinds of illegitimate unions
-may occur. In regard to the difference in the sizes of the
-pollen grains, those from the long-styled form are the largest,
-from the mid-styled form next, and from the short-styled
-form the smallest. The extreme difference is as 100 to 60.
-“Nothing shows more clearly the extraordinary complexity
-of the reproductive system of this plant than the necessity of
-making eighteen distinct unions in order to ascertain the relative
-fertilizing power of the three forms.” Darwin tried the
-effect of each of these combinations, making 223 unions in
-all. The results are surprising. Comparing the outcome
-of the six legitimate unions with the twelve illegitimate ones,
-the following results were obtained:—</p>
-<div><span class='pageno' id='Page_366'>366</span></div>
-<div class='fs80'>
-
-<table class='table8' summary=''>
-<colgroup>
-<col width='27%' />
-<col width='18%' />
-<col width='18%' />
-<col width='18%' />
-<col width='18%' />
-</colgroup>
-  <tr>
- <th class='bttd bbt c024'><br /><br /><span class='sc'>Nature of Union</span></th>
- <th class='bttd bbt blt c033'><span class='sc'>Number of Flowers Fertilized</span></th>
- <th class='bttd bbt blt c033'><br /><span class='sc'>Number of Capsules Produced</span></th>
- <th class='bttd bbt blt c033'><br /><span class='sc'>Average No. of Seeds per Capsule</span></th>
- <th class='bttd bbt blt c033'><span class='sc'>Average No. of Seeds per Flower Fertilized</span></th>
-  </tr>
-  <tr>
- <td class='bbt c024'>The 6 legitimate unions</td>
- <td class='bbt blt c033'>75</td>
- <td class='bbt blt c033'>56</td>
- <td class='bbt blt c033'>96.29</td>
- <td class='bbt blt c033'>71.89</td>
-  </tr>
-  <tr>
- <td class='bbtd c024'>The 12 illegitimate unions</td>
- <td class='bbtd blt c033'>146</td>
- <td class='bbtd blt c033'>36</td>
- <td class='bbtd blt c033'>44.72</td>
- <td class='bbtd blt c033'>11.03</td>
-  </tr>
-</table>
-
-</div>
-<p class='c009'>This table shows that the fertility of the legitimate to that
-of the illegitimate is as 100 to 33, as judged by the flowers
-that produced capsules; and as 100 to 46 as judged by the
-average number of seeds per capsule. It is evident, therefore,
-that “it is only the pollen from the longest stamens
-that can fully fertilize the longest pistil; only that from the
-mid-length stamens, the mid-length pistil; and only that
-from the shortest stamens, the shortest pistil.”</p>
-
-<p class='c010'>Darwin tries to connect this fact with the visits of insects
-to the flowers. He says: “And now we can comprehend
-the meaning of the almost exact correspondence in length
-between the pistil in each form and of a set of six stamens
-in two of the other forms; for the stigma of each form is
-thus rubbed against that part of the insect’s body which becomes
-charged with the proper pollen.” A further conclusion
-that Darwin draws is “that the greater the inequality in
-length between the pistil and the set of stamens, the pollen
-of which is employed for its fertilization, by so much is the
-sterility the more increased.” Darwin also makes the following
-significant comment on the problem here involved:
-“The correspondence in length between the pistil in each
-form, and a set of stamens in the other two forms, is probably
-the direct result of adaptation, as it is of the highest
-service to the species by leading to full and legitimate fertilization.”
-He points out, on the other hand, that the increased
-sterility of the illegitimate unions, in proportion to
-the inequality in length between the pistil and the stamens
-<span class='pageno' id='Page_367'>367</span>employed, can be of no service at all. Neither can this relation
-have any connection with the facility for self-fertilization.
-“We are led, therefore, to conclude that the rule of
-increased sterility in accordance with increased inequality
-in length between the pistils and stamens is a purposeless
-result, incidental on those changes through which the species
-has passed in acquiring certain characters fitted to insure
-the legitimate fertilization of the three flowers.”</p>
-
-<p class='c010'>In regard to the plants that were raised from the seeds
-from legitimate and illegitimate unions, Darwin found in
-Lythrum that of twelve illegitimate unions two were completely
-barren, and nearly all showed lessened fertility; only
-one approached complete fertility. Darwin lays much emphasis
-on the close resemblance in the sterility of the illegitimate
-unions, and the sterility of different species when
-crossed. In both cases every degree of sterility is met with,
-“from very slightly lessened fertility to absolute barrenness.”
-The importance of this comparison cannot, I think, be overestimated,
-for, if admitted, it indicates clearly that the infertility
-between species cannot be used as a criterion of their
-distinctness, because here, in individuals belonging to the
-same species, we find sterility between pistils and stamens
-of different lengths. If, as I shall urge below, we must consider
-these different forms of Primula the results of a mutation,
-and not the outcome of selection as Darwin supposed,
-then this relation in regard to infertility becomes a point of
-great interest.</p>
-
-<p class='c010'>This brings us to the central point of our examination
-of these cases of dimorphism and trimorphism. How have
-these forms arisen? Darwin tries to account for them as
-follows: Since heterostyled plants occur in fourteen different
-families of plants, it is probable that this condition has been
-acquired independently in each family, and “that it can be
-acquired without any great difficulty.” The first step in the
-process he imagines to have been due to great variability
-<span class='pageno' id='Page_368'>368</span>in the length of the pistil and stamens, or of the pistil alone.
-Flowers in which there is a great deal of variation of this
-sort are known. “As most plants are occasionally cross-fertilized
-by the aid of insects, we may assume that this was
-the case with our supposed varying plant; but that it would
-have been beneficial to it to have been more regularly cross-fertilized.”
-“This would have been better accomplished if the
-stigma and the stamens stood at the same level; but as
-the stamens and pistil are supposed to have varied much
-in length, and to be still varying, it might well happen that
-they could be reduced much more easily through natural
-selection into two sets of different lengths in different individuals
-than all to the same length and level in all individuals.”
-By means of these assumptions, improbable as they may
-appear, Darwin tries to explain these cases of dimorphism.
-But when we attempt to apply the same argument to the
-trimorphic forms, it is manifestly absurd to pretend that three
-such sharply defined types could ever have been formed as
-the result of natural selection. But we have not even yet
-touched the chief difficulty, as Darwin himself points out.
-“The essential character of a heterostyled plant is that an
-individual of one form cannot fully fertilize, or be fertilized
-by, an individual of the same form, but only by one belonging
-to another form.” This result Darwin admits cannot be explained
-by the selection theory, for, as he says, “How can
-it be any advantage to a plant to be sterile with half of its
-brethren, that is, with the individuals belonging to the same
-form?” He concludes that this sterility between the individuals
-of the same form is an incidental and purposeless
-result. “Inner constitutional differences” between the
-individuals is the only suggestion that is offered to account
-for the phenomenon. In other words, it is clearly apparent
-that the attempt to apply the theory of selection has here
-broken down, and it is a fortunate circumstance that the
-Lamarckian theory cannot here be brought to the rescue, as
-<span class='pageno' id='Page_369'>369</span>it so often is in Darwin’s writings, when the theory of natural
-selection fails to give a sufficient explanation.</p>
-
-<p class='c010'>On the other hand, this is one of the cases that seem to
-fit in excellently with the mutation theory, for if these two
-forms of the primrose should appear, as mutations, and if, as
-is the case, they do not blend when crossed, but are equally
-inherited, they would both continue to exist as we find them
-to-day. Whether the similar forms were infertile with each
-other would be determined at the outset by the nature of
-the individual variation, and if, despite this obvious disadvantage,
-the forms could still continue to propagate themselves,
-the new dimorphic form would remain in existence. Darwin
-cannot explain the origin of dimorphic forms and trimorphic
-forms unless he can show that there is some advantage in
-having two forms, and as we have seen, he fails completely
-to show that there is an advantage. On the other hand, the
-result might have been reached on the mutation theory, even
-if the dimorphic and trimorphic forms were placed at a
-greater disadvantage than were the parent forms. In such
-a case fewer individuals might appear, or find a foothold; but
-as long as the race could be kept up the new forms would
-remain in existence. Thus, while no attempt is made to explain
-what has always been, and may possibly long remain,
-inexplicable to us, namely, the origin of the new form itself,
-yet granting that such new forms may sometimes appear
-spontaneously, they may be able to establish themselves, regardless
-of whether they are a little more or a little less well
-adapted to the environment than were their parent forms.
-If it should appear that the question is begged by the assumption
-that mutations such as these may appear (at one
-step or by a series of steps is immaterial), it should not be
-forgotten that the whole Darwinian theory itself also rests
-on the spontaneous appearance of fluctuating variations,
-whose origin it does not pretend to explain. In this respect
-both theories are on the same footing, but where the
-<span class='pageno' id='Page_370'>370</span>Darwinian theory meets with difficulties at every turn by
-assuming that new forms are built up through the action
-of selection, the mutation theory escapes most of these difficulties,
-because it applies no such rigid test as that of selection
-to account for the presence of new forms.</p>
-<h3 class='c014'><span class='sc'>Length of Life as an Adaptation</span></h3>
-
-<p class='c015'>It has been pointed out in the first chapter that the length
-of life of the individual has been supposed by some of the
-most enthusiastic followers of Darwin to be determined by
-the relation of the individual to the species as a whole. In
-other words, the doctrine of utility has been applied here also,
-on the ground that it would be detrimental to the species to
-have part of the individuals live on to a time when they can
-no longer propagate the race or protect the young. It is
-assumed that those varieties or groups of individuals (unfortunately
-not sharply defined) would have the best chance
-to survive in which the parent forms died as soon as they
-had lost the power to produce new individuals. Sometimes
-interwoven with this idea there is another, namely, that <i>death
-itself</i> has been acquired because it was more profitable to
-supplant the old and the injured individuals by new ones,
-than to have the old forms survive, and thus deprive the
-reproducing individuals of some of the common food supply.</p>
-
-<p class='c010'>This insidious form that the selection theory has taken in
-the hands of its would-be advocates only serves to show to
-what extremes its disciples are willing to push it. On the
-whole it would be folly to pursue such a will-o’-the-wisp, when
-the theory can be examined in much more tangible examples.
-If in these cases it can be shown to be improbable, the remaining
-superstructure of quasi-mystical hypothesis will fall
-without more ado.</p>
-
-<p class='c010'>That the problem of the length of life may be a real one
-for physiological investigation will be granted, no doubt, without
-<span class='pageno' id='Page_371'>371</span>discussion, and that in some cases the length of life and
-the coming to maturity of the germ-cell may be, in some way,
-physiologically connected seems not improbable; but that this
-relation has been regulated by the competition of species
-with each other can scarcely be seriously maintained. I will
-not pretend to say whether the mutation theory can or cannot
-be made to appear to give the semblance of an explanation
-of the length of life in each species, but it seems to me
-fairly certain that this is one of the questions which we are
-not yet in a position to attempt to consider on any theory of
-evolution.</p>
-<h3 class='c014'><span class='sc'>Organs of Extreme Perfection</span></h3>
-
-<p class='c015'>It has often been pointed out that certain organs may be
-more perfectly developed than the requirements of the surroundings
-strictly demand. At least we have no good reasons
-to suppose in some cases that constant selection is keeping
-certain organs at the highest possible point of development,
-yet, on the Darwinian theory, as soon as selection ceases
-to be operative the level of perfection must sink to that
-which the exigencies of the situation demand. The problem
-may be expressed in a different way. Does the animal
-or plant ever possess organs that are more perfectly adapted
-than the absolute requirements demand? If such organs
-are the result of fluctuating variations, they will be unable
-to maintain themselves in subsequent generations without
-a constant process of selection going on. If, on the other
-hand, the organs have arisen as mutations, they may become
-permanently established without respect to the degree
-of perfection of their adaptation. We can see, therefore,
-that cases of extreme perfection meet with no difficulty on
-the mutation theory, while they have proven one of the
-stumbling-blocks to the selection theory.</p>
-
-<p class='c010'>There are, in fact, many structures in the animal and plant
-kingdoms that appear to be more perfect than the requirements
-<span class='pageno' id='Page_372'>372</span>seem to demand. The exact symmetry of many forms
-appears in some cases to be unnecessarily perfect. The perfection
-of the hand of man, the development of his vocal
-organs, and certain qualities of his brain, as his musical and
-mathematical powers, seem to go beyond the required limits.
-It is not, of course, that these things may not be of some use,
-but that their development appears to have gone beyond what
-selection requires of these parts.</p>
-
-<p class='c010'>Closely related to this group of phenomena are those cases
-in which certain organs are well developed, but which can
-scarcely be of use to the animal in proportion to their elaboration.
-The electric organs of several fishes and skates are
-excellent examples of this sort of structures. The phosphorescent
-organs do not appear, in some forms at least, to be
-useful in proportion to their development. The selection
-theory fails completely to explain the building up of organs
-of this kind, but on the mutation theory there is no difficulty
-at all in accounting for the presence of even highly developed
-organs that are of little or of no use to the individual. If the
-organs appeared in the first place as mutations, and their
-presence was not injurious to the extent of interfering seriously
-with the existence and propagation of the new form,
-this new form may remain in existence, and if the mutations
-continued in the same direction, the organs might become
-more perfect, and highly developed. The whole class of secondary
-sexual organs may belong to this category, but a discussion
-of these organs will be deferred to the following section.</p>
-<h3 class='c014'><span class='sc'>Secondary Sexual Organs as Adaptations</span></h3>
-
-<p class='c015'>In the sixth chapter we have examined at some length Darwin’s
-interpretation of the secondary sexual characters.
-His explanation has been found insufficient in many cases to
-account for the conditions. That these organs do play in
-some cases a role in the relation of the sexes to each other
-may be freely admitted. In other words, in some animals the
-<span class='pageno' id='Page_373'>373</span>organs in one sex appear in the light of adaptations to certain
-instincts in the other sex. It would, perhaps, appear to
-simplify the problem to deny outright that any such relation
-exists; but I think, in the light of the evidence that we have,
-this procedure would be like that of the proverbial ostrich,
-which is supposed to stick its head in the sand in order to
-escape an anticipated danger. If we assumed this agnostic
-position, we might attempt to account for the appearance of
-secondary sexual organs as mutations that had appeared in
-one sex, and had no immediate connection with the other
-sex; and, so long as these organs were not directly and
-seriously injurious, we might assume that the animals in
-which such structures had appeared might be able to exist.
-But, on the other hand, I think that an examination of the
-evidence will show that this way out of the difficulty is not
-very satisfactory, for the organs in question appear, in some
-cases at least, to be closely connected with certain definite
-responses in the other sex. Moreover, as Darwin has so
-insistently pointed out, the action of the males is of such a
-sort that it is evidently associated with the presence of the
-secondary sexual organs which they often display before the
-other sex. Furthermore, the greater and often exclusive
-development of these organs during the sexual period distinctly
-points to them as in some way connected with the
-relation of the sexes to each other. And finally, there is a
-small, although not entirely convincing, body of evidence,
-indicating that the female is influenced by the action of
-the male; but I do not think that this evidence shows
-that she selects one individual at the expense of all
-other rivals. We meet here with a problem that is as profoundly
-interesting as it is obscure. In fact, if we admit
-that this relation exists we have a double set of conditions to
-deal with: first, the development in the males of certain
-secondary sexual organs; and secondly, the instinct to display
-these organs. The supposed influence of the display on
-<span class='pageno' id='Page_374'>374</span>the female may also have to be taken into account, although,
-for all we know to the contrary, the same results might
-follow were there no secondary sexual character at all, as
-is, in fact, the case in most animals.</p>
-
-<p class='c010'>I have a strong suspicion that much that has been written
-on this subject is imaginative, and in large part fictitious; so
-that it may, after all, be the wisest course not to attempt to
-explain how this relation has arisen until we have a more
-definite conception of what we are really called upon to
-explain. For example, when we see a gorgeously bedecked
-male displaying himself before a female, we feel that his finery
-must have been acquired for this very purpose. On the
-other hand, when we see an unornamented male also making
-definite movements before the female, we do not feel called
-upon to explain the origin of his colors. Now, it is not improbable
-that the ornaments of the first individual have not
-been acquired in order to display them before the female,
-and this view seems to me the more probable. From this
-standpoint our problem is at least much simplified. What
-we need to account for is only that the male is excited to
-undergo certain movements in the presence of the female,
-and possibly that the female may be influenced by the result.
-That this view is the more profitable is indicated by
-the occurrence of secondary sexual characters in the lower
-forms, as in the insects and crustaceans, in which it appears
-almost inconceivable that the ornamentation could have been
-acquired in connection with the æsthetic taste of the other
-sex. It does not seem to me that the conditions in the
-higher animals call for any other explanation than that which
-applies to these lower forms.</p>
-
-<p class='c010'>My position may be summed up in the statement, that,
-while in some cases there appears to be a connection between
-the presence in one sex of secondary sexual organs and their
-effect on the other sex, yet their origin cannot be explained
-on account of this connection.</p>
-<div>
-  <span class='pageno' id='Page_375'>375</span>
-  <h3 class='c014'><span class='sc'>Individual Adjustments as Adaptations</span></h3>
-</div>
-
-<p class='c015'>As pointed out in the first chapter, there is a group of adaptations,
-obviously including several quite different kinds of
-phenomena, that can at least be conveniently brought together
-under the general rubric of individual adjustments or
-regulations. A few examples of these will serve to show in
-what sense they may be looked upon as adaptations, and how
-they may be regarded from the evolutionary point of view.</p>
-<h3 class='c014'><span class='sc'>Color Changes as Individual Adaptations</span></h3>
-
-<p class='c015'>The change in color of certain fish in response to the color
-of the background, the change in color of some chrysalides
-also in response to their surroundings, appears to be of some
-use to the animals in protecting them from their enemies.
-The change in color from green to brown and from brown
-back to green in several lizards and in some tree frogs is
-popularly supposed to be in response to the color of the surroundings,
-but a more searching examination has shown that,
-in some cases at least, the response has nothing to do with
-the color of the background.</p>
-
-<p class='c010'>In the first cases mentioned above, in which the response
-appears to be of some advantage to the animal, the question
-may be asked, how have such responses arisen? The selection
-theory assumes that those animals that responded at
-first to a slight degree in a favorable direction have escaped,
-and this process being repeated, the power to change has been
-gradually built up. The mutation theory will also account
-for the result by assuming the response to have appeared
-as a new quality, but it has been preserved, not because it
-has been of vital importance to its possessor, but simply
-because the species possessing it has been able to survive,
-perhaps in some cases even more easily, although this is not
-essential. Even if the change were of no direct benefit,
-<span class='pageno' id='Page_376'>376</span>or even injurious to a slight degree, it might have been
-retained, as appears in fact to be the case in the change of
-color of the green lizards.</p>
-<h3 class='c014'><span class='sc'>Increase of Organs through Use and Decrease through Disuse</span></h3>
-
-<p class='c015'>We meet here with one of the most characteristic and
-unique features of living things as contrasted with non-living
-things. We shall have to dismiss at once the idea that we
-can explain this attribute of organisms by either the selection
-or the mutation theory; for we find animals possessing
-this power that could never be supposed to have acquired it
-by any experience to which they have been subjected; and
-since it appears to be so universally present, we cannot
-account for it as a chance mutation that may have appeared
-in each species. No doubt Wolff had responses of this kind
-in view when he made the rather sweeping statement that
-purposeful adaptation is the most characteristic feature of
-living things. The statement appears to contain a large
-amount of truth, if confined to the present group of phenomena.</p>
-
-<p class='c010'>This power of self-regulation may confer a great benefit
-on its possessor. The increase in the size and strength of
-the muscles through use may give the animal just those
-qualities that make its existence easier. The increase in the
-power of vision, or at least of visual discrimination through
-use, of the power of smell and of taste, of hearing and of
-touch, are familiar examples of this phenomenon.</p>
-
-<p class='c010'>However much we may be tempted to speculate as to how
-this property of the animal may have been acquired, we lack
-the evidence which would justify us in formulating even a
-working hypothesis. It may be that when we come to know
-more of what the process of contraction of the muscle involves,
-the possibility of its development as a consequence
-<span class='pageno' id='Page_377'>377</span>of its use may be found to be a very simple phenomenon that
-requires no special explanation at all to account for its existence
-in the individual, further than that the muscles are of
-such a kind that this is a necessary physical result of their
-action. But until we know more of the physiology involved
-in the process, it is idle to speculate about the origin
-of the phenomenon.</p>
-<h3 class='c014'><span class='sc'>Reactions of the Organism to Poisons, etc.</span></h3>
-
-<p class='c015'>In this case also we meet with a number of responses for
-whose origin we can give not the shadow of an explanation.
-On the other hand, the cases are significant in so far as a
-number of them show quite clearly that the response cannot
-have been acquired through the experience of the organism,
-or the selection of those individuals that have best resisted
-the particular poison. This is true, because in a number of
-cases the poison is a substance that the animal cannot possibly
-have met with during the ordinary course of its life, or
-of that of its ancestors. It may be argued, it is true, that
-in the case of the poisons produced by certain bacteria the
-power of resistance has been acquired through the survival
-of the less susceptible, or more resistant, individuals. Improbable
-as this may be in some cases, it does not, even if
-it were true, alter the real issue, for it can be shown, as has
-just been said, that the same power of responding adaptively
-is sometimes shown in cases of poisons that are new to the
-animal.</p>
-
-<p class='c010'>There is no question that different individuals respond in
-very different degrees to these poisonous substances, and it
-is easy to imagine in the case of contagious diseases that
-a sort of selective process might go on that would bring
-the race up to the highest point to which fluctuating variations
-could be carried, even to complete immunity; but even
-if this were the case, it seems to be true that the moment
-<span class='pageno' id='Page_378'>378</span>the selection stopped the race would sink back to the former
-condition.</p>
-
-<p class='c010'>All this touches only indirectly the main point that we
-have under consideration, namely, the existence of this
-power of resistance in cases where it cannot have been the
-result of any educative process. Since the responses to
-new poisons do not appear to be in principle different from
-the responses to those to which the organism may have possibly
-been subjected at times in the past, we shall probably
-not go far wrong if we treat all cases on the same general
-footing. Whether the power of adaptation to certain substances,
-such as nicotine, morphine, cocaine, arsenic, alcohol,
-etc., is brought about by the formation of a counter-substance
-is as yet unproven. And while it seems not improbable
-that in some of these instances it may turn out that this is
-the case, especially for poisons of plant origin, it is better
-to suspend judgment on this point until each case has been
-established.</p>
-
-<p class='c010'>In recent years it has been shown that the animal body
-has the power of making counter-substances when a very
-large number of different kinds of things are introduced
-into the blood. We seem to be here on the threshold of a
-field for discovery which may, if opened up, give us an insight
-into some of the most remarkable phenomena of adaptation
-shown by living things.</p>
-
-<p class='c010'>It has already been pointed out that it appears to be almost
-a <i>reductio ad absurdum</i> to speak of animals adapting themselves
-to poisonous substances. It is curious, too, that in
-man at least the use of these substances may arouse a craving
-for the poison, or at any rate the individual may become so
-dependent on the poison that the depression following its disuse
-may lead to a desire for a repetition of the dose. The
-two questions that are raised here must be kept apart, for
-the adaptation of the individual to the poison and the so-called
-craving for it may depend on quite different factors.
-<span class='pageno' id='Page_379'>379</span>Nevertheless, it seems to be true in the case of morphine and
-of arsenic, and probably for some other substances as well,
-that if their use is suddenly stopped the individual may die
-in consequence. In this respect the organism behaves exactly
-as it does to an environment to which it has become
-adapted.</p>
-<h3 class='c014'><span class='sc'>Regeneration</span></h3>
-
-<p class='c015'>Many animals are able to replace lost parts, and all of
-them can heal wounds and mend injuries. This power is
-obviously of great advantage to them, and it has been supposed
-by Darwin, and more especially by his followers, that
-the power has been acquired through natural selection. It
-is not difficult to show that regeneration could not, in many
-cases, and presumably in none, have been acquired in this
-way. Since I have treated this subject at some length
-recently in my book on “Regeneration,” I shall attempt to
-do no more here than indicate the outline of the argument.</p>
-
-<p class='c010'>The Darwinians believe that, if some individuals of a
-species have the power to replace a part that is lost better
-than have other individuals, it would follow that those would
-survive that regenerate best, and in this way after a time the
-power to regenerate perfectly would be acquired.</p>
-
-<p class='c010'>But the matter is by no means so simple as may appear
-from this statement. In the first place, it is a matter of
-common observation that all the individuals of a species are
-never injured in the same part of the body at the same time.
-In those cases in which it is known that a special part is
-often injured, an examination has shown that there are not
-more than ten per cent of individuals that are injured at any
-one time, and in the case of the vast majority of animals
-this estimate is much too great. Thus there will be very
-little chance for competition of the injured individuals in
-each generation with each other, and the effects that are
-imagined to be gained as a result would be entirely lost
-<span class='pageno' id='Page_380'>380</span>by crossing with the uninjured individuals. But it is not
-necessary to consider this possibility, since there is another
-fact that shows at once that the power to regenerate could
-not have been gained through selection. The number of uninjured
-individuals in each generation will be much greater
-than the injured ones, and these will have so great an advantage
-over the injured individuals that, if competition
-approached the degree assumed by the selectionists, the injured
-individuals should be exterminated. A slight advantage
-gained through better powers of regeneration would
-be of little avail in competition, as compared with the competition
-with the uninjured individuals. Since selection is
-powerless to accomplish its end without competition, and
-since with competition all the injured individuals would be
-eliminated, it is clear that an appeal cannot be made to
-selection to explain the power of regeneration.</p>
-
-<p class='c010'>In many cases the power of regeneration could not have
-been slowly acquired through selection, since the intermediate
-steps would be of no use. Unless, for example, a
-limb regenerated from the beginning almost completely, the
-result would be of no use to the animal. If the limb did
-regenerate completely the first time it was injured, then the
-selection hypothesis becomes superfluous.</p>
-
-<p class='c010'>There are also a few cases known in which a process of regeneration
-takes place that is of no use to the animal. If, for
-instance, the earthworm (<i>Allolobophora fœtida</i>) be cut in two
-in the middle, the posterior piece regenerates at its anterior
-cut end, not a head, but a tail. Not by the widest stretch
-of the imagination can such a result be accounted for on the
-selection theory. Again, we find the reverse case, as it were,
-in certain planarians. If the head of <i>Planaria lugubris</i> is
-cut off just behind the eyes, there develops at the cut
-surface of this head-piece another head turned in the opposite
-direction. Here again we have the regeneration of a perfect
-structure, but one that is entirely useless to the individual.
-<span class='pageno' id='Page_381'>381</span>The development of an antenna in place of an eye
-in the shrimp, when the eye stalk is cut off near its base, is
-another instance of the occurrence of a perfectly constant
-process, but one that is of no use to the organism.</p>
-
-<p class='c010'>When we recall that in some organisms regeneration takes
-place in almost every part of the body, it does not seem
-possible that this power could have been acquired by selection.
-And when we find that many internal organs regenerate,
-that can rarely or never be injured without the animal
-perishing, it seems impossible that this can be ascribed to
-the principle of natural selection.</p>
-
-<p class='c010'>It has also been found that if the first two cells of the
-egg of a number of animals, jellyfish, sea-urchins, salamanders,
-etc., be separated, each will produce an entire animal.
-In some of these cases it is inconceivable that the process
-could ever have been acquired through selection, because the
-cells themselves can be separated only by very special and
-artificial means.</p>
-
-<p class='c010'>These, and other reasons, indicate with certainty that regeneration
-cannot be explained by the theory of natural
-selection.</p>
-
-<div class='pbb'>
- <hr class='pb c006' />
-</div>
-<div class='chapter'>
-  <span class='pageno' id='Page_382'>382</span>
-  <h2 class='c008'>CHAPTER XI<br /> <br /><span class='c013'>TROPISMS AND INSTINCTS AS ADAPTATIONS</span></h2>
-</div>
-<p class='c009'><span class='sc'>Of</span> the different kinds of adaptation none are more remarkable
-than those connected with the immediate responses
-of organisms to external agents. These responses are usually
-thought of as associated with the nervous system; and while
-in the higher forms the nervous system plays an important
-role in the reaction, yet in many cases it is little more than
-the shortest path between the point stimulated and the muscles
-that contract; and in the lower animals, where we find just as
-definite responses, there may be no distinct nervous system,
-as in the protozoa, for instance.</p>
-
-<p class='c010'>Many of the so-called instincts of animals have been shown
-in recent years to be little more than direct responses to external
-agents. Many of these instincts are for the good of
-the individual, and must be looked upon as adaptations. For
-example: if a frog is placed in a jar of water, and the temperature
-of the water lowered, the frog will remain at the
-top until the water reaches 8 degrees C., when it will dive
-down to the bottom of the jar; and, if the temperature is
-further lowered, it will remain there until the water becomes
-warmer again, when it will come to the surface again. It is
-clear that, under the ordinary conditions of life of the frog,
-this reaction is useful to it, since it leads the animal to go to
-the bottom of the pond on the approach of cold weather,
-and thus to avoid being frozen at the surface.</p>
-
-<p class='c010'>Another illustration of an instinct that is a simple response
-to light is shown by the earthworm. During the day the
-worm remains in its burrow, but on dark nights it comes out
-<span class='pageno' id='Page_383'>383</span>of its hole, and lies stretched out on the surface of the ground.
-It procures its food at this time, and the union of the individuals
-takes place. In the early morning the worm retires into
-its burrow.</p>
-
-<p class='c010'>This habit of the earthworm is the direct result of its reaction
-to light. It crawls away from ordinary light as bright
-as that of diffuse daylight, and, indeed, from light very
-much fainter than that of daylight. If, however, the light
-be decreased to a certain point, the worm will then turn and
-crawl toward the source of light. This lower limit has been
-found by Adams to be about that of .001 candle-metre. This
-corresponds to the amount of light of a dark night, and gives
-an explanation of why the worm leaves its burrow only at
-night, and also why it crawls back on the approach of dawn.
-It is also obvious that this response is useful to the animal,
-for if it left the burrow during the day, it would quickly fall
-a prey to birds.</p>
-
-<p class='c010'>The blow-fly lays its eggs on decaying meat, on which the
-larvæ feed. The fly is drawn to the meat by its sense of
-smell, a simple and direct response to a chemical compound
-given off by the meat. The maggot that lives in the decaying
-meat is also attracted by the same odor, as Loeb has
-shown, and will not leave the meat, or even a spot on a
-piece of glass that has been smeared with the juice of the
-meat, so long as the odor remains. Here again the life of
-the race depends on the proper response to an external
-agent, and the case is all the more interesting, since the
-response of the fly to the meat is of no immediate use to
-the fly itself, but to the maggot that hatches from the egg
-of the fly.</p>
-
-<p class='c010'>The movement toward or from a stimulating agent is, in
-some cases, brought about in the following way. Suppose
-an earthworm is lying in complete darkness, and light be
-thrown upon it from one side. The worm turns its head,
-as it thrusts it forward, to the side away from the light; and
-<span class='pageno' id='Page_384'>384</span>as it again moves forward, it continues to bend its head
-away from the light, until it is crawling directly away from
-the source. When the light first strikes the worm, the two
-sides will be differently illuminated. This causes a bending
-of the head, as it stretches forward, toward the side of less
-illumination, and the bending is due to a stronger contraction
-of some of the muscles on the less illuminated side;
-at least the reaction appears to be due to a simple response
-of this kind. When the body has been so far turned that
-the two sides are equally illuminated, the muscles of the two
-sides will contract equally, and the movement will be straight
-forward and away from the light. If the reaction is as simple
-as this (which is in principle the explanation advanced by
-Loeb), the result is a simple reflex act, and need not involve
-any consciousness or intentional action on the part of the
-worm to crawl away from the light. In fact, the same reaction
-takes place when the brain is removed, not so quickly or
-definitely, it is true, but this may be due to the removal of
-the anterior segments of the worm, in which part the skin
-appears to be more sensitive to light than elsewhere.</p>
-
-<p class='c010'>Another factor that plays an important rôle in the habits
-of the earthworm is the response to contact,—the so-called
-stereotropism. If, in crawling over a flat surface, the worm
-comes in contact with a crevice, it will crawl along it, and
-refuse to leave until the end is reached. The contact holds
-the worm as strongly as though it were actually pulled into
-the crevice. It can be forced to leave a crevice only by
-strong sunlight, and then it does not do so at once. If the
-worm crawls into a small glass tube, it is also held there
-by its response to contact, and the smaller the tube, the more
-difficult is it to make the worm leave by throwing strong sunlight
-upon it.</p>
-
-<p class='c010'>Loeb has found that when winged aphids, the sexual
-forms, are collected in a tube, and the tube is kept in a
-room, the aphids crawl toward the light. This happens in
-<span class='pageno' id='Page_385'>385</span>ordinary diffuse light, as well as in lamplight. It is stated
-that the animals orientate themselves towards the light more
-quickly when it is strong than when it is weak. They turn
-their bodies toward the light, and then move forward in the
-direction from which the rays come. It can be shown by a
-simple experiment that the aphids are turned by the <i>direction</i>
-of the light, and not by its intensity. If they are placed in a
-tube, and the tube laid obliquely before a window in such a
-way that the direct sunlight falls only on the inner end of the
-tube, the aphids will, if started at the inner end of the tube,
-first crawl toward the outer surface of the tube, and then wander
-along this wall, passing out of the region of sunlight into
-the end of the tube nearest the window, where they come to
-rest at the end. They have moved constantly towards the
-direction from which the rays come, passing, as it were, from
-ray to ray, but each time toward a ray nearer the source of
-the light.</p>
-
-<p class='c010'>If the tube be turned toward the window, and the window
-end be covered with blue glass, the aphids crawl into this
-end of the tube, as they would have done had the tube been
-uncovered. If, on the other hand, the end of the tube be
-covered with red glass, they do not crawl into the part of the
-tube that is covered, unless they are very sensitive to light.
-Even in the latter case they may remain scattered in the red
-part, and do not all accumulate at the end, as they do when
-blue glass is used. In other words, while they respond to blue
-as they do to ordinary light, they behave toward red as they do
-towards a very faint light.</p>
-
-<p class='c010'>In diffuse daylight the aphids, as has been said, crawl
-toward the light, but if they come suddenly into the sunlight
-they begin to fly. Thus they remain on the food-plant
-until the sun strikes it, and then they fly away.</p>
-
-<p class='c010'>The aphid also shows another response; it is negatively
-geotropic, <i>i.e.</i> it tends to crawl upward against gravity. If
-placed on an inclined, or on a vertical, surface, it will crawl
-<span class='pageno' id='Page_386'>386</span>upward. Such an experiment is best made in the dark,
-since in the light the aphid also responds to the light. If
-put on a window it crawls upward never downward.</p>
-
-<p class='c010'>Aphids are also sensitive to heat. If they are placed in a
-darkened tube and put near a stove, they crawl away from
-the warmer end; but if they are acted upon by the light at
-the same time, they will be more strongly attracted by the
-light than repulsed by the heat. We thus see that there are
-at least three external agents that determine the movements
-of this animal, and its ordinary behavior is determined by
-a combination of these, or by that one that acts so strongly
-as to overpower the others.</p>
-
-<p class='c010'>The swarming of the male and female ants is also largely
-directed by the influence of light. Loeb observed that when
-the direct sunlight fell full upon a nest in a wall the sexual
-forms emerged, and then flew away. Other nests in the
-ground were affected earlier in the day, because the sun
-reached them first. These ants, when tested, were found to
-respond to light in the same way as do the aphids. The
-wingless forms, or worker ants, do not show this response,
-and the winged forms soon lose their strong response to light
-after they have left the nest. Thus we see that the heliotropism
-is here connected with a certain stage in the development
-of the individual; and this is useful to the species, as it
-leads the winged queens and males to leave the nest, and
-form new colonies. Even the loss of response that takes
-place later may be looked upon as beneficial to the species,
-since the queens do not leave the nest after they have once
-established it.</p>
-
-<p class='c010'>It is familiar to every one that many of the night-flying
-insects are attracted to a lamplight, and since those that fly
-most rapidly may be actually carried into the flame before
-they can turn aside, it may seem that such a response is
-worse than useless to them. The result must be considered,
-however, in connection with other conditions of their life.
-<span class='pageno' id='Page_387'>387</span>The following experiments carried out by Loeb on moths
-show some of the responses of these insects to light.</p>
-
-<p class='c010'>Night-flying moths were placed in a box and exposed in a
-room to ordinary light. As twilight approached the moths
-became active and began to fly always toward the window
-side of the box. They were positively heliotropic to light of
-this intensity. If let out of the case, they flew toward the
-window, where they remained even during the whole of the
-next day, fully exposed to light. If the moth is disturbed in
-the daytime, so that it flies, it goes always toward the light,
-and never away from it. These facts show that the moth is
-always positively heliotropic, and also that the flight toward
-the lamp is a natural response, misapplied in this case.
-That the moths do not fly by day is due to another factor,
-namely, the alternation in the degree of their sensitiveness at
-different times. But this condition alone does not seem to
-account fully for all the facts.</p>
-
-<p class='c010'>If the moths are given the alternative of flying toward the
-evening light, or toward the lamp, they always go toward
-the brighter light. Thus if, when they swarm at dusk, they
-are set free in the middle of the room, at the back of which
-a lamp is burning, the moths fly toward the window. If,
-however, they are set free within a metre of the lamp, they
-fly toward it.</p>
-
-<p class='c010'>The explanation that Loeb offers of the habit of these
-moths to fly only in the evening is, that, although they are
-at all times positively heliotropic, they respond to light only
-in the evening. In other words, it is assumed that there is a
-periodic change in their sensitiveness to light, which corresponds
-with the change from day to night. Loeb says that,
-just as certain flowers open only at night, and others only
-during the day, so do moths become more responsive in
-the evening, and butterflies during the day. Both moths and
-butterflies are positively heliotropic, and the sensitiveness of
-moths to light may be even greater in the evening than is
-<span class='pageno' id='Page_388'>388</span>that of butterflies, for the light of the evening to which the
-moth reacts is less than the minimal to which the butterfly
-responds.</p>
-
-<p class='c010'>Moths appear to pass into a sort of sleep during the day,
-while butterflies are quiescent only at night. The periodicity
-of the sleeping time continues, at least for several days,
-when the insects are kept in the dark. For instance, moths
-kept in the dark become restless as the evening approaches,
-as Réaumur observed long ago. It has been found in plants
-that this sort of periodicity may continue for several days,
-but gradually disappears if the plants are kept in the dark.
-By using artificial light, and exposing the plants to it during
-the night, and putting them in the dark during the day, a new
-periodicity, alternating with the former one, may be induced;
-and this will continue for some days if the plants are then
-kept continually in the dark.</p>
-
-<p class='c010'>Loeb tried the experiment of exposing the quiescent moths
-suddenly to a lower intensity of light, in order to see if they
-would respond equally well at any time of day. It was found
-that if the change was made in the forenoon, between six
-o’clock and noon, it was not possible to awaken the moths by
-a sudden decrease in the intensity of the light. But it was
-possible to do so in the afternoon, long before the appearance
-of dusk. It appears, therefore, that in this species, <i>Sphinx
-euphorbiæ</i>, it is possible to influence the period of awakening
-by decreasing the intensity of light, but this can be done
-only near the natural period of awakening. It seems to me
-that this awaking of a positively heliotropic animal by decreasing
-the light needs to be further investigated.</p>
-
-<p class='c010'>The day butterflies are also positively heliotropic. Butterflies
-of the species <i>Papilio machaon</i>, that have been raised
-from the pupa, remain quietly on the window in the diffuse
-daylight of a bright day. They can be carried around on
-the finger without leaving it, but the moment they come into
-the direct rays of the sun they fly away.</p>
-
-<p class='c010'><span class='pageno' id='Page_389'>389</span>Butterflies that have just emerged from their pupa case
-exhibit a marked negative geotropic reaction, and this appears
-to be connected with the necessity of unfolding their
-wings at this time. Loeb says that the same cause that
-determines the direction of the falling stone and the paths of
-the planets, namely, gravity, also directs the actions of the
-butterfly that has just left its pupa case. The geotropic
-response is especially strong at first. The animal wanders
-around until it reaches a vertical wall, which it immediately
-ascends, straight upward, and remains hanging at the top
-until its wings have unfolded. A similar response occurs in
-the final stage of the larva of the May-fly, which leaves the
-water and crawls up a blade of grass, or other vertical support,
-and there, bursting the pupa skin, it dries its wings and
-flies away. That this is a reaction to gravity and not to
-light is shown by Loeb’s observation, that their empty skins
-are sometimes observed under a bridge where the light does
-not come from above. “This observation on the larva of
-the May-fly contradicts the assumption that the ‘purpose’ of
-the geotropic response of the butterfly is that it may the
-better unfold its new wings, for in the ephemerid larva the
-negative geotropism appears at a time when no wings are
-present.” On the other hand, it should not be overlooked
-that the reaction is important for the May-fly larva in other
-ways, because it leads the larva to leave the water at the
-right period, and come out into the air, where the flying
-insect can more safely emerge.</p>
-
-<p class='c010'>It is not without interest to find that caterpillars exhibit
-some of the same reaction shown by butterflies. Loeb
-has made numerous experiments with the caterpillars of
-<i>Porthesia chrysorrhœa</i>. The caterpillars of this moth collect
-together in the autumn and spin a web or nest in
-which they pass the winter. If they are taken from the
-nest and brought into a warm room, they will orientate
-themselves to the light, and also crawl toward it. If
-<span class='pageno' id='Page_390'>390</span>placed in a tube, they crawl to the upper side of the glass
-and then along this side toward the light. If a covering is
-placed over the end of the tube that is turned toward the
-window, the caterpillars will crawl only as far as the edge
-of the cloth. They also react negatively to gravity. If
-kept in a dark room, they will crawl upward to the top of
-the receptacle in which they are enclosed. If subjected
-to the influences of both light and gravity, they respond
-more strongly to the light. The caterpillars also show a
-contact reaction. They tend to collect on convex sides or
-on corners and angles of solid bodies. They may even pile
-up one on top of the other in response to this reaction; the
-convex side of a quiescent animal acting on another animal
-crawling over it as any convex surface would do and holding
-the animal fast.</p>
-
-<p class='c010'>These three kinds of reactions determine the instincts of
-these caterpillars. In the spring, when they become warm,
-they leave the nest. Positive heliotropism and negative
-geotropism compel them to crawl upward to the tops of the
-branches of the trees, and there the contact reaction with the
-small buds holds them fast in this place. That they are not
-attracted to the end of the branches by the food that they
-find there is shown by placing buds in the bottom of the
-tubes in which the caterpillars are contained. The caterpillars
-remain at the top of the tube, although food is within easy
-reach. If, however, they are placed directly on the buds, the
-contact reaction will hold them there, and they will not crawl
-farther upward. Curiously enough, as soon as the caterpillars
-have fed and the time for shedding approaches, the
-responsiveness to light and to gravity decreases, and at the
-time of shedding they do not respond at all to these agents.
-These same caterpillars react also to warmth above a certain
-point. In a dark tube placed near a stove, the caterpillars
-collect at the end farthest away from the source of the heat.
-They react to light best at a temperature between 20 and 30
-<span class='pageno' id='Page_391'>391</span>degrees C., and above this temperature point they become
-restless and wander about.</p>
-
-<p class='c010'>The very close connection between the reactions of this
-caterpillar and its mode of life is perfectly obvious. The
-entire series of changes seems to have for its “purpose” the
-survival of the individual by bringing it to the place where
-it will find its food. It may seem natural to conclude that
-these responses have been acquired for this very purpose,
-but let us not too quickly jump at this obvious conclusion
-until the whole subject has been more fully examined.</p>
-
-<p class='c010'>The upward and downward movements of some pelagic
-animals have been shown to depend on certain tropic responses.
-Every student of marine zoology is familiar with
-the fact that many animals come to the surface at night,
-and go down at the approach of daylight. It has been
-shown that this migration is due largely to a response to
-light. Light can penetrate to only about four hundred
-metres in sea-water, and there is complete darkness below
-this level. It has been shown that the swimming larvæ of
-one of the barnacles is positively heliotropic in a weak light,
-but negatively heliotropic in a stronger light. Animals
-having responses like these will come to the surface as the
-light fades away in the evening and remain there until the
-light becomes too bright in the following morning. They
-will then become negatively heliotropic and begin to go
-down. When they reach a level where the intensity of the
-light is such that they become positively heliotropic, they
-will turn and start upward again. Thus during the day
-they will keep below the surface, remaining in the region
-where they change from positive to negative, and <i>vice versa</i>.</p>
-
-<p class='c010'>It would not be difficult to imagine that this upward and
-downward migration of pelagic animals is useful to them, but,
-on the other hand, it may be equally well imagined that the
-response may be injurious to them. Thus it might be supposed
-that certain forms could procure their food by coming
-<span class='pageno' id='Page_392'>392</span>to the surface at night, and avoid their enemies by going
-down during the day. But it is difficult to see why organisms
-that serve as prey should not have acquired exactly the
-opposite tropisms in order to escape.</p>
-
-<p class='c010'>Some of these marine forms are also geotropic. Loeb has
-determined that “the same circumstances that make the
-animals negatively heliotropic also make them positively
-geotropic, and <i>vice versa</i>.” It was found, for instance, that
-the larva of the marine worm Polygordius is negatively
-geotropic at a low temperature, while at a higher temperature
-it is positively geotropic. This response would drive
-the animals upward when the water becomes too cold, and
-back again if the surface water becomes too warm; but
-whether the response is so adjusted that the animals keep, as
-far as possible, in water of that temperature that is best for
-their development, we do not know. We can easily imagine
-that within wide limits this is the case.</p>
-
-<p class='c010'>The change from positive to negative can also be brought
-about in other ways. One of the most striking cases of
-this sort is that described by Towle in one of the small
-crustaceans, <i>Cypridopsis vidua</i>. It was found that after an
-animal had been picked up in a pipette its response was always
-positive; that is, it swam toward the light, no matter
-what its previous condition had been. The disturbance
-caused by picking the animal up induced always a positive
-response towards light. If the light were moved, the Cypridopsis
-followed the light. In this way it could be kept
-positive for some time, but if it came to rest, or if it came into
-contact with the sides or end of the trough, it became, after
-a short time, negatively heliotropic, and remained negative as
-long as it could be kept in motion, without being disturbed, or
-coming into contact with a solid object. If when positive
-it were allowed to reach the glass at the end of the trough, it
-would swim about there, knocking against the glass, and then
-soon turn and swim away from the light. If the light were
-<span class='pageno' id='Page_393'>393</span>shifted while the negative animal was in the middle of the
-trough, it would turn and swim directly away, as before, from
-the source of light. It could be kept in this negative state as
-long as it did not come into contact with the ends.</p>
-
-<p class='c010'>It appears that the positive condition in Cypridopsis is of
-short duration, and ceases after a while either as a response
-to contact or without any observable external factor causing
-the change.</p>
-
-<p class='c010'>This crustacean lives at the bottom of pools, amongst water-plants,
-and here also, no doubt, the same change from one to
-the other reaction takes place. What possible advantage it
-may be to the animal to be kept continually changing in this
-way is not at all obvious, nor, in fact, are we obliged to
-assume that this reaction may be of any special use to it.
-Indeed, it is far from obvious how the change that causes the
-animal to swim toward the light when it is disturbed could
-be of the least advantage to it.</p>
-
-<p class='c010'>In another crustacean, one of the marine copepods,
-<i>Labidocera æstiva</i>, it has been shown by Parker that the
-male and female react in a somewhat different way both to
-light and to gravity. The females are strongly negatively
-geotropic, and this sends them up to the top of the water.
-The males are very slightly negatively geotropic. The
-females are strongly positively heliotropic toward light of
-low intensity; the males show the same response to a less
-degree. To strong light the females are negative and the
-males are indifferent. On the other hand, the males are
-attracted to the females, probably in response to some
-chemical substance diffusing from the females, since the
-males show the same reaction when the females are enclosed
-in an opaque tube through whose ends a diffusion
-of substances may take place. This crustacean frequents
-the surface of the ocean from sunset to sunrise. During the
-day it retires to deeper water. Its migrations can be explained
-as follows: The females come to the surface at
-<span class='pageno' id='Page_394'>394</span>night, because they are positively heliotropic to weak light,
-and also because they are negatively geotropic. They go
-down during the day, because they react to bright light
-more strongly than to gravity. The males follow the females,
-largely because they react positively chemotactically
-toward the females.</p>
-
-<p class='c010'>Some other animals respond in a somewhat different way
-to light, as shown by the fresh-water planarians. These
-animals remain during the day under stones, where the
-amount of light is relatively less than outside. If they are
-placed in a dish in the light in front of a window, they crawl
-away from the light, but when they reach the back of the
-dish they do not come to rest, but continue to crawl around
-the sides of the dish even toward the light. The light
-makes the worms restless, and while they show a negative
-response as long as they are perfectly free to move away
-from the light, they will not come to rest when they come
-to the back of the dish if they are there still in the light,
-because the irritating action of the light on them is stronger
-than its directive action. If, however, in crawling about
-they come accidentally into a place less bright than that in
-which they have been, they stop, and will not leave this
-somewhat darker spot for a brighter one, although they
-might leave the newly found spot for one still less bright.</p>
-
-<p class='c010'>At night the planarians come out and wander around,
-which increases their chance of finding food, although it
-would not be strictly correct to say that they come out in
-search of food. If, however, food is placed near them, a
-piece of a worm, for example, they will turn toward it,
-being directed apparently by a sense of smell, or rather of
-taste.</p>
-
-<p class='c010'>The heliotropic responses of the planarians appear to be of
-use to them, causing them to hide away in the daytime, and
-to come out only after dark, when their motions will not discover
-them to possible enemies. But some of the planarians
-<span class='pageno' id='Page_395'>395</span>are protected in other ways, so that they will not be eaten by
-fish, probably owing to a bad taste; so that it is not so apparent
-that they are in real need of the protection that their
-heliotropic response brings to them. Their turning towards
-their food is, however, beyond question of great advantage to
-them, for in this way they can find food that they cannot
-detect in any other way.</p>
-
-<p class='c010'>The unicellular plants were amongst the first organisms
-whose tropic responses were studied, and the classical work
-of Strasburger gave the impetus to much of the later work.
-In recent years the unicellular animals, the protozoans,
-have been carefully studied, more especially by Jennings.
-His results show that the reactions in these animals
-are different in some important respects from those met
-with in higher forms. For instance, most of the free-swimming
-infusoria are unsymmetrical, as are also many of
-the flagellate forms, and as they move forward they rotate
-freely on a longitudinal axis. It is therefore impossible that
-they could orientate themselves as do the higher animals that
-have been described above, and we should not expect these
-Protozoa to react in the same way. In fact, Jennings shows
-that they exhibit a different mode of response. Paramœcium
-offers a typical case. As it moves forward it rotates toward
-the aboral side of the body. As a result of the asymmetry
-of the body, the path followed, as it revolves on its own axis,
-is that of a spiral. Did the animal not rotate, as it swims
-forward, its asymmetrical form would cause it to move in a
-circle, but its rotation causes, as has been said, the course to
-be that of a spiral, and the general direction of movement is
-forward.<a id='r31' /><a href='#f31' class='c017'><sup>[31]</sup></a> The rotation of a paramœcium on its axis is in turn
-caused by the oblique stroke of the cilia that cover the surface
-of the body. Their action when reversed causes the
-animal to rotate backward.</p>
-
-<div class='footnote c018' id='f31'>
-<p class='c019'><span class='label'><a href='#r31'>31</a>.&nbsp;&nbsp;</span>The same result is attained by a bullet that is caused by the rifling to rotate
-as it moves forward.</p>
-</div>
-
-<p class='c010'><span class='pageno' id='Page_396'>396</span>If a drop of weak acid be put into the water in which the
-paramœcia are swimming,—for instance, in the water between
-a cover-slip and a slide,—it will be found, after a
-time, that many individuals have collected in the drop. It
-was at first supposed that the paramœcia are attracted by
-the diffusion of the acid in the water, and turn toward the
-source of the chemical stimulus; but Jennings has shown that
-this is not the way in which the aggregation is brought
-about. If the individuals are watched, it will be found that
-they swim forward in a spiral path without regard to the
-position of the drop of acid. If one happens, by chance, to
-run into the drop, there is no reaction as it enters, but when
-it reaches the other side of the drop, and comes into contact
-with the water on this side, it suddenly reacts. It stops,
-backs into the middle of the drop, rotates somewhat toward
-the aboral side (<i>i.e.</i> away from the vestibule), and then starts
-forward again, only to repeat the action on coming into contact
-with the edge of the drop again. The paramœcium has
-been caught in a veritable trap. All paramœcia that chance
-to swim into the drop will also be caught, until finally a large
-number will accumulate in the region. The result shows,
-that, in passing from ordinary water into a weak acid, no
-reaction takes place; but having once entered the acid, the
-animal reacts on coming into contact with the water again.</p>
-
-<p class='c010'>On the other hand, there are some substances to which the
-paramœcium may be said to be negatively chemotropic. If
-a drop of a weak alkaline solution be put into water in which
-paramœcium is swimming, an individual that happens to run
-against it reacts at once. It stops instantly, backs off,
-revolving in the opposite direction, turns somewhat to one
-side, and swims forward again. The chances are that it will
-again hit the drop, in which case it repeats the same reaction,
-turning again to one side. If it continues to react in this way,
-it will, in the course of time, turn so far that when it swims
-forward it will miss the edge of the drop, and then continue
-<span class='pageno' id='Page_397'>397</span>on its way. If an individual were put into an alkaline drop,
-it would leave it, because it would not react when it passed
-from inside the drop into the surrounding water.</p>
-
-<p class='c010'>Unicellular animals react to other things besides differences
-in the chemical composition of different parts of a solution.
-In many cases they react to light, swimming toward or away
-from it according to whether they are positively or negatively
-heliotropic. If they are positively heliotropic, and while
-swimming run into a shadow, they react as they would on
-coming into contact with a drop of acid. Since they rotate as
-they swim forward, we cannot explain their orientation as in
-the case of other animals that hold a fixed vertical position.
-If we assume that the two ends of the body are differently
-affected by the light, for which there is some evidence, we
-can perhaps in this way account for their turning toward, or
-away from, the source of light.</p>
-
-<p class='c010'>Changes in the osmotic pressure of the different parts of
-the fluid, mechanical stimulation produced by jarring, extremes
-of heat and of cold, all cause this same characteristic
-reaction in Paramœcium; and this accounts for their behavior
-toward these agents that are so different in other
-respects.</p>
-
-<p class='c010'>Paramœcia, as well as other protozoans, show a contact
-response. They fix themselves to certain kinds of solid
-bodies. If, for example, a small bit of bacterial slime is put
-into the water, the paramœcia collect around it in crowds,
-and eat the bacteria; but they will collect in the same way
-around almost any solid. On coming in contact with bodies
-having a certain physical texture, the cilia covering the paramœcium
-stop moving, only those in the oral groove continuing
-to strike backward. The animal comes to rest, pressed
-against the solid body. If one or more paramœcia remain in
-the same place, they set free carbon dioxide, as a result of
-their respiratory processes. There is formed around them a
-region containing more of this acid than does the surrounding
-<span class='pageno' id='Page_398'>398</span>water. If other moving paramœcia swim, by chance,
-into this region, they are caught, and as a result an accumulation
-of individuals will take place. The more that
-collect the larger will the area become, and thus large numbers
-may be ultimately entrapped in a region where there is
-formed a substance that, from analogy with other animals,
-we should expect to be injurious.</p>
-
-<p class='c010'>The question as to how far these responses of the unicellular
-forms are of advantage to them is difficult to decide, for
-while, as in the above case, the response appears to be
-injurious rather than useful, yet under other conditions the
-same response may be eminently advantageous. In other
-cases, as when the paramœcia back away, and then swim forward
-again, only to repeat the process, the act appears to be
-such a stupid way of avoiding an obstacle that the reaction
-hardly appears to us in the light of a very perfect adaptation.
-If we saw a higher animal trying to get around a wall by
-butting its head into it until the end was finally reached, we
-should probably not look upon that animal as well adapted
-for avoiding obstacles.</p>
-
-<p class='c010'>Bacteria, which are generally looked upon as unicellular
-plants, appear, despite the earlier statements to the contrary,
-to react in much the same way as do the protozoans, according
-to the recent work of Rothert, and of Jennings and Crosby.
-The bacteria do not seem to turn toward or away from chemical
-substances, but they collect in regions containing certain
-substances in much the same way as do the protozoans.
-The collecting of bacteria in regions where oxygen is present
-has been known for some time, but it appears from
-more recent results that they are not attracted toward the
-oxygen, but by accidentally swimming into a region containing
-more oxygen they are held there in the same way as is paramœcium
-in a drop of acid. On the other hand bacteria do
-not enter a drop of salt solution, or of acids, or of alkalies.
-They react negatively to all such substances. Some kinds of
-<span class='pageno' id='Page_399'>399</span>bacteria have a flagellum at each end, and swim indifferently
-in either direction. If they meet with something that stimulates
-them, as they move forward, they swim away in the
-opposite direction, and continue to move in the new direction
-until something causes again a reversal of their movement.
-In this respect their mode of reaction seems of greater
-advantage than that followed by paramœcium.</p>
-
-<p class='c010'>Another instinct, that appears to be due to a tropic
-response, is the definite time of day at which some marine
-animals deposit their eggs. The primitive fish, Amphioxus,
-sets free its eggs and sperm only in the late afternoon. A
-jellyfish, Gonionema, also lays its eggs as the light begins
-to grow less in the late afternoon, and in this case it has
-been found that the process can be hastened if the animals
-are placed in the dark some hours before their regular
-time of laying. There is no evidence that this habit is of
-any advantage to the animal. We may imagine, if we like,
-that the early stages may meet with less risk at night, but
-this is not probable, for it is at this time that countless marine
-organisms come to the surface, and it would seem that the
-chance of the eggs being destroyed would then be much
-greater. It is more probable that the response is of no
-immediate advantage to the animals that exhibit it, although
-in particular cases it may happen to be so.</p>
-
-<p class='c010'>This response recalls the diurnal opening and closing of
-certain flowers. The flowers of the night-blooming cereus
-open only in the dusk of evening, and then emit their strong
-fragrance. Other flowers open only in the daytime, and
-some only in bright sunlight. It is sometimes pointed out
-that it is of advantage to some of these flowers to open at a
-certain time, since the particular insects that are best suited
-to fertilize them may then be abroad. This may often be the
-case, but we cannot but suspect that in other cases it may
-be a matter of little importance. In special instances it may
-be that the time of opening of the flowers is of importance
-<span class='pageno' id='Page_400'>400</span>to the species; but even if this is so, there is no need to
-assume that the response has been gradually acquired for
-this particular purpose. If it were characteristic of a new
-form to open at a particular time, and there were insects in
-search of food at this time that would be likely to fertilize
-the plant, then the plant would be capable of existing; but
-this is quite different from supposing that the plant developed
-this particular response, because this was the most
-advantageous time of day for the fertilization of its flowers.</p>
-
-<p class='c010'>We can apply this same point of view, I believe, to many
-of the remarkable series of tropisms shown by plants, whose
-whole existence in some cases is closely connected with
-definite reactions to their environment. Let us examine
-some of these cases.</p>
-
-<p class='c010'>When a seed germinates, the young stem is negatively
-geotropic, and, in consequence, as it elongates it turns upward
-towards the light that is necessary for its later growth.
-The root, on the contrary, is positively geotropic, and, in
-consequence, it is carried downward in the ground. Both
-responses are in this case of the highest importance to the
-seedling, for in this way its principal organs are carried into
-that environment to which they are especially adapted. It
-matters very little how the seed lies in the ground, since the
-stem when it emerges will grow upward and the root downward.
-The young stem, when it emerges from the soil, will
-turn toward the light if the illumination comes from one
-side, and this also may often be of advantage to the plant,
-since it turns toward the source from which it gets its
-energy. The leaves also turn their broad surfaces toward
-the light, and as a result they are able to make use of a
-greater amount of the energy of the sunlight. The turning is
-due to one side of the stem growing more slowly than the
-opposite side, and it is true, in general, that plants grow
-faster at night than in the daylight. Very bright light will
-in some cases actually stop all growth for a time. Thus we
-<span class='pageno' id='Page_401'>401</span>see that this bending of the stem toward the light and the
-turning of the leaves to face the light are only parts of the
-general relation of the whole plant toward the light.</p>
-
-<p class='c010'>Negative heliotropism is much less frequent in plants. It
-has been observed in aërial roots, in many roots that are ordinarily
-buried in the ground, in anchoring tendrils that serve
-as holdfasts, and even in the stems of certain climbers. In
-all of these cases, and more especially in the case of the
-climbers, the reaction is obviously of advantage to the plant;
-and it is significant to find, in plants that climb by tendrils
-carrying adhering disks, that there is a reversal of the ordinary
-heliotropism shown by homologous organs in other
-plants. There is an obvious adaptation in the behavior of
-the tendril, since its growth away from the more illuminated
-side is just the sort of reaction that is likely to bring it into
-contact with a solid body.</p>
-
-<p class='c010'>In this connection it is important to observe that these
-reactions to light are perfectly definite, being either positive
-or negative under given conditions, and therefore there is at
-present nothing to indicate that there has been a gradual
-transformation from positive to negative, or <i>vice versa</i>. It
-seems to me much more probable that when the structural
-change took place, that converted the plant into a climber,
-there appeared a new heliotropic response associated with the
-other change. In other words, both appeared together in the
-new organ, and neither was gradually acquired by picking
-out fluctuating variations.</p>
-
-<p class='c010'>The leaves of plants also show a sort of transverse heliotropic
-response. It has been found, for example, that the leaves of
-Malva will turn completely over if illuminated by a mirror
-from below. A curious case of change of heliotropism is found
-in the flower stalks of Linaria. They are at first positively
-heliotropic, but after the flower has been fertilized the stalk becomes
-negatively heliotropic. As the stalks continue to grow
-longer, they push the fruits into the crevices of the rocks on
-<span class='pageno' id='Page_402'>402</span>which the plants grow, and in this way insure the lodgement
-of the seeds. Here we have an excellent example showing
-that the negative heliotropism of the flower stalk could
-scarcely have been acquired by slight changes in the final
-direction, for only the complete change is useful to the plant.
-Intermediate steps would have no special value.</p>
-
-<p class='c010'>As has been pointed out in the case of the seedling plant,
-the main stem responds positively and the roots negatively
-to gravity. In addition to this, the lateral position taken by
-the lateral roots and branches and by underground stems are
-also, in part, due to a geotropic response. In this case also
-the effect is produced by the increased growth on the upper
-side when the response is positive, and on the lower when it
-is negative. Leaves also assume a transverse position in
-response to the action of gravity, or at least they make a
-definite angle with the direction of its action.</p>
-
-<p class='c010'>The most striking case of geotropic response is seen in
-plants that climb up the stems of other plants. The twining
-around the support is the result of a geotropic response of
-the sides of the stem. The young seedling plant stands at
-first erect. As its end grows it begins to curve to one side
-in an oblique position, and this is due to an increase in growth
-on one side of the apex of the shoot. As a result the stem
-bends toward the other side. Not only does the end “sweep
-round in a circle like the hands of a watch,” but it rotates on
-its long axis as it revolves. As a result of this rotation “the
-part of the stem subjected to the action of the lateral geotropism
-is constantly changing; and the revolving movement
-once begun, must continue, as no position of equilibrium can
-be attained.” This movement will carry the end around any
-support, not too thick, that the stem touches.</p>
-
-<p class='c010'>Most climbers turn to the left, <i>i.e.</i> against the hands of a
-watch, others are dextral, and a few climb either way.<a id='r32' /><a href='#f32' class='c017'><sup>[32]</sup></a>
-<span class='pageno' id='Page_403'>403</span>Strasburger states that whenever any external force, or substance,
-is important to the vital activity of the plant or any
-of its organs, there will also be found to be developed a corresponding
-irritability to their influence. Roots in dry soil
-are diverted to more favorable positions by the presence of
-greater quantities of moisture. This may, I venture to suggest,
-be putting the cart before the horse. The plant may
-be only able to exist whose responses are suited to certain
-external conditions, and these determine the limits of distribution
-of the plant or the places in which it is found.</p>
-
-<div class='footnote c018' id='f32'>
-<p class='c019'><span class='label'><a href='#r32'>32</a>.&nbsp;&nbsp;</span>These cases recall the spiral growth of the shell of the snail, but the spiral
-in the latter is due to some other factor.</p>
-</div>
-
-<p class='c010'>A number of plants climb in a different way, and show
-another sort of tropism. Those that climb by means of tendrils
-twist their tendrils about any support that they happen
-to come in contact with, and thus the plant is able to lift its
-weak stem, step by step, into the air. The twining of the
-tendrils is due to contact, which causes a cessation of growth
-at the points of contact. The growth of the opposite side
-continues, and thus the tendril bends about its support. In
-the grape and in ampelopsis the tendril is a modified branch.
-The stalk of the leaves in a few plants, as in Lophospermum,
-act as tendrils. Other climbers are able to ascend vertical
-walls owing to the presence of disks, whose secretions hold
-the tendril firmly against the support, as in ampelopsis.</p>
-
-<p class='c010'>It is interesting to find in practically all these cases that,
-whatever the stimulus may be, the results are reached in the
-same way, namely, by one part growing faster than another.
-The fact of importance in this connection is that the plant is
-so constructed that the response is often beneficial to the
-organism.</p>
-
-<p class='c010'>Before leaving this subject there is one set of responses to
-be referred to that is not the result of growth. Certain movements
-are brought about by the change in the turgidity of
-certain organs. The small lateral leaflets of <i>Desmodium
-gyrans</i> make circling movements in one to three minutes.
-No apparent benefit results from their action. The terminal
-<span class='pageno' id='Page_404'>404</span>leaflets of <i>Trifolium pratense</i> oscillate in periods of two to four
-hours, but do so only in the dark; in the light the leaflets
-assume a rigid position. There is nothing in the process to
-suggest that the movement is useful to the plant, and yet it
-appears to be as definite as are those cases in which the
-response is of vital importance. Had these movements been
-of use, their origin would, no doubt, have been explained because
-of their usefulness, and the conclusion would have been
-wrong.</p>
-
-<p class='c010'>The leaves of the Mimosa respond, when touched, and it
-cannot be supposed that this is of any great advantage to the
-plant. The sleep movements of many plants are also due to
-the effect of light. In some cases the leaflets are brought together
-with their upper surfaces in contact with one another;
-in other cases the lower surfaces are brought together. Darwin
-supposed that these sleep movements served to protect
-the leaves from a too rapid loss of heat through radiation, but
-it has been pointed out that tropical plants exhibit the same
-responses. We have here another admirable instance of the
-danger of concluding that because we can imagine an advantage
-of a certain change, that the change has, therefore, been
-acquired because of the advantage. In the Mimosa not only
-do the leaflets close together, but the whole leaf drops down
-if the stimulus is strong. Other plants also show in a less
-degree the same movements, Robinia and Oxalis for instance,
-and certainly in these latter the result does not appear to be
-of any advantage to the plants.</p>
-
-<p class='c010'>The preceding account of some of the tropisms in animals
-and plants will serve to give an idea of how certain movements
-are direct responses to the environment. Some of
-the reactions appear to be necessary for the life of the
-individual, others seem to be of less importance, and a few
-of no use at all. Yet the latter appear to be as definite
-and well-marked as are the useful responses. I think the
-conviction will impress itself on any one who examines
-<span class='pageno' id='Page_405'>405</span>critically the facts, that we are not warranted in applying
-one explanation to those responses that are of use, and
-another to those that are of little or of no value. Inasmuch
-as the Darwinian theory fails to account for the origin of
-organs of little or of no value, it is doubtful if it is needed to
-explain the origin of the useful responses. If, on the other
-hand, we assume that the <i>origin</i> of the responses has nothing
-to do with their value to the organism, we meet with no difficulty
-in those cases in which the response is of little or of
-no use to the organism. That great numbers of responses
-are of benefit to the organism that exhibits them can be
-accounted for on the grounds that those new species, that
-have appeared, that have useful responses, are more likely,
-in the long run, to survive, than are those that do not respond
-adaptively.</p>
-
-<p class='c010'>We may now examine some of the more complicated
-responses and instincts, more especially those of the higher
-animals. Some of these are pure tropisms, <i>i.e.</i> definite responses
-or reactions to an external exciting agent; others may
-be, in part, the result of individual experience, involving
-memory; others, combinations of the two; and still others
-may depend on a more complex reaction in the central nervous
-system of the animal. These cases can be best understood
-by means of a few illustrations.</p>
-
-<p class='c010'>As an example of a simple action may be cited a well-known
-reflex after cutting the nerve-cord of the frog, or
-after destroying the brain. If the frog is held up, and its
-side tickled, the leg is drawn up to rub the place touched.
-To accomplish this requires a beautifully adjusted system
-of movements, yet the act seems to be a direct reflex, involving
-only the spinal cord.</p>
-
-<p class='c010'>An example of a somewhat more complex reflex is the
-biting off of the navel-string by the mother in rodents
-and other mammals; an act eminently useful to the young
-animal, although of no importance to the mother herself.
-<span class='pageno' id='Page_406'>406</span>The protection of the young by their parents from the
-attacks of other animals appears to be a somewhat complex
-instinct, and it is interesting to note that the protection
-is extended to the young only so long as they are in need
-of it, and as soon as they are able to shift for themselves
-the maternal protection is withdrawn.</p>
-
-<p class='c010'>The instinct of the young chick to seize in its beak any
-small moving object is a simple and useful reflex action, but if
-the object should happen to be a bee which stings the chick,
-another bee or similar insect will not be seized. Here we see
-that a reflex has been changed, and changed with amazing
-quickness. Moreover, the chick has learnt to associate this
-experience with a particular sort of moving object. It is this
-power to benefit by the result of a brief experience that is one
-of the most advantageous properties of the organism.</p>
-
-<p class='c010'>Young chicks first show a drinking reflex if by chance
-their beaks are wet by water. At once the head is lifted
-up, and the drop of water passes down the throat. In this
-way the chick first learns the meaning of water, and no doubt
-soon comes to associate it with its own condition of thirst.
-The sight of water produces no effect on the inexperienced
-chick, and it may even stand with its feet in the water without
-drinking; but as soon as it touches, by chance, the water
-with its beak, the reflex, or rather the set of reflexes is
-started.</p>
-
-<p class='c010'>A more complicated instinct is that shown by the spider
-in making its web. In some cases the young are born from
-eggs laid in the preceding summer, and can have had, therefore,
-no experience of what a web is like; and yet, when they
-come to build this wonderfully complex structure, they do so
-in a manner that is strictly characteristic of the species.</p>
-
-<p class='c010'>The formation of the comb by bees, in which process,
-with a minimum of wax, they secure a maximum number of
-small storehouses in which to keep their honey and rear their
-young, is often cited as a remarkable case of adaptation.</p>
-
-<p class='c010'><span class='pageno' id='Page_407'>407</span>There has been some discussion as to whether birds build
-their nests in imitation of the nest in which they were reared,
-or whether they do so independently of any such experience.
-There can be no doubt, however, that in some birds neither
-memory nor imitation can play any important part in the
-result, and that they build their nests as instinctively as spiders
-make webs.</p>
-
-<p class='c010'>These instincts of spiders, bees, and birds appear to be
-more complex than the reflexes and tropisms that were first
-described. Whether they are really so, or only combinations
-of simple responses, we do not yet know. That they
-have come suddenly into existence as we now find them
-does not seem probable, but this does not mean that they
-must have been slowly acquired as the result of selection.
-The mutation theory also assumes that the steps of advance
-may have been small.</p>
-
-<p class='c010'>Our account may be concluded with the recital of some
-instincts, chosen almost at random, that serve to show some
-other adaptations which are the result of these inborn
-responses.</p>
-
-<p class='c010'>It is known that ants travel long distances from their nests,
-and yet return with unerring accuracy. It has been shown
-that they are able to do this through a marvellous sense of
-smell. The track left by the ant, as it leaves the nest, serves
-as a trail in returning to the starting-point. Moreover, it
-appears that the ant can pick out her own trail, even when
-it has been crossed by that of other ants. This means that
-she can distinguish the odor of her own trail from that of
-other members of the colony. The sense-organs by means
-of which the odor is detected lie in the antennæ. This fact
-accounts for certain actions of ants that have been described
-as showing that they have an affection for each other. Two
-ants, meeting, pat each other with their antennæ. In this
-way they are quickly able to distinguish members of their
-own nest from those of other nests. If they are of the same
-<span class='pageno' id='Page_408'>408</span>nest, they separate quietly; if of other nests, they may fight.
-If an ant from one nest is put into another nest, it is instantly
-attacked and killed—an act that appears to be injurious
-rather than useful, for the ant might become a valuable member
-of the new colony. If, however, an ant is first immersed
-in the blood of a member of the community into which she
-is to be introduced, she will not be attacked, and may soon
-become a part of the new community. By her baptism of
-blood she has no doubt acquired temporarily the odor of the
-new nest, and by the time that this has worn off she will
-have acquired this odor by association, and become thereby a
-member of another colony.</p>
-
-<p class='c010'>Numerous stories have been related of cases in which an
-ant, having found food, returns to the nest with as much of
-it as she can carry, and when she comes out again brings with
-her a number of other ants. This has been interpreted to
-mean that in some mysterious way the ant communicates her
-discovery to her fellow-ants. A simpler explanation is probably
-more correct. The odor of the food, or of the trail,
-serves as a stimulus to other ants, that follow to the place
-where the first ant goes for a new supply of the food. The
-fact that the first individual returns to the supply of food
-seems to indicate that the ant has memory, and this is obviously
-of advantage to her and to the whole colony.</p>
-
-<p class='c010'>The peculiar habits of some of the solitary wasps, of stinging
-the caterpillar or other insect which they store up as
-food for their young, is often quoted as a wonderful case
-of adaptive instinct. The poison that is injected into the
-wound paralyzes the caterpillar, but as a rule does not kill it,
-so that it remains motionless, but in a fresh state to serve
-as food for the young that hatch from the egg of the wasp.
-A careful study of this instinct by Mr. and Mrs. Peckham
-has shown convincingly that the act is not carried out with the
-precision formerly supposed. It had been claimed that the
-sting is thrust into the caterpillar on the lower side, a ventral
-<span class='pageno' id='Page_409'>409</span>ganglion being pierced, the poison acting with almost instantaneous
-effect. But it may be questioned whether this is
-really necessary, and whether the same end might not be
-gained, although not quite so instantaneously, if the caterpillar
-were pierced in almost any other part of the body. Can
-we be seriously asked to believe that this instinct has been
-perfected by the destruction of those individuals (or of their
-descendants) that have not pierced the caterpillar in exactly
-the middle of a segment of the anterior ventral surface? It
-seems to me that the argument proves too much from the
-selectionist’s point of view. If the wasp pierced the caterpillar
-in the middle of its back, we should have passed over
-the act without comment; but since the injection is usually
-made on the ventral side, and since we know that the nervous
-system lies in this position, it has been assumed that the
-act is carried out in this way, in order that the poison may
-penetrate the nervous system more quickly. Yet a fuller
-knowledge may show that there is really no necessity for
-such precision.</p>
-
-<p class='c010'>A curious response is the so-called death-feigning instinct
-shown by a number of animals, especially by certain insects,
-but even by some mammals and birds. Certain insects, if
-touched, draw in their legs, let go their hold, and fall to the
-ground, if they happen to be on a plant. It is not unusual
-to meet with the statement that this habit has been acquired
-because it is useful to the insect, since it may often escape in
-this way from an enemy. This does not appear on closer
-examination to be always the case, and sometimes as much
-harm as good may result, or what is more probable, neither
-much advantage, nor disadvantage, is the outcome. This can,
-of course, only be determined in each particular case from a
-knowledge of the whole life of a species and of the enemies
-that are likely to injure it.</p>
-
-<p class='c010'>Hudson has recorded<a id='r33' /><a href='#f33' class='c017'><sup>[33]</sup></a> a number of cases of this death-feigning
-<span class='pageno' id='Page_410'>410</span>instinct in higher animals, and attributes it to violent
-emotion, or fear, that produces a sort of swoon. He describes
-the gaucho boys’ method, in La Plata, of catching the silver-bill
-by throwing a stick or a stone at it, and then rushing
-toward the bird, “when it sits perfectly still, disabled by
-fear, and allows itself to be taken.” He also states that one
-of the foxes (<i>Canis azaræ</i>) and one of the opossums (<i>Didelphys
-azaræ</i>) “are strangely subject to the death-simulating swoon.”</p>
-
-<div class='footnote c018' id='f33'>
-<p class='c019'><span class='label'><a href='#r33'>33</a>.&nbsp;&nbsp;</span>“The Naturalist in La Plata.”</p>
-</div>
-
-<p class='c010'>Hudson remarks that it seems strange that animals so
-well prepared to defend themselves should possess this “safeguard.”
-When caught or run down by dogs, the fox fights
-savagely at first, but after a time its efforts stop, it relaxes,
-and it drops to the ground. The animal appears dead, and
-Hudson states that the dogs are “constantly taken in by it.”
-He has seen the gauchos try the most barbarous tricks on a
-captive fox in this condition, and, despite the mutilations to
-which it was subjected, it did not wince. If, however, the
-observer draws a little away from the animal, “a slight opening
-of the eye may be detected, and finally, when left to
-himself, he does not recover and start up like an animal that
-has been stunned, but cautiously raises his head at first and
-only gets up when his foes are at a safe distance.” Hudson,
-coming once suddenly upon a young fox, saw it swoon at his
-approach, and although it was lashed with a whip it did not
-move.</p>
-
-<p class='c010'>The common partridge of the pampas of La Plata (<i>Hothura
-maculosa</i>) shows this death-feigning instinct in a very marked
-degree. “When captured, after a few violent struggles to
-escape, it drops its head, gasps two or three times, and to all
-appearance dies.” But if it is released it is off in an instant.
-The animal is excessively timid, and if frightened, may actually
-die simply from terror. If they are chased, and can find no
-thicket or burrow into which to escape, “they actually drop
-down dead on the plain. Probably when they feign death in
-their captor’s hand they are in reality very near to death.”</p>
-
-<p class='c010'><span class='pageno' id='Page_411'>411</span>In this latter instance it must appear very improbable that
-we are dealing with an instinct that has been built up by
-slow degrees on account of the benefit accruing at each stage
-to the individual. In fact, it appears that the instinct is in
-this case of really no use at all to the animal, for there can
-scarcely be any question of an escape by this action. Yet so
-far as we can judge it is the same instinct shown by other
-animals, and it is not logical to account for its origin in one
-case on the grounds of its usefulness, when we cannot apply
-the explanation in the other cases. If this be admitted, we
-have another illustration of the importance of keeping apart
-the origin of an instinct or of a structure and the fact of its
-usefulness or non-usefulness to the organism. Thus under
-certain conditions this death-feigning instinct might really
-be of use to the animal, while under other conditions and in
-other animals it may be of no advantage at all, and in still
-other conditions it may be a positive injury to its possessor.
-Perhaps we need not go outside of our own experience to find
-a parallel case, for the state of fright into which imminent
-danger may throw an individual may deprive him for the
-moment of the proper use of those very mental qualities of
-which he stands in this crisis in greatest need.</p>
-
-<p class='c010'>The peculiar behavior of cattle caused by the smell of blood
-is another case of an instinct whose usefulness to its possessors
-is far from apparent. It is known that cattle and horses
-and several wild animals become violently excited by the
-smell of blood. Hudson gives a vivid account of a scene
-witnessed by himself, the animals congregating, “and moving
-around in a dense mass, bellowing continually.” Those animals
-that forced their way into the centre of the mass where
-the blood was “pawed the earth and dug it up with their
-horns, and trampled each other down in their frantic excitement.”</p>
-
-<p class='c010'>This action leads us to a consideration of the behavior
-of animals toward companions in distress. “Herbivorous
-<span class='pageno' id='Page_412'>412</span>animals at such times will trample and gore the distressed
-one to death. In the case of wolves and other savage-tempered
-carnivorous species the distressed fellow is frequently
-torn to pieces and devoured on the spot.” If any
-one will be bold enough to claim in this case that this habit
-has been acquired because of advantage to the pack, <i>i.e.</i>
-if it be imagined that the pack gains more by feeding on
-a weak member than by letting him take his chances of
-recovery, it may be pointed out in reply that cattle also
-destroy their weak or injured, but do not devour them, and
-the same statement holds for birds, where the same instinct
-has often been observed. Romanes has suggested that the
-instinct of destroying the weak or injured members is of use
-because such members are a source of danger to the rest of the
-herd; but Hudson points out that it is not so much the weak
-and sickly members of the herd that are attacked in this
-way, as those that are injured, and concludes, “the instinct
-is not only useless, but actually detrimental.” He suggests
-that these “wild abnormal movements of social animals” are
-a sort of aberration, so “that in turning against a distressed
-fellow they oppose themselves to the law of being.” Yet
-whether we gain anything by calling this action aberrant or
-abnormal, the important fact remains that it is a definite
-response under certain external conditions, and is shown by
-all the individuals of the species.</p>
-
-<p class='c010'>The preceding illustrations of reactions that go to make
-up the so-called instincts of animals may be separated into
-those that are essential to the life of the individual or of the
-race, those that are of some apparent use, although not
-absolutely essential, and a few of no use at all, and fewer
-still that appear to be even injurious. If the latter reactions
-take place only rarely, as appears often to be the case,
-they are not sufficiently harmful to cause the destruction of
-the race. The evidence points to the conclusion, I believe,
-that the origin of these tropisms and instincts cannot be
-<span class='pageno' id='Page_413'>413</span>accounted for on the ground of their benefit to the individual
-or to the race; and it does not seem reasonable to
-make up one explanation for the origin of those that are
-essential, and another for those that are of little use or even
-of no use at all.</p>
-
-<p class='c010'>From what has been already said more than once, while
-discussing each particular case, the simplest course appears
-to be in all instances to look upon these instincts as having
-appeared independently of the use to which they may be
-put, and not as having been built up by selection of the
-individual variations that happen to give an organism some
-advantage over its fellows in a life and death struggle. It
-appears reasonable to deal with the origin of tropisms and
-instincts in general in the same way as in dealing with
-structures; for, after all, the tropism is only the outcome
-of some material or structural basis in the organism.</p>
-
-<p class='c010'>No attempt has been made here to interpret the more complex
-reactions of the nervous system, for until we can get
-some insight into the meaning of the simpler processes, we
-are on safer ground in dealing with these first.</p>
-
-<div class='pbb'>
- <hr class='pb c006' />
-</div>
-<div class='chapter'>
-  <span class='pageno' id='Page_414'>414</span>
-  <h2 class='c008'>CHAPTER XII<br /> <br /><span class='c013'>SEX AS AN ADAPTATION</span></h2>
-</div>
-<p class='c009'><span class='sc'>In</span> what sense may the separation of all the individuals of
-a species into two kinds of individuals, male and female, be
-called an adaptation? Does any advantage result to the species
-that would not come from a non-sexual method of reproduction?
-Many attempts have been made to answer these questions,
-but with what success I shall now try to show.</p>
-
-<p class='c010'>There are four principal questions that must be considered:—</p>
-
-<p class='c010'>I. The different kinds of sexual individuals in the animal
-and plant kingdoms.</p>
-
-<p class='c010'>II. The historical question as to the evolution of separate
-sexes.</p>
-
-<p class='c010'>III. The factors that determine the sex in each individual
-developing from an egg.</p>
-
-<p class='c010'>IV. The question as to whether any advantage is gained
-by having each new individual produced by the union of two
-germ-cells, or by having the germ-cells carried by two kinds
-of individuals.</p>
-
-<p class='c010'>While our main problem is concerned with the last of these
-topics, yet there would be little hope of giving a complete answer
-to it unless we could get some answer to the first three
-questions.</p>
-<h3 class='c014'><span class='sc'>The Different Kinds of Sexual Individuals</span></h3>
-
-<p class='c015'>Amongst the unicellular animals and plants the fusion of
-two (or more) individuals into a single one is generally regarded
-as the simplest, and possibly also the most primitive,
-<span class='pageno' id='Page_415'>415</span>method of sexual reproduction. Two amœbas, or amœba-like
-bodies, thus flow together, as it were, to produce a new
-individual.</p>
-
-<p class='c010'>In the more highly specialized unicellular animals, the
-processes are different. Thus in vorticella, a small, active
-individual unites with a larger fixed individual. The protoplasm
-fuses into a common mass, and a very complicated
-series of changes is passed through by the nucleus. In
-paramœcium, a free-swimming form very much like vorticella,
-two individuals that are alike unite only temporarily,
-and after an interchange of nuclear material they separate.</p>
-
-<p class='c010'>In the lower plants, and more especially in some of the
-simple aggregates or colonial forms, there are found a number
-of stages between species in which the uniting individuals
-are alike, and those in which they are different. There are
-several species whose individuals appear to be exactly alike;
-and other species in which the only apparent difference
-between the individuals that fuse together is one of size;
-and still other species in which there are larger resting or
-passive individuals, and smaller active individuals that unite
-with the larger ones. In several of the higher groups, including
-the green algæ and seaweeds, we find similar series,
-which give evidence of having arisen independently of each
-other. If we are really justified in arranging the members
-of these groups in series, beginning with the simpler cases
-and ending with those showing a complete differentiation
-into two kinds of germ-cells, we seem to get some light as to
-the way in which the change has come about. It should not
-be forgotten, however, that it does not follow because we can
-arrange such a series without any large gaps in its continuity,
-that the more complex conditions have been gradually
-formed in exactly this way from the simplest conditions.</p>
-
-<p class='c010'>So far we have spoken mainly of those cases in which the
-forms are unicellular, or of many-celled species in which all
-the cells of the individual resolve themselves into one or the
-<span class='pageno' id='Page_416'>416</span>other kind of germ-cells. This occurs, however, only in the
-lowest forms. A step higher we find that only a part of the
-cells of the colony are set aside for purposes of reproduction.
-The cells surrounding these germ-cells may form distinct
-organs, which may show certain differences according to
-whether they contain male or female germ-cells. When
-these two kinds of cells are produced by two separate individuals,
-the individuals themselves may be different in other
-parts of the body, as well as in the reproductive organs.</p>
-
-<p class='c010'>When this condition is reached, we have individuals that
-we call males and females, because, although they do not
-themselves unite to form new individuals, they produce one
-or the other kind of germ-cell. It is the germ-cells alone
-that now combine to form the new individual.</p>
-
-<p class='c010'>Amongst living groups of animals we find no such complete
-series of forms as exist in plants, and the transition from the
-one-celled to the many-celled forms is also more abrupt. On
-the other hand, we find an astonishing variety of ways in
-which the reproduction is accomplished, and several ways in
-which the germ-cells are carried by the sexual individuals.
-Let us examine some of the more typical conditions under
-the following headings: (1) sexes separate; (2) sexes united
-in the same individual; (3) parthenogenetic forms; (4) exceptional
-methods of propagation.</p>
-
-<p class='c010'>1. <i>Sexes Separate; Unisexual Forms.</i><a id='r34' /><a href='#f34' class='c017'><sup>[34]</sup></a>—Although the animals
-with which we are more familiar have the sexes separate,
-this is far from being universal amongst animals and
-plants; and, in fact, can scarcely be said to be even the rule.
-When the sexes are separate they may be externally alike,
-and this is especially true for those species that do not unite,
-but set free their eggs and spermatozoa in the water, as fish,
-frogs, corals, starfish, jellyfish, and many other forms. In
-other animals there are sometimes other secondary differences
-<span class='pageno' id='Page_417'>417</span>in the sexes besides those connected with the organs
-of reproduction. Such differences are found, as we have
-seen, in insects, in some spiders, crustaceans, and in many
-birds and mammals. In a few cases the difference between
-the sexes is very great, especially when the female is parasitic
-and the male free, as in some of the crustaceans. In
-some other cases the male is parasitic on the female. Thus
-in Bonellia the male is microscopic in size, being in length
-only one-hundredth part of the female. In <i>Hydatina senta</i>
-the male is only about a third as large as the female. It has
-no digestive tract, and lives only a few days. In another
-rotifer the males are mere sacs enclosing the male reproductive
-organs.</p>
-
-<div class='footnote c018' id='f34'>
-<p class='c019'><span class='label'><a href='#r34'>34</a>.&nbsp;&nbsp;</span>Geddes and Thompson’s “The Evolution of Sex” has been freely used in the
-preparation of this part of this chapter.</p>
-</div>
-
-<p class='c010'>2. <i>Hermaphroditic Forms.</i>—There are many species of
-animals and plants in which each individual contains both
-the male and the female organs of reproduction, and there
-are whole groups in which only these hermaphroditic forms
-occur. Thus in the ctenophors the eggs develop along
-one side of each radial canal and spermatozoa along the
-other. The group of flatworms is almost exclusively hermaphroditic.
-The earthworms and the leeches have only
-these bisexual forms, and in the mollusks, while a few groups
-have separate sexes, yet certain groups of gasteropods and
-of bivalve forms are entirely hermaphroditic.</p>
-
-<p class='c010'>In the common garden snail, although there are two sets
-of sexual ducts closely united, yet from the same reproductive
-sac both eggs and sperm are produced. The barnacles
-and the ascidians are for the most part hermaphroditic forms.
-Many other examples might be cited, but these will suffice
-to show that it is by no means unusual in the animal kingdom
-for the same individual to produce both male and female germ-cells.
-However, one of the most striking facts in this connection
-is that self-fertilization seldom takes place, so that the
-result is the same in certain respects as though separate sexes existed.
-This point will come up later for further consideration.</p>
-
-<p class='c010'><span class='pageno' id='Page_418'>418</span>3. <i>Parthenogenetic Reproduction.</i>—It has long been known
-that, in some cases, eggs that are not fertilized will begin
-to develop and may even produce new individuals. Tichomiroff
-showed that by rubbing with a brush the unfertilized
-eggs of the silkworm moth, a larger percentage would
-produce caterpillars than if they were not rubbed. During
-the last few years it has been shown that the development
-of a non-fertilized egg may be started in a number of ways.
-Such, for example, as by certain solutions of salt or of
-sugar, by subjecting the eggs to cold, or by simply shaking
-them.</p>
-
-<p class='c010'>There are certain groups of animals in which the males
-appear only at regular (in others at irregular) intervals. In
-their absence the females produce eggs that develop without
-being fertilized, <i>i.e.</i> parthenogenetically. The following examples
-will serve to show some of the principal ways in which
-this “virgin reproduction” takes place. In the group of
-rotifers the males are generally smaller than the females
-and are usually also degenerate. In some species, although
-degenerate males are present, they are unnecessary, since
-parthenogenesis is the rule. In still other species no males
-exist and the eggs develop, therefore, without being fertilized.
-In some of the lower crustaceans parthenogenesis occurs in
-varying degrees. In Apus males may be entirely absent at
-times in certain localities, and at other times a few, or even
-very many, males may appear. Some species of ostracod
-crustaceans seem to be purely parthenogenetic; others reproduce
-by means of fertilized eggs; and others by an alternation
-of the two processes. The crustaceans of the genus
-<i>Daphnia</i> produce two kinds of eggs. The summer eggs
-are small, and have a thin shell. These eggs develop without
-being fertilized, but in the autumn both male and female
-individuals develop from these unfertilized eggs, and the
-eggs of the female, the so-called winter eggs, are fertilized.
-These are also larger than the summer eggs, have thicker
-<span class='pageno' id='Page_419'>419</span>shells, and are much more resistant to unfavorable conditions.
-They give rise in the following spring to females
-only, and these are the parthenogenetic individuals that continue
-to produce during the summer new parthenogenetic
-eggs.</p>
-
-<p class='c010'>It is within the group of insects that some of the most
-remarkable cases of parthenogenesis that we know are
-found. In the moth, <i>Psyche helix</i>, only females are present,
-as a rule, but rarely males have been found. In another
-moth, <i>Solenobia trinquetrella</i>, the female reproduces by parthenogenesis,
-but at times males appear and may then be
-even more numerous than the females. In the gall-wasps
-parthenogenetic generations may alternate with a sexual
-generation, and it is interesting to note that the sexual and
-the parthenogenetic generations are so different that they
-were supposed to belong to separate species, until it was
-found that they were only alternate generations of the same
-species.</p>
-
-<p class='c010'>The aphids or plant-lice reproduce during the summer
-by parthenogenesis, but in the autumn winged males and
-females appear, and fertilized winter eggs are produced.
-From these eggs there develop, in the following spring, the
-wingless parthenogenetic summer forms, which produce the
-successive generations of the wingless forms. As many
-as fourteen summer broods may be produced. By keeping
-the aphids in a warm temperature and supplying them with
-plenty of moist food, it has been possible to continue the
-parthenogenetic reproduction of the wingless forms for
-years. As many as fifty successive broods have been produced
-in this way. It has not been entirely determined
-whether it is the temperature or a change in the amount,
-or kind, of food that causes the appearance of the winged
-males and females, although it seems fairly certain that
-diminution in the food, or in the amount of water contained
-in it, is the chief cause of the change.</p>
-
-<p class='c010'><span class='pageno' id='Page_420'>420</span>In the honey-bee the remarkable fact has been well established
-that fertilized eggs give rise only to females (queens
-and workers), while unfertilized eggs develop into males.
-Whether a fertilized egg becomes a queen or a worker
-(sterile female) depends solely on the kind of food that is
-given to the young larva, and this is determined, in a sense,
-entirely by the bees themselves.</p>
-
-<p class='c010'>In plants also there are many cases of parthenogenesis
-known. Some species of Chara when kept under certain
-conditions produce only female organs, and seem to produce
-new plants parthenogenetically. In this case it appears
-that the same conditions that caused the plants to produce
-only female organs may also lead to the development
-of the egg-cells without fertilization. In fact it is only by
-a combination of this kind that parthenogenesis could arise.
-The result is similar when the eggs of insects produce only
-females whose eggs are capable of parthenogenetic development.
-If a case should arise in which only females appeared
-whose eggs did not possess the power of parthenogenetic
-development, the species would die out.</p>
-
-<p class='c010'>In the green alga, Spirogyra, it has been found that if
-conjugation of two cells is prevented, a single cell may become
-a parthenogenetic cell. In a number of parasitic fungi
-the male organs appear to be degenerate, and from the
-female organs parthenogenetic development takes place. A
-small number of flowering plants are also capable of parthenogenetic
-reproduction.</p>
-
-<p class='c010'>There is a peculiarity in the development of the parthenogenetic
-eggs of animals that will be more fully discussed later,
-but may be mentioned here. Ordinarily an egg that becomes
-fertilized gives off two polar bodies, but in a number of cases
-in which parthenogenetic development occurs it has been found
-that only one polar body is given off. It is supposed that in
-such cases one polar body is retained, and that it plays the
-same part as the entrance of the spermatozoon of the male.</p>
-
-<p class='c010'><span class='pageno' id='Page_421'>421</span>4. <i>Exceptional Cases.</i>—Occasionally in a species that is unisexual
-an individual is found that is bisexual. The male of
-the toad, <i>Pelobates fuscus</i>, has frequently a rudimentary ovary
-in front of the testis. The same thing has been found in several
-species of fish. In Serranus, a testis is present in the wall
-of the ovary, and the eggs are said to be fertilized by the spermatozoa
-of the same individual. In frogs it has been occasionally
-found that ovary and testis may be associated in the same
-individual, or a testis may be present on one side, and a testis
-with an anterior ovarian portion on the other. Cases like
-these lead up to those in which the body itself may also show
-a mosaic of sex-characters, and it is noticeable that when
-this occurs there is nearly always a change in the reproductive
-organs also. Thus butterflies have been found with the
-wings and the body of one side colored like the male and the
-other side like the female. Similar cases have also been found
-in bees and ants. Bees have been found with the anterior part
-of the body of one sex and posterior part of another!</p>
-
-<p class='c010'>The preceding cases illustrate, in different ways, the fact
-that in the same individual both kinds of reproductive organs
-may suddenly appear, although it is the rule in such species
-that only one set develops. Conversely, there are cases
-known, especially amongst plants, in which individuals, that
-usually produce male and female organs (or more strictly
-spores of two kinds from which these organs develop), produce
-under special conditions only one or the other kind.
-Facts like these have led to the belief that each individual is
-potentially bisexual, but in all unisexual forms one sex
-predominates, and the other remains latent. This idea has
-been the starting-point for nearly all modern theories of sex.</p>
-
-<p class='c010'>An excellent illustration of this theory is found in those
-cases in which the same individual may be male at one time
-and female at another. For instance, it is said that in one of
-the species of starfish (<i>Asterina gibbosa</i>) the individuals at
-Roscoff are males for one or two years, and then become
-<span class='pageno' id='Page_422'>422</span>females. At Banyuls they are males for the first two or three
-years, and then become females; while at Naples some are
-always males, others females, some hermaphrodites, others
-transitional as in the cases just given. In one of the isopod
-crustaceans, <i>Angiostomum</i>, the young individuals are males
-and the older females. In <i>Myzostomum glabrum</i> the young
-animal is at first hermaphroditic, then there is a functional
-male condition, followed by a hermaphroditic condition, and
-finally a functional female phase, during which the male reproductive
-organs disappear.</p>
-
-<p class='c010'>The flowers of most of the flowering plants have both stamens
-and pistils, which contain the two kinds of spores out
-of which the male and female germ-cells are formed. The
-stamens become mature before the pistils, as a rule, but in
-some cases the reverse is the case. This difference in the
-time of ripening of the two organs is often spoken of as an
-adaptation which prevents self-fertilization. The latter is
-supposed to be less advantageous than cross-fertilization.
-This question will be more fully considered later.</p>
-
-<p class='c010'>Before we come to an examination of the question of the
-adaptations involved in the cases in which the sexes are
-separate, and the different times at which the sex-cells are
-ripened, it will be profitable first to examine the question as
-to what determines in the egg or young whether a male or a
-female or a hermaphroditic form shall arise.</p>
-<h3 class='c014'><span class='sc'>The Determination of Sex</span></h3>
-
-<p class='c015'>A large number of views have been advanced as to what
-determines whether an egg will give rise to a male or to a female
-individual. The central question is whether the fertilized egg
-has its sex already determined, or whether it is indifferent;
-and if the latter, what external factor or factors determine
-the sex of the embryo. Let us first examine the view that
-some external factor determines the sex of the individual, and
-<span class='pageno' id='Page_423'>423</span>then the evidence pointing in the opposite direction. Among
-the different causes suggested as determining the sex of the
-embryo, that of the condition of the egg itself at the time of
-fertilization has been imagined to be an important factor in
-the result. Another similar view holds that the condition of
-the spermatozoon plays the same rôle. For instance, it has
-been suggested that if the egg is fertilized soon after it leaves
-the ovary, it produces a female, but if the fertilization is delayed,
-a male is produced. It has also been suggested that
-the relative age of the male and the female parents produces
-an effect in determining the sex of the young. There is
-no satisfactory evidence, however, showing that this is really
-the case.</p>
-
-<p class='c010'>Another view suggested is that the sex is determined by
-the more vigorous parent; but again there is no proof that
-this is the case, and it would be a difficult point to establish,
-since as Geddes and Thompson point out, what is meant by
-greater vigor is capable of many interpretations. Somewhat
-similar is the idea that if the conditions are favorable,
-the embryo develops further, as it were, and becomes a
-male; but there are several facts indicating that this view
-is untenable.</p>
-
-<p class='c010'>Düsing maintains that several of these factors may play a
-part in determining the sex of the embryo, and if this be true,
-the problem becomes a very complex one. He also suggests
-that there are self-regulative influences of such a kind that,
-when one sex becomes less numerous, the conditions imposed
-in consequence on the other sex are such as to bring the
-number back to the normal condition; but this idea is far
-from being established. The fact that in some species there
-are generally more individuals of one sex than of the other
-shows that this balance is not equally adjusted in such forms.</p>
-
-<p class='c010'>Of far greater value than these speculations as to the origin
-of sex are the experiments that appear to show that nutrition
-is an important factor in determining sex. Some of the
-<span class='pageno' id='Page_424'>424</span>earlier experiments in this direction are those of Born and of
-Yung. By feeding one set of tadpoles with beef, Yung found
-the percentage of females that developed to be greatly increased,
-and a similar increase was observed when the tadpoles
-were fed on the flesh of fish. An even greater effect
-was produced by using the flesh of frogs, the percentage
-rising to 92 females in every hundred. These results have
-been given a different interpretation by Pflüger and by
-others, and, as will be pointed out later, there is a possible
-source of error that may invalidate them.</p>
-
-<p class='c010'>Somewhat similar results have been obtained by Nussbaum
-for one of the rotifers. He found that if the rotifer is abundantly
-fed in early life, it produces <i>female eggs</i>, that is, larger
-eggs that become females; while if sparingly fed, it produces
-only small eggs, from which males develop. It has been
-claimed also in mammals, and even in man, that sex is to
-some extent determined by the nourishment of the individual.</p>
-
-<p class='c010'>Some experiments made by Mrs. Treat with caterpillars
-seemed to show that if the caterpillars were well nourished
-more female moths were produced, and if starved before
-pupation more males emerged. But Riley has pointed out
-that since the larger female caterpillars require more food
-they will starve sooner than the males, and, in consequence,
-it may appear that proportionately more male butterflies are
-born when the caterpillars are subjected to a starvation diet.
-This point of view is important in putting us on our guard
-against hastily supposing that food may directly determine
-sex. Unless the entire number of individuals present at the
-beginning of the experiment is taken into account, the results
-may be misleading, because the conditions may be more fatal
-to one sex than to the other.</p>
-
-<p class='c010'>In some of the hymenopterous insects, the bees for example,
-it has been discovered that the sex of the embryo is determined
-by the entrance, or lack of entrance, of the spermatozoon.
-In the honey-bee all the fertilized eggs produce
-<span class='pageno' id='Page_425'>425</span>females and the unfertilized eggs males. The same relation
-is probably true also in the case of ants and of wasps.
-In the saw-flies, the conditions are very remarkable. Sharp
-gives the following account of some of these forms:<a id='r35' /><a href='#f35' class='c017'><sup>[35]</sup></a>—“It
-is a rule in this family that males are very much less numerous
-than females, and there are some species in which no
-males have been discovered. This would not be of itself
-evidence of the occurrence of parthenogenesis, but this has
-been placed beyond doubt by taking females bred in confinement,
-obtaining unfertilized eggs from them, and rearing the
-larvæ produced from the eggs. This has been done by numerous
-observers with curious results. In many cases the
-parthenogenetic progeny, or a portion of it, dies without
-attaining full maturity. This may or may not be due to constitutional
-weakness, arising from the parthenogenetic state.
-Cameron, who has made extensive observations on this subject,
-thinks that the parthenogenesis does involve constitutional
-weakness, fewer of the parthenogenetic young reaching
-maturity. This, he suggests, may be compensated for—when
-the parthenogenetic progeny is all of the female sex—by
-the fact that all those that grow up are producers of eggs.
-In many cases the parthenogenetic young of Tenthredinidæ
-are of the male sex, and sometimes the abnormal progeny is
-of both sexes. In the case of one species—the common
-currant-fly, <i>Nematus ribesii</i>—the parthenogenetic progeny
-is nearly, but not quite always, entirely of the male sex; this
-has been ascertained again and again, and it is impossible to
-suggest in these cases any advantage to the species to compensate
-for constitutional parthenogenetic weakness. On the
-whole, it appears most probable that the parthenogenesis, and
-the special sex produced by it, whether male or female, are
-due to physiological conditions of which we know little, and
-that the species continues in spite of the parthenogenesis
-rather than profits by it. It is worthy of remark that one of
-<span class='pageno' id='Page_426'>426</span>the species in which parthenogenesis with the production of
-males occurs—<i>Nematus ribesii</i>—is perhaps the most abundant
-of saw-flies.”</p>
-
-<div class='footnote c018' id='f35'>
-<p class='c019'><span class='label'><a href='#r35'>35</a>.&nbsp;&nbsp;</span>“The Cambridge Natural History,” Vol. V, “Insects,” by David Sharp.</p>
-</div>
-
-<p class='c010'>It has been pointed out that in a number of species of
-animals and plants only parthenogenetic females are present
-at certain times. In a sense this means a preponderance of
-one sex, but since the eggs are adapted only to this kind of
-development, it may be claimed that the conditions in such
-cases are somewhat different from those in which eggs that
-would be normally fertilized may develop in the absence of
-fertilization. Nevertheless, it is generally supposed that the
-actual state of affairs is about the same. It is usually assumed,
-and no doubt with much probability, that these
-parthenogenetic forms have evolved from a group which
-originally had both male and female forms. One of the most
-striking facts in this connection is that in the groups to which
-these parthenogenetic species belong there are, as a rule,
-other species with occasional parthenogenesis, and in some of
-these the males are also fewer in number than the females.</p>
-
-<p class='c010'>In the aphids, the parthenogenetic eggs give rise during
-the summer to parthenogenetic females, but in the autumn
-the parthenogenetic eggs give rise without fertilization both
-to males and to females. It appears, therefore, that we can
-form no general rule as to a relation between fertilization
-and the determination of sex. While in certain cases, as in
-the bees, there appears to be a direct connection between
-these two, in other cases, as in that of the aphids just mentioned,
-there is no such relation apparent.</p>
-
-<p class='c010'>Geddes and Thompson have advocated a view in regard to
-sex which at best can only serve as a sort of analogy under
-which the two forms of sex may be considered, rather than
-as a legitimate explanation of the phenomenon of sex. They
-rest their view on the idea that living material is continually
-breaking down and building up. An animal in which there
-is an excess of the breaking-down process is a male, and
-<span class='pageno' id='Page_427'>427</span>one that is more constructive is a female. Furthermore,
-whichever process is in the excess during development determines
-the sex of the individual. Thus, if conditions are very
-favorable, there will be more females produced; but if, on the
-other hand, there is an excess of the breaking-down process,
-males are produced. So far, the process is conceived as a
-purely physiological one, but to this the authors then apply
-the selection hypothesis, which, they suppose, acts as a sort
-of break or regulation of the physiological processes, or in
-other words as a directive agent. They state: “Yet the
-sexual dimorphism, in the main, and in detail, has an adaptive
-significance, also securing the advantages of cross-fertilization
-and the like, and is, therefore, to some extent the result
-of the continual action of natural selection, though this may,
-of course, check variation in one form as well as favor it in
-another.” Disregarding this last addition, with which Geddes
-and Thompson think it necessary to burden their theory, let
-us return to the physiological side of the hypothesis. Their
-idea appears to me a sort of symbolism rather than a
-scientific attempt to explain sex. If their view had a real
-value, it ought to be possible to determine the sex of the
-developing organism with precision by regulating the conditions
-of its growth, and yet we cannot do this, nor do the
-authors make any claim of being able to do so. The hypothesis
-lacks the only support that can give it scientific
-standing, the proof of experiment.</p>
-
-<p class='c010'>There have been made, from time to time, a number of
-attempts to show that the sex of the embryo is predetermined
-in the egg, and is not determined later by external
-circumstances. In recent years this view has come more to
-the front, despite the apparent experimental evidence which
-seemed in one or two cases to point to the opposite view.
-One of the most complete analyses of the question is that
-of Cuénot, who has attempted to show that the sex of the
-embryo is determined in the egg, before or at the time of
-<span class='pageno' id='Page_428'>428</span>fertilization. He has also examined critically the evidence
-that appeared to show that external conditions, acting on the
-embryo, may determine the sex, and has pointed out some
-possible sources of error that had been overlooked. The
-best-known case is that of the tadpole of the frog, but Cuénot
-shows not only that there are chances of error in this experiment
-as carried out, but also, by his own experiments and
-observations, that the facts themselves are not above suspicion.
-He points out that at the age at which some of the tadpoles
-were when the examination was made, it was not always
-possible to tell definitely the sex of the individual, and least
-of all by means of the size alone of the reproductive organs,
-as was supposed, in one case at least, to be sufficient. In his
-own experiments he did not find an excess of one sex over
-the other as a result of feeding.</p>
-
-<p class='c010'>Cuénot points out that Brocadello found that the larger
-eggs laid by the silkworm give rise to from 88 to 95 per cent
-of females, and the small eggs to from 88 to 92 per cent of
-males. Joseph has confirmed this for <i>Ocneria dispar</i>, and Cuénot
-himself also reached this conclusion. Korschelt found that
-the large eggs of Dinophilus produced females and the small
-ones males. Cuénot experimented with three species of flies,
-and found that when the maggots were well nourished the
-number of the individuals of the two sexes was about equal,
-and when poorly nourished there were a few more females in
-two cases, and in another about the same number of males
-and females.</p>
-
-<p class='c010'>It has been claimed that the condition of nourishment of
-the mother may determine the number of eggs of a particular
-sex, but Cuénot found, in three species of flies which he
-raised, that there was a slight response in the opposite direction.
-He concludes that the condition of the mother is
-not a factor in the determination of sex.</p>
-
-<p class='c010'>The first egg of the two laid in each set by the pigeon is
-said, as a rule, to produce a male, and the second a female.
-<span class='pageno' id='Page_429'>429</span>Both Flourens and Cuénot found this to be the case in the
-few instances that they examined, but Cuénot has shown that
-this does not always happen. Even when this occurs, it has
-not been determined whether the result depends on something
-in the egg itself, that causes a male egg to be set free first, or
-on some external condition that determines that the first egg
-shall become a male. It has been claimed that the age of
-the spermatozoon might in this and in other cases determine
-the result; but Gerbe has shown that if the domestic hen is
-isolated for fifteen days after union with the male, she will
-continue to produce fertile eggs from which both sexes are
-produced, without showing any relation between the time
-the eggs are laid and the particular sex that develops.</p>
-
-<p class='c010'>Cuénot does not discuss whether sex is determined by the
-nucleus or by the protoplasm, but if, as he thinks probable,
-the size of the egg is a determining factor, it would appear
-that the protoplasm must be the chief agent. Even if this
-were the case it would still be possible that the size of the
-egg itself might be connected with some action on the part
-of the nucleus. If, as seems probable, identical twins come
-from halves of the same egg, then, since they are of the same
-sex, the absolute amount of protoplasm cannot be a factor
-in sex determination.</p>
-<div id='fig-6'  class='figcenter id010'>
-<img src='images/i430.jpg' alt='' class='ig001' />
-<div class='ic001'>
-<p><span class='sc'>Fig. 6.</span>—Diagram showing the maturation of the egg.</p>
-</div>
-</div>
-
-<p class='c009'>As a basis for the discussion that follows, certain processes
-that take place during the maturation divisions of the egg
-and of the spermatozoon must be briefly noticed. After the
-egg leaves the ovary it extrudes a minute body called the
-first polar body (Fig. <a href='#fig-6'>6 B, C, D</a>). This process of extrusion
-is really a cell division accompanied by the regular mitotic
-division of the nucleus; but since one of the products of the
-division, the polar body, is extremely small, the meaning of
-the process was not at first understood. The half of the
-nucleus, that remains in the egg, divides again, and one of its
-halves is thrown out into a second polar body (Fig. <a href='#fig-6'>6 E, F, G</a>)). Meanwhile, the first polar body has divided into two
-<span class='pageno' id='Page_430'>430</span>equal parts, so that we find now three polar bodies and the
-egg (Fig. <a href='#fig-6'>6 G</a>)). A strictly analogous process takes place
-in the formation of the spermatozoa (Fig. <a href='#fig-7'>7 B-F</a>). The
-mother-cell of the spermatozoon divides into two parts, which
-are equal in this case (Fig. <a href='#fig-7'>7 B-D</a>). Each of these then
-divides again (Fig. <a href='#fig-7'>7 E, F</a>), producing four cells that are
-comparable to the three polar bodies and the mature egg.
-Each of the four becomes a functional spermatozoon (Fig. <a href='#fig-7'>7 G, H</a>).
-Thus while in the maturation of the egg only the
-egg itself is capable of development, in the case of the male
-cells all four products of the two maturation divisions are
-functional.</p>
-<div id='fig-7'  class='figcenter id011'>
-<span class='pageno' id='Page_431'>431</span>
-<img src='images/i431.jpg' alt='' class='ig001' />
-<div class='ic001'>
-<p><span class='sc'>Fig. 7.</span>—Diagram showing the maturation of the spermatozoon.</p>
-</div>
-</div>
-<p class='c009'>Now, in certain cases of parthenogenesis, it has been found
-that one of the polar bodies may not be given off, but, remaining
-in the egg, its nucleus reunites with the egg nucleus, and
-thus takes the place of the spermatozoon, which does exactly
-the same thing when it fertilizes the egg, <i>i.e.</i> the nucleus of
-the spermatozoon unites with the nucleus of the egg. This
-fact in regard to the action of the polar body in fertilization
-is not as surprising as appears at first sight, for if each of the
-polar bodies is equivalent to a spermatozoon, the fertilization
-of the egg by one of its own polar bodies conforms to theory.</p>
-
-<p class='c010'>There is a considerable body of evidence showing that
-in many eggs at one of the two maturation divisions the
-<span class='pageno' id='Page_432'>432</span>chromatin rods derived from the nucleus are divided crosswise
-(Fig. <a href='#fig-6'>6 B, C</a>). The same thing occurs at one of the two
-divisions in the formation of the spermatozoon (Fig. <a href='#fig-7'>7 B, C</a>).
-At the other division to form the other polar body (or the
-other sperm-cell) the chromatin rods appear to be split
-lengthwise, as in ordinary cell division (Fig. <a href='#fig-6'>6 E, F, G</a>).
-In recent years the <i>cross-division</i> of the chromatin rods has
-attracted a great deal of notice, and Weismann in particular
-drew attention to the possible importance of this kind of
-division.</p>
-
-<p class='c010'>There is another fact that gives this division especial significance.
-It has been discovered that the number of chromosomes
-that appears in each dividing cell of the organism
-is a constant number, but it has also been discovered that
-the egg, before extruding its polar bodies, and the mother-cell
-of the spermatozoon (Figs. <a href='#fig-6'>6</a>, <a href='#fig-7'>7 B</a>), contain exactly
-half of the number of chromosomes that are characteristic
-of the body-cells of the same animal (Figs. <a href='#fig-6'>6</a>, <a href='#fig-7'>7 A</a>). Now
-there is good evidence to show that the reduction in number
-is due to the chromosomes uniting sometimes end to end in
-pairs, as shown in Figures A and B. Furthermore, it has
-been suggested that at one of the maturation divisions, when
-the chromosomes divide crosswise, the united chromosomes
-are separated (Figs. <a href='#fig-6'>6</a>, <a href='#fig-7'>7 B, C</a>), so that one remains in the
-egg and the other goes out into the polar body. The same
-thing is supposed to occur at one of the maturation divisions
-of the sperm mother-cell. A further consideration of capital
-importance in this connection has been advocated by Montgomery
-and by Sutton, namely, that, when the chromosomes
-unite in pairs, a chromosome from one parent unites with
-one from the other parent. Consequently at one of the two
-reduction divisions maternal and paternal chromosomes may
-separate again, some to go to one cell, some to the other.</p>
-
-<p class='c010'>When the spermatozoon enters the egg it brings into the
-egg as many new chromosomes as the egg itself possesses at
-<span class='pageno' id='Page_433'>433</span>this time, and the two nuclei, uniting into a single one, furnish
-the total number of chromosomes characteristic of the
-animal that develops from the egg. At first the chromosomes
-that are brought in by the spermatozoon lie at one side of
-the fused nucleus, and those from the egg itself at the other
-side. This arrangement appears, however, in some cases
-at least, to be lost later. At every division of the nucleus,
-each chromosome divides and sends a half to each of the
-daughter-nuclei. Thus every cell in the body contains as
-many paternal as maternal chromosomes. This statement
-also applies to the first cells that go into the reproductive
-organs, some of which become the mother-cells of the germ-cells.
-Later, however, in the history of the germ-cells,—just
-before the maturation divisions,—these chromosomes
-are supposed to unite in pairs, end to end, as explained
-above, to give the reduced number. Later there follows
-the separation of these paired chromosomes at one of the
-two maturation divisions. If at this time all the paternal
-chromosomes should pass to one pole, and all the maternal
-to the other, the germ-cell ceases to be mixed, and becomes
-purely paternal or maternal. If this ever occurs, the problem
-of heredity may become simplified, and even the question of
-sex may be indirectly involved; but it has not been established
-that, when the reduced number of chromosomes is formed,
-there is a strict union between the paternal and maternal chromosomes,
-and if not, the subsequent separation is probably
-not along these lines. If, however, the chromosomes contain
-different qualities, as Boveri believes, there may be two kinds
-of eggs, and two kinds of spermatozoa in regard to <i>each
-particular character</i>. It is this last assumption only that is
-made in Mendel’s theory of the purity of the germ-cells.</p>
-
-<p class='c010'>Several attempts have been made at different times to
-connect the facts in regard to the extrusion of the polar
-bodies with those involved in the determination of sex.
-Minot suggested, in 1877, that the egg ejects by means of the
-<span class='pageno' id='Page_434'>434</span>polar bodies its male elements, which are again received in
-the fertilization of the egg by the spermatozoon. The same
-idea has also been expressed by others. It has been objected
-to this view that one polar body ought to suffice, and that
-no similar throwing out of part of its substance is found in
-the process of formation of the spermatozoon, which should,
-on the hypothesis, throw out its female elements. It
-would seem, on first thought, that this view might find support
-in the idea expressed above, namely, that in one of
-the polar bodies half of the chromosomes pass out, so that
-there is conceivably a separation of the maternal from the
-paternal. If this were the case also in the spermatozoa, then
-two of each four would be paternal and two maternal. This
-is, however, a very different thing from supposing them to
-be male and female, for it by no means follows, because
-the chromosomes correspond to those of the father or of
-the mother in the sum of their characters, that they are,
-therefore, also male or female in regard to sex.</p>
-
-<p class='c010'>It has been pointed out already, that in most parthenogenetic
-eggs only one polar body is extruded. There are,
-it is true, a few apparent exceptions to this rule, but in most
-cases it is certain that only one is extruded. In several
-cases the beginning of the formation of the second maturation
-division of the nucleus takes place, but after the chromosomes
-have divided they come together again in the
-nucleus. If each polar body be interpreted as equivalent
-to a spermatozoon, then this result is rather a process of
-self-fertilization than true parthenogenesis. It is, nevertheless,
-true that in some cases development seems to go on
-after both polar bodies have been extruded. Moreover, it
-has been found possible to cause the eggs of the sea-urchin
-to begin their development by artificial solutions after they
-have extruded both polar bodies. A single spermatozoon
-may also produce an embryo if it enters a piece of egg-protoplasm
-without a nucleus. The last instance is a case of
-<span class='pageno' id='Page_435'>435</span>male parthenogenesis, and if the theory of the equivalency
-of spermatozoon and egg be correct, this is what should
-occur.</p>
-
-<p class='c010'>Quite recently, Cuénot, Beard, Castle, and Lenhossek have
-contended that the differentiation of sex is the outcome of internal
-factors. They think that the view that sex is determined
-by external agents is fundamentally erroneous. The fallacies
-that have given rise to this conception, Castle points out, are,
-first, that in animals that reproduce sometimes by parthenogenesis
-and sometimes by fertilized eggs, the former process
-is favored by good nutrition and the latter by poor nutrition.
-This only means, in reality, Castle thinks, that parthenogenetic
-reproduction is favored by external conditions, and this kind
-of reproduction, he thinks, is a thing <i>sui generis</i>, and not
-to be compared to the formation of more females in the
-sexual forms of reproduction. There is no proof, however,
-that this is anything more than a superficial distinction,
-and it ignores the fact that in ordinary cases the females
-sometimes lay parthenogenetic eggs which differ, as far as we
-can see, from eggs that are destined to be fertilized in no
-important respect. More significant, it seems to me, is the
-fact that only parthenogenetic females develop the following
-spring from the fertilized eggs of the last generation of the
-autumn series, whose origin is described to be due to lack
-of food. We find, in the case of aphids, that unfertilized
-parthenogenetic eggs and also fertilized eggs give rise to
-females only, while a change in the amount of food causes
-the parthenogenetic eggs to give rise both to males and to
-females. This point is not, I think, fully met by Castle, for
-even if the change in food does not, as he claims, cause only
-one sex to appear, yet lack of food does seem to account for
-the appearance of the males at least.</p>
-
-<p class='c010'>The other fallacy, mentioned by Cuénot, is that the excess
-of males that has been observed when the food supply is
-limited is due to the early death of a larger percentage
-<span class='pageno' id='Page_436'>436</span>of females, which require more food, but this still fails to
-account for the excess of females when more food is given,
-provided Yung’s experiments on tadpoles are correct. It
-may be, however, in the light of Pflüger’s results, that there
-has been some mistake in the experiments themselves.</p>
-
-<p class='c010'>We may now proceed to examine Castle’s argument,
-attempting to show in what way sex is predetermined in the
-embryo. His hypothesis rests on the three following premises:
-“(1) the idea of Darwin, that in animals and plants of
-either sex the characters of the opposite sex are latent; (2) the
-idea of Mendel, that in the formation of the gametes [germ-cells]
-of hybrids a segregation of the parental characters
-takes place, and when in fertilization different segregated
-characters meet, one will dominate, the other become latent
-or recessive; (3) the idea of Weismann, that in the maturation
-of egg and spermatozoon a segregation is attended by a
-visible reduction in the number of chromosomes in the
-germinal nuclei.”</p>
-
-<p class='c010'>Expressed in a somewhat more general way, Castle suggests
-that each egg and each spermatozoon is either a male or a
-female germ-cell (and not a mixture of the two), and when a
-female egg is fertilized by a male spermatozoon, or <i>vice versa</i>,
-the individual is a sexual hybrid with one sex dominating
-and the other latent. The assumption that there are two
-kinds of eggs, male and female, and two kinds of spermatozoa,
-male and female, is not supported by any direct or experimental
-evidence. Moreover, in order to carry out the
-hypothesis, it is necessary to make the further assumption
-that a female egg can only be fertilized by a male spermatozoon,
-and a male egg by a female spermatozoon. While
-such a view is contrary to all our previous ideas, yet it must
-be admitted that there are no facts which disprove directly
-that such a selection on the part of the germ-cells takes place.
-If these two suppositions be granted, then Castle’s hypothesis
-is as follows:—</p>
-
-<p class='c010'><span class='pageno' id='Page_437'>437</span>In order that half of the individuals shall become males
-and half females it is necessary to assume that in some
-individuals the male element dominates and in others the
-female, and since each fertilized egg contains both male
-and female elements, it is necessary to assume that either
-the egg or the spermatozoon contains the dominating element.</p>
-
-<p class='c010'>Castle supposes that in hermaphroditic organisms the two
-characters “exist in the balanced relationship in which they
-were received from the parents,” but, as has just been stated,
-in unisexual forms one or the other sex dominates, except of
-course in those rare cases, as in the bees and ants, where
-half of the body may bear the characters of one sex, and the
-other half that of the other sex.</p>
-
-<p class='c010'>In parthenogenetic species the female character is supposed
-to be uniformly stronger, so that it dominates in every contest,
-“for the fertilized egg in such species develops invariably
-into a female.” Under certain circumstances, as Castle
-points out, the parthenogenetic female produces both males
-and females, and this is also true in the occasional development
-of the unfertilized egg of the silkworm moth, and of
-the gypsy moth, in which both male and female individuals
-are produced by parthenogenesis. These facts show that
-even in unfertilized eggs both sexes are potentially present;
-but this might be interpreted to mean that some eggs are
-male and some female, rather than that each egg has the
-possibility of both kinds of development. If, however, one
-polar body is retained in these parthenogenetic eggs, then <i>ex
-hypothese</i> each egg would contain the potentialities of both
-sexes (if the polar body were of the opposite sex character).
-It seems necessary to make this assumption because in some
-parthenogenetic forms males and females may be produced
-later by each individual, as in the aphids, and this could not
-occur if we assume that some parthenogenetic eggs are purely
-male and some female.</p>
-
-<p class='c010'><span class='pageno' id='Page_438'>438</span>Castle assumes, in fact, that in animals like daphnids and
-rotifers one polar body only is extruded, and the other (the
-second) is retained in the egg, and hence the potentiality of
-producing males is present. In the honey-bee, on the contrary,
-Castle assumes that both polar bodies are extruded
-in the unfertilized egg (and there are some observations that
-support this idea), and since only males are produced from
-these, he believes it is the female element that has been sent
-out into the second polar body. This hypothesis is necessary,
-because Castle assumes that when both elements are present
-in the bee’s eggs, the female element dominates. “Hence,
-if the egg which has formed two polar cells develops without
-fertilization, it must develop into a male. But if such an
-egg is fertilized, it invariably forms a parthenogenetic female
-♀ (♂), that is, an individual in which the male character is
-recessive. Accordingly the <i>functional</i> spermatozoon must
-in such cases invariably bear the <i>female character</i>, and this is
-invariably dominant over the male character when the two
-meet in fertilization.”</p>
-
-<p class='c010'>If it should prove generally true that the size of the egg
-is one of the factors determining the sex, we have still the
-further question to consider as to whether some eggs are
-bigger because they are already female, or whether all eggs
-that go beyond a certain size are females, and all those that
-fail to reach this are males. If this is the case, an animal
-might produce more females if the external conditions were
-favorable to the growth of the eggs, and if in some cases
-these large eggs were capable of developing, parthenogenetic
-races might become established. Should, however, the conditions
-for nutrition become less favorable, some of the eggs
-might fall below the former size and produce males. It is
-not apparent, however, why all the fertilized autumn eggs of
-the aphids should give rise to females, for although these
-eggs are known to be larger than the summer eggs, yet they
-are produced under unfavorable conditions.</p>
-
-<p class='c010'><span class='pageno' id='Page_439'>439</span>The preceding discussion will show how far we still are
-from knowing what factors determine sex. Castle’s argument
-well illustrates how many assumptions must be made
-in order to make possible the view that sex is a predetermined
-quality of each germ-cell. Even if these assumptions
-were admissible, we still return to the old idea that the <i>fertilized
-egg</i> has both possibilities, and something determines
-which shall dominate. Until we have ascertained definitely
-by experimental work whether the sex in some forms can be
-determined by external conditions, it is almost worthless to
-speculate further. Whatever decision is reached, the conclusion
-will have an immediate bearing on the question to be
-next discussed. Meanwhile, we can at least examine some
-of the theories that have been advanced as to what advantage,
-if any, has been gained by having the individuals of
-many classes divided into two kinds, male and female.</p>
-<h3 class='c014'><span class='sc'>Sex as a Phenomenon of Adaptation</span></h3>
-
-<p class='c015'>Of what advantage is it to have the individuals of many
-species separated into males and females? It is obviously
-a disadvantage from the point of view of propagation to have
-half of the individuals incapable of producing young, and the
-other half also incapable of doing so, as a rule, unless the
-eggs are fertilized by the other sex. Is there any compensation
-gained because each new individual arises from two
-parents instead of from one? Many answers have been
-attempted to these questions.</p>
-
-<p class='c010'>At the outset it should be recognized that we are by no
-means forced to assume, as is so often done, that because
-there is this separation of the sexes it must have arisen on
-account of its advantage to the species. Whether the result
-may be of some benefit regardless of how it arose, may
-be an entirely different question. It would be extremely
-difficult to weigh the relative advantages (if there are any)
-<span class='pageno' id='Page_440'>440</span>and disadvantages (that are obvious as pointed out above),
-nor is it probable that in this way we can hope to get a final
-answer to our problem. We may begin by examining some
-of the modern hypotheses that have been advanced in this
-connection.</p>
-
-<p class='c010'>Darwin has brought together a large number of facts
-which appear to show the beneficial effects of the union of
-germ-cells from two different individuals. Conversely, it is
-very generally believed, both by breeders and by some experimenters,
-that self-fertilization in the case of hermaphroditic
-forms leads, in many cases, though apparently not in all, to
-the production of less vigorous offspring. Darwin’s general
-position is that it is an advantage to the offspring to have
-been derived from two parents rather than to have come
-from the union of the germ-cells of the same individual, and
-he sees, in the manifold contrivances in hermaphroditic animals
-and plants to insure cross-fertilization, an adaptation for
-this purpose.</p>
-
-<p class='c010'>This question of whether self-fertilization is less advantageous
-than cross-fertilization is, however, a different question
-from that of whether <i>non-sexual</i> methods of reproduction
-are less advantageous than sexual ones. Since some plants,
-like the banana, have been propagated for a very long time
-solely by non-sexual methods without any obvious detriment
-to them, it is at first sight not easy to see what other advantage
-could be gained by the sexual method. The case of the
-banana shows that some forms do not require a sexual
-method of propagation. Other forms, however, are so constituted,
-as we find them, that they cannot reproduce at the
-present time except by the sexual method. In other words,
-the latter are now adapted, as it were, to the sexual method,
-and there is no longer any choice between the two methods.
-The question of whether a non-sexual form might do better
-if it had another method of propagation is not, perhaps, a
-profitable question to discuss.</p>
-
-<p class='c010'><span class='pageno' id='Page_441'>441</span>What we really need to know is whether or not the sexual
-method was once acquired, because it was an advantage
-to a particular organism, or to the species to reproduce in
-this way. It is assumed by many writers that this was the
-case, but whether they have sufficient ground for forming
-such an opinion is our chief concern here. On the other
-hand, it is conceivable, at least, that if the sexual method
-once became established, it might continue without respect to
-any superiority it gave over other methods, and might finally
-become a necessary condition for the propagation of particular
-species. Thus the method would become essential to
-propagation without respect to whether the species lost more
-than it gained. Whichever way the balance should turn, it
-might make little difference, so long as the species was still
-able to propagate itself.</p>
-
-<p class='c010'>Brooks made the interesting and ingenious suggestion that
-the separation of the sexes has been brought about as a sort
-of specialization of the individuals in two directions. The
-male cells are supposed to accumulate the newly acquired
-characters, and represent, therefore, the progressive element
-in evolution. The female cells are the conservative element,
-holding on to what has been gained in the past. It does not
-seem probable, in the light of more recent work, that this
-is the function of the two sexes, and it is unlikely that we
-could account for the origin of the two sexes through the
-supposed advantage that such a specialization might bring
-about. A number of writers, Galton, Van Beneden, Bütschli,
-Maupas, and others, have looked at the process of sexual reproduction
-as a sort of renewal of youth, or rejuvenescence
-of the individuals. There is certainly a good deal in the
-process to suggest that something of this sort takes place,
-although we must be on our guard against assuming that
-the rejuvenescence is anything more than the fulfilment of a
-necessary stage in the life history. Weismann has ridiculed
-this suggestion on the ground that it is inconceivable that
-<span class='pageno' id='Page_442'>442</span>two organisms, decrepit with old age, could renew their
-youth by uniting. Two spent rockets, he says, cannot be
-imagined to form a new one by combining. There is apparent
-soundness in this argument, if the implication is taken
-in a narrow physical sense. If, on the other hand, the egg is
-so constituted that at a certain stage in its development an
-outside change is required to introduce a new phase, then
-the conception of rejuvenescence does not appear in quite
-so absurd a light.</p>
-
-<p class='c010'>This hypothesis of rejuvenescence is based mainly on certain
-processes that take place in the life history of some of
-the unicellular animals. Let us now see what this evidence is.
-The results of certain experiments carried out by Maupas on
-some of the ciliate protozoans have been fruitful in arousing
-discussion as to the ultimate meaning of the sexual process.
-Maupas’ experiments consisted in isolating single individuals,
-and in following the history of the descendants that were
-produced non-sexually by division. He found that the descendants
-of an individual kept on dividing, but showed no
-tendency to unite with each other. After a large number of
-generations had been passed through (in <i>Stylonychia pustulata</i>,
-between 128 and 175; in <i>Leucophys patula</i>, 300 to 450;
-and in <i>Onychodromus grandis</i>, 140 to 230 generations), the
-division began to slow down, and finally came to a standstill.
-Maupas found that if he took one of these run-down
-individuals, and placed it with another in the same condition
-from another culture, that had had a different parentage, the
-two would unite and the so-called process of conjugation take
-place. This process consists for the species used, in the temporary
-union and partial fusion of the protoplasm of the two
-individuals, of an interchange of micronuclei, and of a fusion,
-in each individual, of the micronucleus received from the
-other individual with one of its own. The individuals then
-separate, and a new nucleus (or nuclei) is formed out of the
-fused pair.</p>
-
-<p class='c010'><span class='pageno' id='Page_443'>443</span>The individuals in question, in which this interchange of
-micronuclei has taken place, undergo a change, and behave
-differently from what they did before. They feed, become
-larger and less vacuolated, and are more active. They soon
-begin once more to divide. Maupas found that an individual
-that has conjugated will run through a new cycle of divisions,
-which will, however, after a time also slow down, unless conjugation
-with another individual having a different history
-takes place. If conjugation is prevented, the individual will
-die after a time. These results seemed to show that the
-division phase of the life history cannot go on indefinitely,
-and that through conjugation the individual is again brought
-back to the starting-point.</p>
-
-<p class='c010'>Quite recently Calkins has carried out a somewhat similar
-series of experiments, which have an important bearing on
-the interpretation of Maupas’ results. The experiment of
-isolating an individual and tracing the career of its descendants
-was repeated with the following results: two series
-were started, the original forms coming from different localities.
-Of their eight descendants four of each were isolated.
-The remaining four of each set were kept together as stock
-material. The rate of division was taken as the measure of
-vitality. The animals divided more or less regularly from
-February to July. After each division (or sometimes after
-two divisions) the individuals were separated. About the
-30th of July the paramœcia began to die “at an alarming
-rate, indicating that a period of depression had apparently
-set in, or degeneration in Maupas’ sense.” Up to this time
-the animals had been living in hay infusion, renewed every
-few days, from which they obtained the bacteria on which
-they feed. Calkins tried the effect of putting the weakened
-paramœcia into a new environment. Infusion of vegetables
-gave no good results, but meat infusions proved successful.
-“The first experiment with the latter was with teased liver,
-which was added to the usual hay infusion. The result was
-<span class='pageno' id='Page_444'>444</span>very gratifying, for the organisms began immediately to grow
-and to divide, the rate of division rising from five to nine divisions
-in successive ten-day periods.” This beneficial effect
-was not lasting, however, and after ten days the paramœcia
-began to die off faster than before, and the renewed application
-of the liver extract failed to revive them. A number of
-other extracts were then tried without effect. Finally they
-were transferred to the clear extract of lean beef in tap water.
-The effect of this medium was interesting, for, although it
-restored the weakened vitality, there was no rapid increase
-in the rate of division, as when first treated with the teased
-liver. The infusoria were, however, now large and vigorous,
-and did not die unless transferred from the beef medium to
-the usual hay infusion. “When this was attempted, they
-would become abnormally active and would finally die. The
-division rate gradually increased during the month of August
-until, in the last ten days, they averaged six generations.
-Finally, in September, the attempts to get them back on the
-old diet of hay infusion were successful, and then the division
-rate went up at once to twelve times in ten days, and a
-month later they were dividing at the rate of fifty times a
-month.”</p>
-
-<p class='c010'>“These cultures went on well until December, when the
-paramœcia began to die again. They were saved once more
-with the beef extract, and when returned later to the hay
-infusion continued through another cycle of almost three
-months. Some of these were treated, once a week for
-twenty-four hours, with the beef extract, and while the two
-sets ran a parallel course at first, those kept continuously in
-the hay infusion died after a time, but those that had been
-put once a week into the beef extract (which had been
-stopped, however, in March) continued their high rate of
-division throughout the period of decline of their sister cells,
-and did not show signs of diminished vitality until the first
-period in June.” At this time their rate of division increased
-<span class='pageno' id='Page_445'>445</span>rapidly. They were put back into the beef extract, but it
-failed now to have a beneficial effect, and the animals continued
-to die at a rapid rate. To judge from the appearance
-of the organisms the new decline was due to a different cause;
-for, while in the former periods the food vacuoles contained
-undigested food, at this period the interior was free from food
-masses. The protoplasm became granular and different from
-that of a healthy individual. None of the former remedies
-were now of any avail. “When the last of the <i>B</i>-series stock
-had died in the five hundred and seventieth generation (June
-16th), it looked as though the cultures were about to come to
-an end.” Extract of the brain and of the pancreas were then
-tried. To this a favorable response took place at once. The
-organisms became normal in appearance and began to divide.
-After forty-eight hours’ treatment they were returned to
-the usual hay infusion. Here they continued to multiply and
-reached on June 28th the six hundred and sixty-fifth generation.</p>
-
-<p class='c010'>There can be no doubt that the periods of depression that
-appear in these infusoria kept in cultures can be successfully
-passed if the animals are introduced into a new environment.
-Without a change of this sort they will die. Calkins
-thinks that the effect is produced, not by the new kind of
-food that is supplied, but by the presence of certain chemical
-compounds. The beef extract “does not have a direct
-stimulating effect upon the digestive process and upon division,
-for, while the organisms are immersed in it, there is a
-very slow division rate; when transferred again to the hay
-infusion, however, they divide more rapidly than before.”</p>
-
-<p class='c010'>This brings us back to the idea of the “renewal of youth”
-through conjugation. Maupas claimed that union of individuals
-having the same immediate descent is profitless. Calkins
-suggests that this is due to the similarity in the chemical
-composition of the protoplasm of the two individuals. When
-in nature two individuals that have lived under somewhat
-<span class='pageno' id='Page_446'>446</span>different conditions conjugate, the result should be beneficial,
-since there takes place the commingling of different
-protoplasms.</p>
-
-<p class='c010'>Calkins’s work has shown that by means of certain substances
-much the same effect can be produced as that which
-is supposed to follow from the conjugation of two unrelated
-individuals. The presumption, therefore, is in favor of the
-view that the two results may be brought about in the same
-way, although we should be careful against a too ready acceptation
-of this plausible argument; for we have ample evidence
-to show that many closely similar (if not identical)
-responses of organisms may be brought about by very
-different agencies. The experiments seem to indicate that
-paramœcium might go on indefinitely reproducing by division,
-provided its environment is changed from time to time.
-If this is true, it is conceivable that the same thing is accomplished
-through conjugation. In the light of this possible
-interpretation much of the mystery connected with the term
-<i>rejuvenescence</i> is removed, for we see that there is nothing
-in the process itself except that it brings the organism into a
-new relation with other substances. Difficult as it assuredly
-is to understand how this benefits the animal, the experimental
-fact shows, nevertheless, that such a change is for
-its good. That there is really nothing in the process of
-conjugation itself apart from the difference in the constitution
-of the conjugating individuals is shown by the result
-that the union of individuals having the same history and
-kept under the same conditions is of no benefit.</p>
-
-<p class='c010'>Can we apply this same conception to the process of
-fertilization in the higher animals and plants? Is the substance
-of which their bodies are made of such a sort that it
-cannot go on living indefinitely under the same conditions,
-but must at times be supplied with a new environment? If
-this could be established, we could see the advantage of
-sexual reproduction over the non-sexual method. It would
-<span class='pageno' id='Page_447'>447</span>be extremely rash at present to make a generalization of this
-kind, for there are many forms known in which the only
-method of propagation that exists is the non-sexual one. In
-other words, there are no grounds for the assumption that
-this is a necessary condition for all kinds of protoplasm, but
-only for certain kinds.</p>
-
-<p class='c010'>In the insects, crustaceans, rotifers, and in some plants there
-are a few species whose egg develops without fertilization.
-This makes it appear probable that the particular kind of
-protoplasm of these animals does not absolutely require
-union from time to time with the protoplasm of another
-individual having a somewhat different constitution.</p>
-
-<p class='c010'>There is also an interesting parallel between the effects of
-solutions on the protozoans in Calkins’s experiments and certain
-results that have been obtained in artificial parthenogenesis.
-It has been stated, that by brushing the unfertilized
-eggs of the silkworm moth a larger percentage will develop
-parthenogenetically; and more recently it has been shown by
-Matthews that by agitation of the water in which the unfertilized
-eggs of the starfish have been placed many of
-them will begin their development. It was first shown by
-Richard Hertwig that by putting the unfertilized eggs of the
-sea-urchin in strychnine solutions, they will begin to segment,
-and I obtained the same results much better by placing the
-eggs in solutions of magnesium chloride. Loeb then succeeded
-in carrying the development to a later stage by using
-a different strength of the same solution, as well as by other
-solutions. Under the most favorable circumstances some of
-the eggs may produce larvæ that seem normal in all respects,
-but whether they can develop into adult sea-urchins has not
-yet been shown.</p>
-
-<p class='c010'>These results indicate that one at least of the factors of
-fertilization is the stimulus given to the egg. On the other
-hand, the lack of vigor shown by many eggs that have been
-artificially fertilized indicates that some other result is also
-<span class='pageno' id='Page_448'>448</span>accomplished by the normal method of fertilization that is
-here absent. This may mean no more than that as yet we
-have not found all the conditions necessary to supply the
-place of the spermatozoon.</p>
-
-<p class='c010'>In our study of the phenomena of adaptation we have
-found that sometimes the adaptation is for the benefit of the
-individual and at other times for the benefit of the species.
-May it not be true also that the process of sexual reproduction
-has more to do with a benefit conferred on the race
-rather than on the individual? In fact, Weismann has
-elaborated a view based on the conception that the process
-of sexual reproduction is beneficial to the race rather than to
-the individual. His idea, however, is not so much that the
-result is of direct benefit to a particular species, as it is advantageous
-to the formation of new species from the original
-one. In a sense this amounts, perhaps, to nearly the same
-thing, but in another sense the idea involves a somewhat
-different point of view.</p>
-
-<p class='c010'>According to his view “the deeper significance of conjugation”
-and of sexual reproduction is concerned “with the
-mingling of the hereditary tendencies of two individuals.”
-In this way, through the different combinations that are
-formed, variations which he supposes are indispensable for the
-action of natural selection originate. The purpose of the
-sexual process is solely, according to Weismann, to supply
-the variations for natural selection. If it be asked how this
-process has been acquired for the purpose of supplying natural
-selection with the material on which it can work, we find
-the following reply given by Weismann. “But if amphimixis
-[by which he means the union of sex-cells from different
-individuals] is not absolutely necessary, the rarity of purely
-parthenogenetic reproduction shows that it must have a widespread
-and deep significance. Its benefits are not to be
-sought in the single individual; for organisms can arise by
-agamic methods, without thereby suffering any loss of vital
-<span class='pageno' id='Page_449'>449</span>energy; amphimixis must rather be advantageous for the
-maintenance and modification of species. As soon as we
-admit that amphimixis confers some such benefits, it is clear
-that the latter must be augmented, as the method appears
-more frequently in the course of generations; hence we are
-led to inquire how nature can best have undertaken to give
-this amphimixis the widest possible range in the organic
-world.” Nature, Weismann says, could find no more effectual
-means of bringing about the union of the sexual cells
-than by rendering them incapable of developing alone.
-“The male germ-cells, being specially adapted for seeking
-and entering the ovum, are, as a rule, so ill provided with nutriment
-that their unaided development into an individual
-would be impossible; but with the ovum it is otherwise, and
-accordingly the ‘reduction division’ removes half the germ-plasm
-and the power of developing is withdrawn.” It can
-scarcely be claimed, in the light of more recent discoveries,
-that the reduction division takes place in order to prevent the
-development of the ovum, for how then could we explain the
-corresponding division of the male germ-cells?</p>
-
-<p class='c010'>Whatever means has been employed to bring about the process
-of sexual reproduction, the guiding principle is supposed
-by Weismann to be natural selection as stated in the following
-paragraph: “If we regard amphimixis as an adaptation of
-the highest importance, the phenomenon can be explained in a
-simple way. I only assume that amphimixis is of advantage
-in the phyletic development of life, and furthermore that it is
-beneficial in maintaining the level of adaptation, which has
-been once attained, in every single organism; for this is as
-dependent upon the continuous activity of natural selection as
-the coming of new species. According to the frequency
-with which amphimixis recurs in the life of a species, is the
-efficiency with which the species is maintained; since so
-much the more easily will it adapt itself to new conditions of
-life, and thus become modified.”</p>
-
-<p class='c010'><span class='pageno' id='Page_450'>450</span>Thus we reach the somewhat startling conclusion that
-through natural selection the germ-cells and their protozoan
-prototypes have been rendered incapable, through natural
-selection, of reproducing by non-sexual methods, in order
-that variations may be supplied for the farther action of
-this same process of natural selection. The speculation has
-the appearance of arguing in a circle, although if it were
-worth the attempt an ingenious mind might perhaps succeed
-in showing that such a thing is not logically inconceivable.</p>
-
-<p class='c010'>It seems strange that a claim of this sort should have been
-made, when it is so apparent that the most immediate effect
-of intercrossing is to swamp all variations that depart from
-the average. Even if it were true that new combinations of
-characters would arise through the union of the germ-cells of
-two different animals, it is certainly true that in the case of fluctuating
-variations this new combination would be lost by later
-crossing with average individuals. Moreover, it is well known
-that variations occur amongst forms that are produced asexually.
-On the whole, it does not seem to be a satisfactory
-solution of the problem to assume that sexual reproduction
-has been acquired in order to supply natural selection with
-material on which it may work.</p>
-
-<p class='c010'>Our examination of the suggestions that have been made
-and of the speculation indulged in, as to what benefit the
-process of sexual reproduction confers on the animals and
-plants that make use of this method of propagation, has failed
-to show convincingly that any advantage to the individual or
-to the species is the outcome. This may mean, either that
-there is no advantage, or that we have as yet failed to
-understand the meaning of the phenomenon. The only light
-that has been thrown on the question is that a certain amount
-of renewed vigor is a consequence of this process, but we
-cannot explain how this takes place. There is also the suggestion
-that the union of different cells produces the same
-beneficial effect as a change in the conditions of life produces
-<span class='pageno' id='Page_451'>451</span>on the organism. The bad effects of close interbreeding that
-seem sometimes to follow is explicable on this view. This,
-it seems to me, is the most plausible solution of the question
-that has been advanced; but, even if this should prove to be
-the correct view, we need not assume that the process has
-been acquired on account of this advantage, for there is
-nothing to show that it has been acquired in this way.</p>
-
-<div class='pbb'>
- <hr class='pb c006' />
-</div>
-<div class='chapter'>
-  <span class='pageno' id='Page_452'>452</span>
-  <h2 class='c008'>CHAPTER XIII<br /> <br /><span class='c013'>SUMMARY AND GENERAL CONCLUSIONS</span></h2>
-</div>
-<p class='c009'><span class='sc'>The</span> question of the origin of the adaptations with which
-the last three chapters have so largely dealt is one of the
-most difficult problems in the whole range of biology, and
-yet it is one whose immense interest has tempted philosophers
-in the past, and will no doubt continue to excite the
-imagination of biologists for many years to come. No pretence
-has been made in the preceding pages to account for
-the cause of a single useful variation. We have examined
-the evidence, and from this we believe the assumption justified
-that such variations do sometimes appear. The more
-fundamental question as to the origin of these variations has
-not been taken up, except in those cases in which the adaptive
-response appeared directly in connection with a known
-external cause. But these kinds of responses do not appear
-to have been the source of the other adaptations of the
-organic world. Our discussion has been largely confined to
-the problem of the widespread occurrence of adaptation in
-living things, and to the most probable kinds of known
-variations that could have given rise to these adaptations.
-But, to repeat, we have made no attempt to account for the
-causes or the origin of the different kinds of variation.</p>
-
-<p class='c010'>Nägeli, in speaking of the methods of the earlier theorists
-in Germany, remarks with much acumen: “We might have
-expected that after the period of the Nature-philosophizers,
-which in Germany crippled the best forces that might have
-been used for the advance of the science, we should have
-learnt something from experience, and have carefully guarded
-<span class='pageno' id='Page_453'>453</span>the field of real scientific work from philosophical speculation.
-But the outcome has shown that, in general, the philosophical,
-philological, and æsthetic expression always gets the upper
-hand, and a fundamental and exact treatment of scientific
-questions remains limited to a small circle. The public at
-large always shows a distinct preference for the so-called
-idealistic, poetic, and speculative modes of expression.” The
-truth of this statement can scarcely be doubted when in our
-own time we have seen more than once the same method
-employed with great public applause. Nowhere is this more
-apparent than in the writings of many of the followers of
-Darwin in respect to the adaptations of living things. To
-imagine that a particular organ is useful to its possessor, and
-to account for its origin because of the imagined benefit conferred,
-is the general procedure of the followers of this school.
-Although protests have from time to time been raised against
-this unwarrantable way of settling the matter, they have been
-largely ignored and forgotten. The fallacy of the argument
-has, for example, been admirably pointed out by Bateson in
-the following statement:<a id='r36' /><a href='#f36' class='c017'><sup>[36]</sup></a> “In examining cases of variation
-I have not thought it necessary to speculate on the usefulness
-or harmfulness of the variations described. For reasons
-given in Section II such speculation, whether applied to normal
-structures or to variation, is barren and profitless. If
-any one is curious on these questions of Adaptation, he may
-easily thus exercise his imagination. In any case of Variation
-there are a hundred ways in which it may be beneficial
-or detrimental. For instance, if the ‘hairy’ variety of the
-moor-hen became established on an island, as many strange
-varieties have been, I do not doubt that ingenious persons
-would invite us to see how the hairiness fitted the bird in
-some special way for life in that island in particular. Their
-contention would be hard to deny, for on this class of speculation
-the only limitations are those of the ingenuity of the
-<span class='pageno' id='Page_454'>454</span>author. While the only test of utility is the success of the
-organism, even this does not indicate the utility of one part
-of the economy, but rather the net fitness of the whole.”
-Keeping in mind the admonitions contained in the two preceding
-quotations, let us pass in review and attempt to analyze
-more fully the different points that have been considered
-in the preceding chapters.</p>
-
-<div class='footnote c018' id='f36'>
-<p class='c019'><span class='label'><a href='#r36'>36</a>.&nbsp;&nbsp;</span>“Materials for the Study of Variation.”</p>
-</div>
-
-<p class='c010'>It has been pointed out that the evidence in favor of the
-theory of evolution appears to establish this theory with great
-probability, although a closer examination shows that we are
-almost completely in the dark as to how the process has
-come about. For example, we have not yet been able to
-determine whether the great groups of animals and plants
-owe their resemblance to descent from a single original species
-or from a large number of species. The former view is
-more plausible, because on it we appear to be furnished with
-a better explanation of resemblances as due to divergence
-of character. Yet even here a closer scrutiny of the homologies
-of comparative anatomy shows that this explanation
-may be more apparent than real. If discontinuous variation
-represents the steps by which evolution has taken place, the
-artificiality of the explanation is apparent, at least to a certain
-degree.</p>
-
-<p class='c010'>Admitting that the theory of evolution is the most probable
-view that we have to account for the facts, we next
-meet with two further questions,—the origin of species and
-the meaning of adaptation. These are two separate and distinct
-questions, and not one and the same as the Darwinian
-theory claims. The fact that all organisms are more or
-less adapted to live in some environment appears from our
-examination to have no direct connection with the origin of
-the adaptation, for, in the first place, it seems probable that,
-in general, organisms do not respond adaptively to the environment
-and produce new species in this way; and, in the
-second place, there is no evidence to show that variation
-<span class='pageno' id='Page_455'>455</span>from internal causes is so regulated that only adaptive structures
-arise (although only adaptive ones may survive).</p>
-
-<p class='c010'>Our general conclusion is then as follows: A species does not
-arise from another one because it is better adapted. Selection,
-in other words, does not account for the origin of new species;
-and adaptation cannot be taken as the measure of a species.</p>
-
-<p class='c010'>It may sound like a commonplace to state that only those
-individuals survive and propagate themselves that can find
-some place in nature where they can exist and leave descendants;
-and yet this statement may contain all that it is
-necessary to assume, in order to account for the fact that
-organisms are, on the whole, adapted. Let us see how this
-view differs from the Darwinian statement of the origination
-of new forms through a process of natural selection.</p>
-
-<p class='c010'>According to Darwin’s view of the origin of species, each
-new species is gradually formed out of an older one, because
-of the advantage that the new individual may have over the
-parent form. Each step forward is acquired, because it
-better adapts the organism to the old, or to a new set of
-conditions. In contrast to this, I have urged that the formation
-of the new species is, as a rule, quite independent
-of its adaptive value in regard to the parent species. But
-after it has appeared, its survival will depend upon whether
-it can find a place in nature where it can exist and leave
-descendants. If it should be well adapted to an environment,
-it will be represented in it by a large number of individuals.
-If it is poorly adapted, it may only barely succeed in existing,
-and leave correspondingly fewer descendants. If its adaptiveness
-falls below a certain point, it can never get a permanent
-foothold, however often it may appear. Thus the test
-of survival determines which species can remain in existence,
-and which cannot, but new species are not manufactured in
-this way. How far subsequent variations may be supposed
-to be determined by the survival of certain species and the
-destruction of others will be discussed presently.</p>
-
-<p class='c010'><span class='pageno' id='Page_456'>456</span>The difference between the two points of view that we
-are contrasting can be best brought out by considering
-the two other kinds of selection which Darwin supposes to
-have been at work; namely, artificial and sexual selection.</p>
-
-<p class='c010'>Darwin thinks that the results of artificial selection are
-brought about by the breeder picking out fluctuating variations.
-It appears that he has probably overestimated the
-extent to which this process can be carried; for while there
-can be no doubt that a certain standard, or fixity of type,
-can be obtained by selecting fluctuating variations, yet it
-now seems quite certain that the extent to which this can be
-carried is very limited. It appears that other factors have
-also played an important rôle; amongst these the occasional
-appearance of discontinuous variation, also the bringing under
-cultivation of the numerous “smaller species” of De Vries,
-or the so-called “single variations” of Darwin. Further,
-the effects of intercrossing in all combinations of the above
-forms of variations, followed by the selection of certain of
-the new forms obtained, has been largely employed, and
-also the direct influence of food and of other external conditions,
-which may be necessary to keep the race up to a
-certain standard, have played a part in some cases. The
-outcome is, therefore, by no means so simple as one might
-infer from Darwin’s treatment of the subject in his “Origin
-of Species.” For these reasons, as well as for others that
-have been given, it will be evident that the process of artificial
-selection cannot be expected to give a very clear idea
-of how natural selection could act.</p>
-
-<p class='c010'>It is, however, the process of sexual selection that brings
-out in the strongest contrast the difference between Darwin’s
-main idea of natural selection and the law of the survival
-of species. In sexual selection the competition is supposed
-to be always between the individuals of the same species
-and of the same sex. There can be no doubt in one’s
-mind, after reading “The Descent of Man,” that Darwin
-<span class='pageno' id='Page_457'>457</span>held firmly to the belief that the individual differences, or
-fluctuating variations, furnish the material for selection.
-In this way it could never happen that two competing
-species could exterminate each other, because in the one
-the males were better adorned, or killed each other off on
-a larger scale, owing to the presence of special weapons of
-warfare. It is clear that on the law of the survival of
-species, secondary sexual characters cannot be supposed to
-have evolved because of their value. Their origin is totally
-inexplicable on this view. In fact, the presence of the
-ornaments must be in some cases injurious to the existence
-of the species. The interpretation of this means, I think,
-that individual competition cannot be as severe as Darwin
-believed, and cannot lead to the results that he imagined
-it does. For this reason it seemed important to make as
-careful an examination of the claims of the theory of sexual
-selection as possible, and I hope that the outcome of the
-examination has shown quite definitely that the theory is
-incompetent to account for the facts that it claims to explain.
-It is certain in this case that we are dealing with a phenomenon
-that must be studied quite apart from any selective
-value that the secondary sexual organs may have. If this is
-granted, it will be seen that there is here a wide field for
-experimental investigation that is practically untouched.</p>
-
-<p class='c010'>It is evident that the first step that will clear the way to a
-fuller understanding of the problem of evolution must be a
-more thorough examination of the question of variation.
-Darwin himself fully appreciated this fact, yet until within
-the last fifteen years the study of variation has been largely
-neglected. With a fuller knowledge of the nature of fluctuating
-variation as the outcome of the studies of Galton, Pearson,
-De Vries, and others, and with a fuller knowledge of the
-possibilities of discontinuous variation as emphasized by
-Bateson and by De Vries, and, further, with a better knowledge
-of some of the laws of inheritance in these cases, we
-<span class='pageno' id='Page_458'>458</span>have begun to get a different conception of how evolution has
-come about. It may be well, therefore, to go once more over
-the main points in regard to the different kinds of variation.</p>
-
-<p class='c010'>While it has been found that no two individuals of a
-species are exactly alike, yet, taken as a group, the variations
-appear as though they followed the law of chance. The
-descendants of the group show the same differences. Thus
-the group <i>as a whole</i> appears constant, while the individuals
-fluctuate continually in all directions. This is what we
-understand by fluctuating variation. If the external conditions
-are changed, a new “<i>mode</i>” may appear, but the change
-is generally only a temporary one, and lasts only as long as
-the new conditions remain. Thus, while the direct influence
-of the environment may show for a time, the result is transient.
-Even if it were permanent, there is no evidence that
-the adaptation of organisms could be accounted for in this
-way unless the response were useful. It appears that this
-sometimes really occurs, especially in responses to temperature,
-to moisture, to the amount of salts in solution, to
-poisonous substances, etc. In this way, one kind of adaptation
-is brought about, but there is no evidence that the great
-number of structural adaptations have thus arisen.</p>
-
-<p class='c010'>The Lamarckian principle of the inheritance of acquired
-characters has also been supposed by many writers to be an
-important source of adaptive variation. An examination of
-this theory is not found to inspire confidence. We have, therefore,
-eliminated this hypothesis on the ground that it lacks
-evidence in its favor, and also because it appears improbable
-that in this way many of the adaptations in organisms could
-have been acquired.</p>
-
-<p class='c010'>Finally, there is the group of discontinuous variations. Of
-these there may be several kinds, and there is some evidence
-showing that there are such. For the present we may include
-all the different sorts under the term <i>mutation</i>, meaning
-that the new character or group of characters suddenly
-<span class='pageno' id='Page_459'>459</span>appears, and is inherited in its new form. From the results
-of De Vries it appears that mutations are sometimes
-scattering, at least in the case of the evening primrose.
-From such scattering mutations, the smaller species or
-varieties (in so far as these do not depend on local conditions)
-arise. There is here an important point of agreement
-with Darwin’s idea in regard to evolution, inasmuch as
-he supposed that varieties are incipient species. Our point
-of view is different, however, in that we do not suppose these
-varieties (mutations) to have been gradually formed out of
-fluctuating variations by a process of selection, but to have
-arisen at once by a single mutation. It also appears that in
-some cases a single new mutation may develop in a species.
-We may suppose that the new form might in such a case
-supplant the parent species by absorbing it, or both may go
-on living side by side, as will be more likely the case if they
-are adapted to somewhat different conditions.</p>
-
-<p class='c010'>A number of writers have supposed that evolution marches
-steadily forward toward its final goal, which may even
-lead in some cases to the final but inevitable destruction
-of the species. By certain writers this view has been called
-orthogenesis, although at other times the idea is not so much
-that there is advance in a straight line, as advance in all
-directions. This appears to be Nägeli’s view. It gives a
-splendid picture of the organic world, as irresistibly marching
-toward its goal,—a relentless process in some cases, leading
-to final annihilation, a beneficent process in other cases,
-leading to the fullest perfection of form of which the type is
-capable. Compared with the vacillating progress which is
-supposed to be the outcome of individual selection, this view
-of progression has a grandeur that appeals directly to the imagination.
-We must be guided, however, by evidence, rather
-than by sentiment. The case will, moreover, bear closer
-scrutiny. If evolution has indeed taken place by the survival
-of a series of mutations, whose origin has no connection
-<span class='pageno' id='Page_460'>460</span>with their value, does not this in the end amount to nearly
-the same thing as maintaining that evolution of organisms
-has been a steady progress forward,—a progress undirected
-by external forces, but the outcome of internal development?
-Admitting that innumerable creations have been lopped off,
-because they could find no foothold, yet, as Nägeli points out,
-the result is that, instead of a dense tangle of forms, there
-has been left relatively few that have been found capable of
-existing,—those that have found some place in which they
-can live and leave progeny. From this point of view it
-may appear, at first thought, that the idea of evolution
-through mutations involves a fundamentally different view
-from that of the Darwinian school of selection; but in so far
-as selection also depends on the spontaneous appearance of
-fluctuating variations, the same point of view is to some extent
-involved,—only the steps are supposed to be smaller.
-This point is usually ignored and passed over in silence by
-the Darwinians, but, as Wigand has pointed out, it makes
-very little difference whether the stages in the process of
-evolution are imagined to be very small or somewhat larger,
-so long as they are spontaneous. Selection does not do more
-than determine the survival of what is offered to it, and does
-not create anything new.</p>
-
-<p class='c010'>It is true that if the fluctuating variations that are selected
-be connected by very slight differences with an almost continuous
-series of other forms, and if little by little such a
-series be advanced in a given direction by selection, we get
-the idea of a continuity, whose advance is determined by selection.
-It is this conception that appears to give the theory of
-natural selection a creative power, which in reality it does
-not possess, and certainly not in the modified form in which
-the theory was finally left by Darwin. For Darwin found
-himself forced to admit that, unless a very considerable number
-of individuals varied at the same time and in the same
-direction, the formation of new species could not take place, and
-<span class='pageno' id='Page_461'>461</span>this idea of many individuals varying at the same time, and
-in the same direction, at once involves the conception that
-evolution moves forward by some force residing in the organism,
-driving it forwards or backwards. Instability comes,
-perhaps, nearer to expressing this idea than any other term,
-and yet to evolve from a protozoan to a man implies the idea
-of something more than simple unstableness.</p>
-
-<p class='c010'>The idea that Weismann has touched upon in this connection,
-namely, that the survival of a given form determines the
-future course of evolution for that form, is very plausible, and
-also fits in well with the results of our experience in the field
-of the inheritance of variations. We see new variations or mutations
-departing in some or in many characters from the
-original type, apparently by new combinations or perturbations
-of those already present. We never expect to see a
-bird emerge from the egg of an alligator. Thus it appears
-that by the survival of certain forms the future course of
-evolution is determined in so far as the new types of mutation
-are thereby limited. Weismann means, however, that
-in this way new plus or minus steps will be indefinitely determined
-amongst the new fluctuating variations, but this statement
-is contradicted by our experience of the results of
-artificial selection. The upper limit does not keep on pushing
-out indefinitely in the direction determined by the first selection,
-but is soon brought to a standstill. So that, as far as
-Weismann’s hypothesis is concerned, the idea appears to have
-no special value. On the other hand, this idea may be fruitful
-if applied to mutations, but here unfortunately we have not
-sufficient experience to guide us, and we do not know definitely
-whether a new character that appears as a mutation
-will be more likely, in subsequent mutations, to go on increasing
-in some of the descendants. Thus, while the mutation
-theory must assume that some new characters will go on
-heaping up, we lack the experimental evidence to show that
-this really occurs. It would be also equally important to
-<span class='pageno' id='Page_462'>462</span>determine, whether, if after several mutations have successively
-appeared in the same direction, there would be an
-established tendency to go on in the same direction in some
-of the future mutations. But here again we must wait until
-we have more data before we attempt to build up a theory
-on such a basis.</p>
-
-<p class='c010'>The attacks on the Darwinian school by the followers of
-the modern school of experimentalists are with few exceptions
-based on the assumption that the natural selectionists pretend
-that their principle is a sort of creative force,—a factor
-in evolution in the sense of being an active agent. This
-assumption of the selectionists has led many of them to ignore
-a fundamental weakness of their theory, namely, the
-origin of the variations themselves, although Darwin did
-not overlook or ignore this side of the problem, or fail to
-realize its importance, as have some of his more ardent, but
-less critical, followers. They have contented themselves, as a
-rule, with pointing out that certain structures are useful, and
-this has seemed to them sufficient proof that the structures
-must have been acquired because of their value. In contrast
-to this complacency of the selectionists, we find here and
-there naturalists who have, from time to time, insisted that
-the scientific problem of evolution is not to be found in the
-principle of selection, but in the origin of the variations
-themselves. It will be clear, from what has been said, that
-this is our position also, and for us adaptation itself does not
-appear to be any more a problem that can be examined by
-scientific methods, than the lack of adaptation. The causes
-of the change of whatever kind should be our immediate quest.
-The destruction of the unfit, because they can find no place
-where they can exist, does not explain the origin of the fit.</p>
-
-<p class='c010'>Over and beyond the primary question of the <i>origin</i> of the
-adaptive, or non-adaptive, structure is the fact that we find
-that the great majority of animals and plants show distinct
-evidence of being suited or adapted to live in a special environment,
-<span class='pageno' id='Page_463'>463</span><i>i.e.</i> their structure and their responses are such that
-they can live and leave descendants behind them. I can see
-but two ways in which to account for this condition, either
-(1) teleologically, by assuming that only adaptive variations
-arise, or (2) by the survival of only those mutations that are
-sufficiently adapted to get a foothold. Against the former
-view is to be urged that the evidence shows quite clearly
-that variations (mutations) arise that are not adaptive. On
-the latter view the dual nature of the problem that we have
-to deal with becomes evident, for we assume that, while the
-origin of the adaptive structures must be due to purely
-physical principles in the widest sense, yet whether an organism
-that arises in this way shall persist depends on whether
-it can find a suitable environment. This latter is in one
-sense selection, although the word has come to have a different
-significance, and, therefore, I prefer to use the term
-<i>survival of species</i>.</p>
-
-<p class='c010'>The origin of a new form and its survival after it has
-appeared have been often confused by the Darwinian school
-and have given the critics of this school a fair chance for ridiculing
-the selection theory. The Darwinian school has supposed
-that it could explain the origin of adaptations on the
-basis of their usefulness. In this it seems to me they are
-wrong. Their opponents, on the other hand, have, I believe,
-gone too far when they state that the present condition of
-animals and plants can be explained without applying the
-test of survival, or in a broad sense the principle of selection
-amongst species.</p>
-
-<p class='c010'>It will be clear, therefore, in spite of the criticism that I
-have not hesitated to apply to many of the phases of the selection
-theory, especially in relation to the selection of the individuals
-of a species, that I am not unappreciative of the great
-value of that part of Darwin’s idea which claims that the <i>condition</i>
-of the organic world, as we find it, cannot be accounted
-for entirely without applying the principle of selection in one
-<span class='pageno' id='Page_464'>464</span>form or another. This idea will remain, I think, a most
-important contribution to the theory of evolution. We may
-sum up our position categorically in the following statements:</p>
-
-<p class='c010'>Animals and plants are not changed in this or in that part
-in order to become better adjusted to a given environment,
-as the Darwinian theory postulates. Species exist that are
-in some respects very poorly adapted to the environment in
-which they must live. If competition were as severe as the
-selection theory assumes, this imperfection would not exist.</p>
-
-<p class='c010'>In other cases a structure may be more perfect than the
-requirements of selection demand. We must admit, therefore,
-that we cannot measure the organic world by the measure
-of utility alone. If it be granted that selection is not a
-moulding force in the organic world, we can more easily
-understand how both less perfection and greater perfection
-may be present than the demands of survival require.</p>
-
-<p class='c010'>If we suppose that new mutations and “definitely” inherited
-variations suddenly appear, some of which will find
-an environment to which they are more or less well fitted,
-we can see how evolution may have gone on without assuming
-new species have been formed through a process of
-competition. Nature’s supreme test is survival. She makes
-new forms to bring them to this test through mutation, and
-does not remodel old forms through a process of individual
-selection.</p>
-<div class='pbb'>
- <hr class='pb c006' />
-</div>
-<div class='chapter'>
-  <span class='pageno' id='Page_465'>465</span>
-  <h2 id='idx' class='c008'>INDEX</h2>
-</div>
-<ul class='index c006'>
-  <li class='c035'>Acclimatization, <a href='#Page_319'>319</a>.</li>
-  <li class='c035'>Acorn, <a href='#Page_24'>24</a>.</li>
-  <li class='c035'>Acracids, <a href='#Page_160'>160</a>.</li>
-  <li class='c035'>Adaptation, definition of, <a href='#Page_1'>1</a>.</li>
-  <li class='c035'>Adjustments, individual, <a href='#Page_12'>12</a>.</li>
-  <li class='c035'>Agassiz, <a href='#Page_1'>1</a>, <a href='#Page_44'>44</a>, <a href='#Page_61'>61</a>.</li>
-  <li class='c035'>Agelæus, <a href='#Page_173'>173</a>.</li>
-  <li class='c035'>Alcohol, <a href='#Page_13'>13</a>.</li>
-  <li class='c035'>Algæ, red, <a href='#Page_9'>9</a>.</li>
-  <li class='c035'>Alkaloids, <a href='#Page_13'>13</a>.</li>
-  <li class='c035'>Allen, <a href='#Page_173'>173</a>, <a href='#Page_307'>307</a>-<a href='#Page_310'>310</a>.</li>
-  <li class='c035'>Allolobophora, <a href='#Page_380'>380</a>.</li>
-  <li class='c035'>Alpheus, <a href='#Page_344'>344</a>.</li>
-  <li class='c035'>Ammophila, <a href='#Page_5'>5</a>.</li>
-  <li class='c035'>Ammotragus, <a href='#Page_208'>208</a>.</li>
-  <li class='c035'>Ampelopsis, <a href='#Page_403'>403</a>.</li>
-  <li class='c035'>Amphimixis, <a href='#Page_448'>448</a>-<a href='#Page_449'>449</a>.</li>
-  <li class='c035'>Amphioxus, <a href='#Page_399'>399</a>.</li>
-  <li class='c035'>Ancon race, <a href='#Page_315'>315</a>-<a href='#Page_316'>316</a>.</li>
-  <li class='c035'>Angiostomum, <a href='#Page_422'>422</a>.</li>
-  <li class='c035'>Anguillidæ, <a href='#Page_320'>320</a>.</li>
-  <li class='c035'>Annelids, <a href='#Page_19'>19</a>, <a href='#Page_20'>20</a>.</li>
-  <li class='c035'>Anolis, <a href='#Page_10'>10</a>, <a href='#Page_194'>194</a>.</li>
-  <li class='c035'>Ant-eater, <a href='#Page_227'>227</a>, <a href='#Page_228'>228</a>.</li>
-  <li class='c035'>Antelope, <a href='#Page_6'>6</a>, <a href='#Page_206'>206</a>, <a href='#Page_208'>208</a>.</li>
-  <li class='c035'>Antitoxin, <a href='#Page_14'>14</a>.</li>
-  <li class='c035'>Ants, <a href='#Page_141'>141</a>-<a href='#Page_146'>146</a>, <a href='#Page_354'>354</a>, <a href='#Page_386'>386</a>, <a href='#Page_407'>407</a>.</li>
-  <li class='c035'>Aphids, <a href='#Page_384'>384</a>-<a href='#Page_386'>386</a>, <a href='#Page_419'>419</a>, <a href='#Page_426'>426</a>.</li>
-  <li class='c035'>Apus, <a href='#Page_418'>418</a>.</li>
-  <li class='c035'>Archæopteryx, <a href='#Page_41'>41</a>, <a href='#Page_42'>42</a>, <a href='#Page_53'>53</a>, <a href='#Page_54'>54</a>.</li>
-  <li class='c035'>Ardea, <a href='#Page_200'>200</a>.</li>
-  <li class='c035'>Argus pheasant, <a href='#Page_199'>199</a>.</li>
-  <li class='c035'>Aristolochia Clematitis, <a href='#Page_10'>10</a>, <a href='#Page_11'>11</a>, <a href='#Page_12'>12</a>.</li>
-  <li class='c035'>Arsenic, <a href='#Page_13'>13</a>.</li>
-  <li class='c035'>Artemia, <a href='#Page_306'>306</a>.</li>
-  <li class='c035'>Ascidians, <a href='#Page_417'>417</a>.</li>
-  <li class='c035'>Askenasy, <a href='#Page_161'>161</a>.</li>
-  <li class='c035'>Aspalax, <a href='#Page_227'>227</a>.</li>
-  <li class='c035'>Asterina, <a href='#Page_421'>421</a>-<a href='#Page_422'>422</a>.</li>
-  <li class='c035'>Autenrieth, <a href='#Page_58'>58</a>.</li>
-  <li class='c006'>Baboon, <a href='#Page_209'>209</a>.</li>
-  <li class='c035'>Bacteria, <a href='#Page_14'>14</a>, <a href='#Page_15'>15</a>, <a href='#Page_111'>111</a>, <a href='#Page_398'>398</a>.</li>
-  <li class='c035'>Baer, Von, <a href='#Page_60'>60</a>, <a href='#Page_61'>61</a>, <a href='#Page_74'>74</a>, <a href='#Page_75'>75</a>.</li>
-  <li class='c035'>Bamboo, <a href='#Page_313'>313</a>.</li>
-  <li class='c035'>Barnacles, <a href='#Page_417'>417</a>.</li>
-  <li class='c035'>Bartlett, <a href='#Page_209'>209</a>, <a href='#Page_220'>220</a>.</li>
-  <li class='c035'>Bat, <a href='#Page_2'>2</a>.</li>
-  <li class='c035'>Bates, <a href='#Page_183'>183</a>, <a href='#Page_186'>186</a>.</li>
-  <li class='c035'>Bateson, <a href='#Page_273'>273</a>, <a href='#Page_278'>278</a>, <a href='#Page_453'>453</a>.</li>
-  <li class='c035'><span class='pageno' id='Page_466'>466</span>Beard, <a href='#Page_210'>210</a>, <a href='#Page_211'>211</a>, <a href='#Page_216'>216</a>.</li>
-  <li class='c035'>Beard, J., <a href='#Page_435'>435</a>.</li>
-  <li class='c035'>Bee, <a href='#Page_2'>2</a>, <a href='#Page_3'>3</a>, <a href='#Page_19'>19</a>, <a href='#Page_143'>143</a>, <a href='#Page_179'>179</a>, <a href='#Page_303'>303</a>, <a href='#Page_350'>350</a>, <a href='#Page_406'>406</a>, <a href='#Page_420'>420</a>, <a href='#Page_421'>421</a>, <a href='#Page_425'>425</a>, <a href='#Page_438'>438</a>.</li>
-  <li class='c035'>Beethoven, <a href='#Page_218'>218</a>.</li>
-  <li class='c035'>Beetles, <a href='#Page_182'>182</a>, <a href='#Page_183'>183</a>, <a href='#Page_189'>189</a>.</li>
-  <li class='c035'>Bell-bird, <a href='#Page_198'>198</a>.</li>
-  <li class='c035'>Beneden, Van, <a href='#Page_441'>441</a>.</li>
-  <li class='c035'>Berbura goat, <a href='#Page_208'>208</a>.</li>
-  <li class='c035'>Biogenetic Law, <a href='#Page_71'>71</a>.</li>
-  <li class='c035'>Birds, <a href='#Page_6'>6</a>,  <a href='#Page_407'>407</a>;
-    <ul>
-      <li>definition of group,  <a href='#Page_36'>36</a>;</li>
-      <li>evolution of,  <a href='#Page_41'>41</a>;</li>
-      <li>instincts of young,  <a href='#Page_4'>4</a>;</li>
-      <li>nest,  <a href='#Page_4'>4</a>;</li>
-      <li>of paradise,  <a href='#Page_6'>6</a>;</li>
-      <li>teeth of,  <a href='#Page_301'>301</a>;</li>
-      <li>variation in, <a href='#Page_309'>309</a>-<a href='#Page_312'>312</a>.</li>
-    </ul>
-  </li>
-  <li class='c035'>Blind animals, <a href='#Page_354'>354</a>.</li>
-  <li class='c035'>Blow-fly, <a href='#Page_383'>383</a>.</li>
-  <li class='c035'>Bonellia, <a href='#Page_353'>353</a>, <a href='#Page_417'>417</a>.</li>
-  <li class='c035'>Born, <a href='#Page_424'>424</a>.</li>
-  <li class='c035'>Bos, <a href='#Page_206'>206</a>.</li>
-  <li class='c035'>Boveri, <a href='#Page_433'>433</a>.</li>
-  <li class='c035'>Bovidæ, <a href='#Page_207'>207</a>.</li>
-  <li class='c035'>Branchipus, <a href='#Page_306'>306</a>.</li>
-  <li class='c035'>Brocadello, <a href='#Page_428'>428</a>.</li>
-  <li class='c035'>Brooks, <a href='#Page_441'>441</a>.</li>
-  <li class='c035'>Brown-Séquard, <a href='#Page_232'>232</a>, <a href='#Page_241'>241</a>, <a href='#Page_250'>250</a>-<a href='#Page_257'>257</a>.</li>
-  <li class='c035'>Buffon, <a href='#Page_300'>300</a>.</li>
-  <li class='c035'>Bull, <a href='#Page_207'>207</a>, <a href='#Page_315'>315</a>.</li>
-  <li class='c035'>Bütschli, <a href='#Page_441'>441</a>.</li>
-  <li class='c035'>Butterfly, <a href='#Page_3'>3</a>, <a href='#Page_184'>184</a>, <a href='#Page_389'>389</a>.</li>
-  <li class='c006'>Cactus, <a href='#Page_10'>10</a>.</li>
-  <li class='c035'>Caffein, <a href='#Page_13'>13</a>.</li>
-  <li class='c035'>California salmon, <a href='#Page_19'>19</a>.</li>
-  <li class='c035'>Calkins, <a href='#Page_443'>443</a>-<a href='#Page_447'>447</a>.</li>
-  <li class='c035'>Callionymus, <a href='#Page_191'>191</a>.</li>
-  <li class='c035'>Calocalanus, <a href='#Page_177'>177</a>.</li>
-  <li class='c035'>Cameron, <a href='#Page_425'>425</a>.</li>
-  <li class='c035'>Canestrini, <a href='#Page_178'>178</a>.</li>
-  <li class='c035'>Canidæ, <a href='#Page_308'>308</a>.</li>
-  <li class='c035'>Canis, <a href='#Page_410'>410</a>.</li>
-  <li class='c035'>Carbonnier, <a href='#Page_190'>190</a>, <a href='#Page_192'>192</a>.</li>
-  <li class='c035'>Cardamine, <a href='#Page_335'>335</a>.</li>
-  <li class='c035'>Cardinalis, <a href='#Page_173'>173</a>.</li>
-  <li class='c035'>Cardium, <a href='#Page_305'>305</a>.</li>
-  <li class='c035'>Cassowary, <a href='#Page_202'>202</a>.</li>
-  <li class='c035'>Castle, <a href='#Page_148'>148</a>, <a href='#Page_321'>321</a>, <a href='#Page_435'>435</a>, <a href='#Page_438'>438</a>.</li>
-  <li class='c035'>Caterpillar, <a href='#Page_5'>5</a>, <a href='#Page_8'>8</a>, <a href='#Page_186'>186</a>.</li>
-  <li class='c035'>Cattle, <a href='#Page_411'>411</a>.</li>
-  <li class='c035'>Cats, <a href='#Page_209'>209</a>.</li>
-  <li class='c035'>Cercopithecus, <a href='#Page_208'>208</a>.</li>
-  <li class='c035'><span class='pageno' id='Page_467'>467</span>Cervus, <a href='#Page_304'>304</a>.</li>
-  <li class='c035'>Chara, <a href='#Page_420'>420</a>.</li>
-  <li class='c035'>Charrin, <a href='#Page_257'>257</a>.</li>
-  <li class='c035'>Chick, <a href='#Page_57'>57</a>, <a href='#Page_406'>406</a>.</li>
-  <li class='c035'>Child, <a href='#Page_72'>72</a>.</li>
-  <li class='c035'>Chinese pheasants, <a href='#Page_6'>6</a>.</li>
-  <li class='c035'>Chlorophyl, <a href='#Page_9'>9</a>.</li>
-  <li class='c035'>Cicadas, <a href='#Page_187'>187</a>, <a href='#Page_188'>188</a>.</li>
-  <li class='c035'>Ciona, <a href='#Page_148'>148</a>.</li>
-  <li class='c035'>Classification, <a href='#Page_31'>31</a>-<a href='#Page_36'>36</a>.</li>
-  <li class='c035'>Classification, scheme of, <a href='#Page_38'>38</a>.</li>
-  <li class='c035'>Cockatoo, <a href='#Page_6'>6</a>.</li>
-  <li class='c035'>Colaptes, <a href='#Page_310'>310</a>.</li>
-  <li class='c035'>Colias, <a href='#Page_185'>185</a>.</li>
-  <li class='c035'>Colonial forms, <a href='#Page_127'>127</a>.</li>
-  <li class='c035'>Color, <a href='#Page_18'>18</a>, <a href='#Page_19'>19</a>, <a href='#Page_24'>24</a>, <a href='#Page_133'>133</a>, <a href='#Page_375'>375</a>.</li>
-  <li class='c035'>Coloration, <a href='#Page_5'>5</a>, <a href='#Page_6'>6</a>, <a href='#Page_7'>7</a>, <a href='#Page_23'>23</a>, <a href='#Page_357'>357</a>-<a href='#Page_360'>360</a>.</li>
-  <li class='c035'>Columba livia, <a href='#Page_76'>76</a>.</li>
-  <li class='c035'>Comb of bees, <a href='#Page_4'>4</a>.</li>
-  <li class='c035'>Communal marriages, <a href='#Page_210'>210</a>.</li>
-  <li class='c035'>Competition, <a href='#Page_104'>104</a>, <a href='#Page_112'>112</a>, <a href='#Page_119'>119</a>, <a href='#Page_120'>120</a>, <a href='#Page_121'>121</a>, <a href='#Page_122'>122</a>, <a href='#Page_123'>123</a>.</li>
-  <li class='c035'>Compositæ, <a href='#Page_130'>130</a>.</li>
-  <li class='c035'>Cones, <a href='#Page_310'>310</a>.</li>
-  <li class='c035'>Conklin, <a href='#Page_72'>72</a>.</li>
-  <li class='c035'>Cope, <a href='#Page_49'>49</a>, <a href='#Page_259'>259</a>.</li>
-  <li class='c035'>Copridæ, <a href='#Page_183'>183</a>.</li>
-  <li class='c035'>Coral-snakes, <a href='#Page_194'>194</a>.</li>
-  <li class='c035'>Correlated variation, <a href='#Page_94'>94</a>.</li>
-  <li class='c035'>Correlation, <a href='#Page_134'>134</a>.</li>
-  <li class='c035'>Cottus, <a href='#Page_191'>191</a>.</li>
-  <li class='c035'>Crab, <a href='#Page_15'>15</a>, <a href='#Page_248'>248</a>, <a href='#Page_344'>344</a>, <a href='#Page_354'>354</a>.</li>
-  <li class='c035'>Crickets, <a href='#Page_188'>188</a>.</li>
-  <li class='c035'>Crocodiles, <a href='#Page_193'>193</a>.</li>
-  <li class='c035'>Crosby, <a href='#Page_398'>398</a>.</li>
-  <li class='c035'>Cross-fertilization, <a href='#Page_21'>21</a>.</li>
-  <li class='c035'>Crossing of species, <a href='#Page_148'>148</a>, <a href='#Page_149'>149</a>, <a href='#Page_150'>150</a>.</li>
-  <li class='c035'>Crystal, <a href='#Page_29'>29</a>.</li>
-  <li class='c035'>Cryptocerus, <a href='#Page_144'>144</a>.</li>
-  <li class='c035'>Ctenophors, <a href='#Page_417'>417</a>.</li>
-  <li class='c035'>Cuckoo, <a href='#Page_139'>139</a>, <a href='#Page_140'>140</a>, <a href='#Page_141'>141</a>.</li>
-  <li class='c035'>Cuénot, <a href='#Page_427'>427</a>-<a href='#Page_428'>428</a>, <a href='#Page_435'>435</a>.</li>
-  <li class='c035'>Culicidæ, <a href='#Page_188'>188</a>.</li>
-  <li class='c035'>Cunningham, <a href='#Page_257'>257</a>-<a href='#Page_260'>260</a>.</li>
-  <li class='c035'>Cuvier, <a href='#Page_44'>44</a>, <a href='#Page_301'>301</a>.</li>
-  <li class='c035'>Cynocephalus, <a href='#Page_209'>209</a>.</li>
-  <li class='c035'>Cypridopsis, <a href='#Page_392'>392</a>-<a href='#Page_393'>393</a>.</li>
-  <li class='c035'>Cyprinodonts, <a href='#Page_190'>190</a>.</li>
-  <li class='c035'>Cypris, <a href='#Page_320'>320</a>.</li>
-  <li class='c006'>Dall, <a href='#Page_260'>260</a>.</li>
-  <li class='c035'>Dallinger, <a href='#Page_320'>320</a>.</li>
-  <li class='c035'>Danaids, <a href='#Page_160'>160</a>.</li>
-  <li class='c035'>Dances, <a href='#Page_195'>195</a>.</li>
-  <li class='c035'>Daphnia, <a href='#Page_305'>305</a>, <a href='#Page_418'>418</a>.</li>
-  <li class='c035'>Darwin, C., numerous references throughout the text.</li>
-  <li class='c035'>Darwin, Erasmus, <a href='#Page_223'>223</a>.</li>
-  <li class='c035'><span class='pageno' id='Page_468'>468</span>Date-palm, <a href='#Page_313'>313</a>.</li>
-  <li class='c035'>Davenport, <a href='#Page_264'>264</a>, <a href='#Page_266'>266</a>, <a href='#Page_321'>321</a>.</li>
-  <li class='c035'>Dean, <a href='#Page_358'>358</a>.</li>
-  <li class='c035'>Death, <a href='#Page_370'>370</a>.</li>
-  <li class='c035'>Death, feigning, <a href='#Page_410'>410</a>, <a href='#Page_411'>411</a>.</li>
-  <li class='c035'>Deer, <a href='#Page_309'>309</a>.</li>
-  <li class='c035'>Degeneration, <a href='#Page_165'>165</a>.</li>
-  <li class='c035'>Delamare, <a href='#Page_257'>257</a>.</li>
-  <li class='c035'>Descent theory, <a href='#Page_31'>31</a>-<a href='#Page_35'>35</a>.</li>
-  <li class='c035'>Desmarest, <a href='#Page_206'>206</a>.</li>
-  <li class='c035'>Desmodium, <a href='#Page_403'>403</a>.</li>
-  <li class='c035'>Dianthus, <a href='#Page_149'>149</a>.</li>
-  <li class='c035'>Didelphys, <a href='#Page_410'>410</a>.</li>
-  <li class='c035'>Dimorphism, <a href='#Page_360'>360</a>.</li>
-  <li class='c035'>Dingoes, <a href='#Page_314'>314</a>.</li>
-  <li class='c035'>Dinophilus, <a href='#Page_428'>428</a>.</li>
-  <li class='c035'>Diptera, <a href='#Page_180'>180</a>, <a href='#Page_188'>188</a>.</li>
-  <li class='c035'>Divergence of character, <a href='#Page_127'>127</a>, <a href='#Page_128'>128</a>.</li>
-  <li class='c035'>Dog, <a href='#Page_226'>226</a>.</li>
-  <li class='c035'>Draba, <a href='#Page_288'>288</a>, <a href='#Page_289'>289</a>, <a href='#Page_290'>290</a>, <a href='#Page_292'>292</a>, <a href='#Page_294'>294</a>.</li>
-  <li class='c035'>Draco, <a href='#Page_194'>194</a>.</li>
-  <li class='c035'>Dragonet, <a href='#Page_191'>191</a>.</li>
-  <li class='c035'>Drill, <a href='#Page_209'>209</a>.</li>
-  <li class='c035'>Ducks, <a href='#Page_94'>94</a>, <a href='#Page_314'>314</a>.</li>
-  <li class='c035'>Düsing, <a href='#Page_423'>423</a>.</li>
-  <li class='c035'>Dutrochet, <a href='#Page_320'>320</a>.</li>
-  <li class='c006'>Earthworm, <a href='#Page_380'>380</a>, <a href='#Page_382'>382</a>, <a href='#Page_383'>383</a>, <a href='#Page_384'>384</a>, <a href='#Page_417'>417</a>.</li>
-  <li class='c035'>Echidna, <a href='#Page_54'>54</a>.</li>
-  <li class='c035'>Eciton, <a href='#Page_144'>144</a>.</li>
-  <li class='c035'>Egerton, <a href='#Page_204'>204</a>.</li>
-  <li class='c035'>Egg, <a href='#Page_429'>429</a>-<a href='#Page_430'>430</a>, <a href='#Page_432'>432</a>.</li>
-  <li class='c035'>Eggs, number of, <a href='#Page_19'>19</a>.</li>
-  <li class='c035'>Egypt, animals of, <a href='#Page_225'>225</a>.</li>
-  <li class='c035'>Egyptian remains of animals, <a href='#Page_43'>43</a>, <a href='#Page_44'>44</a>.</li>
-  <li class='c035'>Eimer, <a href='#Page_158'>158</a>, <a href='#Page_260'>260</a>.</li>
-  <li class='c035'>Eisig, <a href='#Page_72'>72</a>.</li>
-  <li class='c035'>Electric organs, <a href='#Page_22'>22</a>, <a href='#Page_132'>132</a>, <a href='#Page_372'>372</a>.</li>
-  <li class='c035'>Elephant, <a href='#Page_110'>110</a>-<a href='#Page_111'>111</a>, <a href='#Page_206'>206</a>, <a href='#Page_304'>304</a>.</li>
-  <li class='c035'>Emu, <a href='#Page_202'>202</a>.</li>
-  <li class='c035'>Entoscolax, <a href='#Page_353'>353</a>.</li>
-  <li class='c035'>Epihippus, <a href='#Page_50'>50</a>.</li>
-  <li class='c035'>Equus, <a href='#Page_50'>50</a>.</li>
-  <li class='c035'>Eristales, <a href='#Page_188'>188</a>.</li>
-  <li class='c035'>Esmeralda, <a href='#Page_182'>182</a>.</li>
-  <li class='c035'>Euploids, <a href='#Page_160'>160</a>.</li>
-  <li class='c035'>Eustephanus, <a href='#Page_201'>201</a>.</li>
-  <li class='c035'>Evolution, <a href='#Page_29'>29</a>.</li>
-  <li class='c035'>Ewart, <a href='#Page_238'>238</a>.</li>
-  <li class='c035'>Exercise, <a href='#Page_12'>12</a>.</li>
-  <li class='c035'>External conditions, <a href='#Page_130'>130</a>.</li>
-  <li class='c035'>Eye, <a href='#Page_13'>13</a>, <a href='#Page_131'>131</a>, <a href='#Page_132'>132</a>.</li>
-  <li class='c035'>Eye, evolution of, <a href='#Page_131'>131</a>, <a href='#Page_132'>132</a>.</li>
-  <li class='c035'>Eye, of flatfish, <a href='#Page_137'>137</a>.</li>
-  <li class='c006'>Fayal Islands, <a href='#Page_124'>124</a>.</li>
-  <li class='c035'>Felidæ, <a href='#Page_308'>308</a>.</li>
-  <li class='c035'><span class='pageno' id='Page_469'>469</span>Felis, <a href='#Page_308'>308</a>.</li>
-  <li class='c035'>Fish, change of color, <a href='#Page_16'>16</a>.</li>
-  <li class='c035'>Fishes, <a href='#Page_7'>7</a>.</li>
-  <li class='c035'>Fishes, secondary sexual character of, <a href='#Page_190'>190</a>.</li>
-  <li class='c035'>Flatfish, <a href='#Page_137'>137</a>, <a href='#Page_138'>138</a>.</li>
-  <li class='c035'>Flatworms, <a href='#Page_417'>417</a>.</li>
-  <li class='c035'>Fleischmann, <a href='#Page_45'>45</a>-<a href='#Page_57'>57</a>.</li>
-  <li class='c035'>Flounders, <a href='#Page_228'>228</a>, <a href='#Page_346'>346</a>, <a href='#Page_347'>347</a>.</li>
-  <li class='c035'>Flowers, <a href='#Page_9'>9</a>, <a href='#Page_17'>17</a>, <a href='#Page_21'>21</a>, <a href='#Page_342'>342</a>, <a href='#Page_399'>399</a>, <a href='#Page_422'>422</a>, <a href='#Page_429'>429</a>.</li>
-  <li class='c035'>Fly, <a href='#Page_428'>428</a>.</li>
-  <li class='c035'>Foot of horse, <a href='#Page_47'>47</a>.</li>
-  <li class='c035'>Forel, <a href='#Page_5'>5</a>.</li>
-  <li class='c035'>Fossil horses, <a href='#Page_52'>52</a>.</li>
-  <li class='c035'>Foxes, <a href='#Page_210'>210</a>, <a href='#Page_410'>410</a>.</li>
-  <li class='c035'>Franqueiros cattle, <a href='#Page_315'>315</a>.</li>
-  <li class='c035'>Frogs, <a href='#Page_193'>193</a>, <a href='#Page_320'>320</a>, <a href='#Page_382'>382</a>, <a href='#Page_405'>405</a>.</li>
-  <li class='c035'>Frogs, cross-fertilization, <a href='#Page_150'>150</a>.</li>
-  <li class='c035'>Fruit, down of, <a href='#Page_133'>133</a>.</li>
-  <li class='c035'>Fundulus, <a href='#Page_16'>16</a>.</li>
-  <li class='c006'>Galton, <a href='#Page_236'>236</a>, <a href='#Page_270'>270</a>-<a href='#Page_272'>272</a>, <a href='#Page_289'>289</a>, <a href='#Page_441'>441</a>.</li>
-  <li class='c035'>Gavials, <a href='#Page_301'>301</a>.</li>
-  <li class='c035'>Geddes and Thompson, <a href='#Page_417'>417</a>, <a href='#Page_423'>423</a>, <a href='#Page_426'>426</a>, <a href='#Page_427'>427</a>.</li>
-  <li class='c035'>Geer, De, <a href='#Page_178'>178</a>.</li>
-  <li class='c035'>Gegenbaur, <a href='#Page_49'>49</a>.</li>
-  <li class='c035'>Gelasimus, <a href='#Page_177'>177</a>.</li>
-  <li class='c035'>Geoffroy St.-Hilaire, <a href='#Page_44'>44</a>, <a href='#Page_67'>67</a>, <a href='#Page_300'>300</a>-<a href='#Page_303'>303</a>.</li>
-  <li class='c035'>Geological evidence, <a href='#Page_39'>39</a>.</li>
-  <li class='c035'>Gerbe, <a href='#Page_429'>429</a>.</li>
-  <li class='c035'>Germinal selection, <a href='#Page_154'>154</a>.</li>
-  <li class='c035'>Gibbon, <a href='#Page_213'>213</a>.</li>
-  <li class='c035'>Gill-clefts, <a href='#Page_62'>62</a>, <a href='#Page_63'>63</a>, <a href='#Page_64'>64</a>, <a href='#Page_73'>73</a>.</li>
-  <li class='c035'>Giraffe, <a href='#Page_6'>6</a>, <a href='#Page_203'>203</a>, <a href='#Page_229'>229</a>, <a href='#Page_248'>248</a>-<a href='#Page_249'>249</a>.</li>
-  <li class='c035'>Glacier, <a href='#Page_28'>28</a>.</li>
-  <li class='c035'>Glowworm, <a href='#Page_23'>23</a>.</li>
-  <li class='c035'>Goat, <a href='#Page_206'>206</a>, <a href='#Page_208'>208</a>.</li>
-  <li class='c035'>Gonionema, <a href='#Page_399'>399</a>.</li>
-  <li class='c035'>Gorilla, <a href='#Page_205'>205</a>.</li>
-  <li class='c035'>Gothic period, <a href='#Page_47'>47</a>, <a href='#Page_48'>48</a>.</li>
-  <li class='c035'>Gould, <a href='#Page_197'>197</a>.</li>
-  <li class='c035'>Graba, <a href='#Page_124'>124</a>, <a href='#Page_125'>125</a>.</li>
-  <li class='c035'>Grafting, <a href='#Page_153'>153</a>.</li>
-  <li class='c035'>Grasshoppers, <a href='#Page_8'>8</a>, <a href='#Page_188'>188</a>.</li>
-  <li class='c035'>Gray, <a href='#Page_126'>126</a>.</li>
-  <li class='c035'>Greyhound, <a href='#Page_134'>134</a>.</li>
-  <li class='c035'>Growth of plants, <a href='#Page_17'>17</a>.</li>
-  <li class='c035'>Guillemots, <a href='#Page_124'>124</a>.</li>
-  <li class='c035'>Guinea-pigs, <a href='#Page_232'>232</a>.</li>
-  <li class='c035'>Günther, <a href='#Page_190'>190</a>.</li>
-  <li class='c035'>Gymnotus, <a href='#Page_132'>132</a>.</li>
-  <li class='c006'>Haeckel, <a href='#Page_48'>48</a>, <a href='#Page_49'>49</a>, <a href='#Page_56'>56</a>, <a href='#Page_70'>70</a>, <a href='#Page_71'>71</a>, <a href='#Page_79'>79</a>, <a href='#Page_80'>80</a>, <a href='#Page_82'>82</a>.</li>
-  <li class='c035'>Hartman, <a href='#Page_187'>187</a>.</li>
-  <li class='c035'>Heart, <a href='#Page_66'>66</a>, <a href='#Page_67'>67</a>.</li>
-  <li class='c035'>Heliconids, <a href='#Page_160'>160</a>.</li>
-  <li class='c035'>Helix, <a href='#Page_344'>344</a>, <a href='#Page_345'>345</a>-<a href='#Page_346'>346</a>.</li>
-  <li class='c035'>Hemiptera, <a href='#Page_181'>181</a>.</li>
-  <li class='c035'><span class='pageno' id='Page_470'>470</span>Heredity, <a href='#Page_270'>270</a>.</li>
-  <li class='c035'>Hermaphroditic animals, <a href='#Page_126'>126</a>.</li>
-  <li class='c035'>Hertwig, O., <a href='#Page_78'>78</a>, <a href='#Page_79'>79</a>, <a href='#Page_80'>80</a>, <a href='#Page_81'>81</a>, <a href='#Page_82'>82</a>, <a href='#Page_83'>83</a>.</li>
-  <li class='c035'>Hertwig, R., <a href='#Page_447'>447</a>.</li>
-  <li class='c035'>Hieracium, <a href='#Page_330'>330</a>, <a href='#Page_331'>331</a>.</li>
-  <li class='c035'>Hildebrand, <a href='#Page_148'>148</a>.</li>
-  <li class='c035'>Hill, <a href='#Page_252'>252</a>.</li>
-  <li class='c035'>Hipparion, <a href='#Page_51'>51</a>.</li>
-  <li class='c035'>Hippeastrum, <a href='#Page_148'>148</a>.</li>
-  <li class='c035'>His, <a href='#Page_71'>71</a>, <a href='#Page_72'>72</a>.</li>
-  <li class='c035'>Holmes, <a href='#Page_72'>72</a>.</li>
-  <li class='c035'>Hornbills, <a href='#Page_219'>219</a>.</li>
-  <li class='c035'>Horns, <a href='#Page_229'>229</a>.</li>
-  <li class='c035'>Horse, <a href='#Page_42'>42</a>, <a href='#Page_224'>224</a>.</li>
-  <li class='c035'>Horse-chestnut, <a href='#Page_24'>24</a>.</li>
-  <li class='c035'>Hothura, <a href='#Page_410'>410</a>.</li>
-  <li class='c035'>Hottentots, <a href='#Page_212'>212</a>.</li>
-  <li class='c035'>Hudson, <a href='#Page_140'>140</a>, <a href='#Page_195'>195</a>, <a href='#Page_409'>409</a>-<a href='#Page_412'>412</a>.</li>
-  <li class='c035'>Humming-birds, <a href='#Page_6'>6</a>, <a href='#Page_197'>197</a>, <a href='#Page_228'>228</a>.</li>
-  <li class='c035'>Hurst, <a href='#Page_75'>75</a>, <a href='#Page_76'>76</a>, <a href='#Page_77'>77</a>, <a href='#Page_78'>78</a>.</li>
-  <li class='c035'>Huxley, <a href='#Page_49'>49</a>, <a href='#Page_156'>156</a>, <a href='#Page_233'>233</a>.</li>
-  <li class='c035'>Hyatt, <a href='#Page_259'>259</a>.</li>
-  <li class='c035'>Hybrids, <a href='#Page_149'>149</a>, <a href='#Page_239'>239</a>.</li>
-  <li class='c035'>Hydatina, <a href='#Page_417'>417</a>.</li>
-  <li class='c035'>Hydroides, <a href='#Page_348'>348</a>.</li>
-  <li class='c035'>Hylobates, <a href='#Page_205'>205</a>.</li>
-  <li class='c035'>Hymenoptera, <a href='#Page_181'>181</a>.</li>
-  <li class='c006'>Ice, <a href='#Page_28'>28</a>.</li>
-  <li class='c035'>Ichneumonidæ, <a href='#Page_181'>181</a>.</li>
-  <li class='c035'>Idioplasm, <a href='#Page_335'>335</a>.</li>
-  <li class='c035'>Immunity, <a href='#Page_13'>13</a>.</li>
-  <li class='c035'>India cattle, <a href='#Page_208'>208</a>.</li>
-  <li class='c035'>Infanticide, <a href='#Page_25'>25</a>.</li>
-  <li class='c035'>Inorganic adaptations, <a href='#Page_26'>26</a>.</li>
-  <li class='c035'>Insectivorous plants, <a href='#Page_10'>10</a>.</li>
-  <li class='c035'>Insects, coloration of,  <a href='#Page_7'>7</a>;
-    <ul>
-      <li>wingless, <a href='#Page_228'>228</a>.</li>
-    </ul>
-  </li>
-  <li class='c035'>Instinct, <a href='#Page_25'>25</a>, <a href='#Page_139'>139</a>, <a href='#Page_140'>140</a>, <a href='#Page_141'>141</a>.</li>
-  <li class='c035'>Irish elk, <a href='#Page_247'>247</a>.</li>
-  <li class='c006'>Jackson, <a href='#Page_260'>260</a>.</li>
-  <li class='c035'>Jaguar, <a href='#Page_209'>209</a>.</li>
-  <li class='c035'>Japanese cock, <a href='#Page_163'>163</a>.</li>
-  <li class='c035'>Jennings, <a href='#Page_395'>395</a>.</li>
-  <li class='c035'>Jonghe, <a href='#Page_314'>314</a>.</li>
-  <li class='c035'>Jordan, <a href='#Page_292'>292</a>.</li>
-  <li class='c035'>Joseph, <a href='#Page_428'>428</a>.</li>
-  <li class='c035'>Junco, <a href='#Page_311'>311</a>.</li>
-  <li class='c006'>Kallima, <a href='#Page_7'>7</a>, <a href='#Page_161'>161</a>, <a href='#Page_162'>162</a>, <a href='#Page_358'>358</a>.</li>
-  <li class='c035'>Kangaroo, <a href='#Page_229'>229</a>, <a href='#Page_351'>351</a>.</li>
-  <li class='c035'>Katydid, <a href='#Page_8'>8</a>.</li>
-  <li class='c035'>Kent, W. Saville, <a href='#Page_191'>191</a>.</li>
-  <li class='c035'>Kidneys, <a href='#Page_66'>66</a>.</li>
-  <li class='c035'>Kielmeyer, <a href='#Page_58'>58</a>.</li>
-  <li class='c035'>Kirby, <a href='#Page_232'>232</a>.</li>
-  <li class='c035'>Kiwi, <a href='#Page_354'>354</a>.</li>
-  <li class='c035'><span class='pageno' id='Page_471'>471</span>Kölreuter, <a href='#Page_149'>149</a>.</li>
-  <li class='c035'>Korschelt, <a href='#Page_428'>428</a>.</li>
-  <li class='c006'>Labidocera, <a href='#Page_393'>393</a>.</li>
-  <li class='c035'>Lamarck, <a href='#Page_146'>146</a>, <a href='#Page_222'>222</a>-<a href='#Page_233'>233</a>.</li>
-  <li class='c035'>Lamarckian factor, <a href='#Page_94'>94</a>, <a href='#Page_205'>205</a>, <a href='#Page_211'>211</a>, <a href='#Page_222'>222</a>, <a href='#Page_458'>458</a>.</li>
-  <li class='c035'>Lang, <a href='#Page_345'>345</a>.</li>
-  <li class='c035'>Law of Biogenesis, <a href='#Page_30'>30</a>.</li>
-  <li class='c035'>Leaf, resemblance to, <a href='#Page_7'>7</a>.</li>
-  <li class='c035'>Leaves, closing of, <a href='#Page_11'>11</a>.</li>
-  <li class='c035'>Leeches, <a href='#Page_417'>417</a>.</li>
-  <li class='c035'>Leguminosæ, <a href='#Page_124'>124</a>.</li>
-  <li class='c035'>Leidy, <a href='#Page_46'>46</a>.</li>
-  <li class='c035'>Length of life, <a href='#Page_20'>20</a>.</li>
-  <li class='c035'>Lenhossek, <a href='#Page_435'>435</a>.</li>
-  <li class='c035'>Leopard, <a href='#Page_209'>209</a>.</li>
-  <li class='c035'>Lepidoptera, <a href='#Page_172'>172</a>.</li>
-  <li class='c035'>Leptothrix, <a href='#Page_320'>320</a>.</li>
-  <li class='c035'>Leucophys, <a href='#Page_442'>442</a>.</li>
-  <li class='c035'>Lichen, <a href='#Page_9'>9</a>.</li>
-  <li class='c035'>Lillie, <a href='#Page_72'>72</a>.</li>
-  <li class='c035'>Limbs of vertebrates, <a href='#Page_46'>46</a>.</li>
-  <li class='c035'>Linaria, <a href='#Page_401'>401</a>.</li>
-  <li class='c035'>Linnæan species, <a href='#Page_83'>83</a>.</li>
-  <li class='c035'>Linnæus, <a href='#Page_191'>191</a>.</li>
-  <li class='c035'>Lion, <a href='#Page_6'>6</a>.</li>
-  <li class='c035'>Lizards, <a href='#Page_7'>7</a>, <a href='#Page_16'>16</a>, <a href='#Page_17'>17</a>, <a href='#Page_193'>193</a>.</li>
-  <li class='c035'>Lobelia, <a href='#Page_148'>148</a>.</li>
-  <li class='c035'>Lobster, <a href='#Page_343'>343</a>.</li>
-  <li class='c035'>Lockwood, <a href='#Page_138'>138</a>.</li>
-  <li class='c035'>Locusts, <a href='#Page_188'>188</a>.</li>
-  <li class='c035'>Loeb, <a href='#Page_383'>383</a>-<a href='#Page_392'>392</a>, <a href='#Page_447'>447</a>.</li>
-  <li class='c035'>Lomaria, <a href='#Page_290'>290</a>.</li>
-  <li class='c035'>Lowell lectures, <a href='#Page_61'>61</a>.</li>
-  <li class='c035'>Lumbriculus, <a href='#Page_15'>15</a>.</li>
-  <li class='c035'>Luminous organs, <a href='#Page_133'>133</a>.</li>
-  <li class='c035'>Lymnæa, <a href='#Page_305'>305</a>, <a href='#Page_322'>322</a>.</li>
-  <li class='c035'>Lythrum, <a href='#Page_363'>363</a>-<a href='#Page_370'>370</a>.</li>
-  <li class='c006'>Machines, <a href='#Page_26'>26</a>, <a href='#Page_27'>27</a>, <a href='#Page_28'>28</a>.</li>
-  <li class='c035'>McIntosh, <a href='#Page_176'>176</a>.</li>
-  <li class='c035'>McNeill, <a href='#Page_204'>204</a>.</li>
-  <li class='c035'>Macropus, <a href='#Page_192'>192</a>.</li>
-  <li class='c035'>Malva, <a href='#Page_401'>401</a>.</li>
-  <li class='c035'>Mammalia, origin, <a href='#Page_54'>54</a>, <a href='#Page_202'>202</a>.</li>
-  <li class='c035'>Man, <a href='#Page_210'>210</a>.</li>
-  <li class='c035'>Marsh, <a href='#Page_49'>49</a>.</li>
-  <li class='c035'>Matthews, <a href='#Page_447'>447</a>.</li>
-  <li class='c035'>Mauchamp, <a href='#Page_315'>315</a>.</li>
-  <li class='c035'>Maupas, <a href='#Page_441'>441</a>, <a href='#Page_442'>442</a>, <a href='#Page_445'>445</a>.</li>
-  <li class='c035'>May-flies, <a href='#Page_19'>19</a>, <a href='#Page_353'>353</a>, <a href='#Page_389'>389</a>.</li>
-  <li class='c035'>Mead, <a href='#Page_72'>72</a>.</li>
-  <li class='c035'>Meckel, <a href='#Page_59'>59</a>, <a href='#Page_60'>60</a>.</li>
-  <li class='c035'>Melanism, <a href='#Page_209'>209</a>.</li>
-  <li class='c035'>Melospiza, <a href='#Page_311'>311</a>.</li>
-  <li class='c035'>Mendel, <a href='#Page_278'>278</a>-<a href='#Page_286'>286</a>, <a href='#Page_433'>433</a>, <a href='#Page_436'>436</a>.</li>
-  <li class='c035'>Mesohippus, <a href='#Page_51'>51</a>.</li>
-  <li class='c035'>Mimosa, <a href='#Page_404'>404</a>.</li>
-  <li class='c035'><span class='pageno' id='Page_472'>472</span>Minnow, <a href='#Page_16'>16</a>.</li>
-  <li class='c035'>Minot, <a href='#Page_433'>433</a>.</li>
-  <li class='c035'>Mirabilis, <a href='#Page_149'>149</a>, <a href='#Page_150'>150</a>.</li>
-  <li class='c035'>Mivart, <a href='#Page_136'>136</a>, <a href='#Page_137'>137</a>.</li>
-  <li class='c035'>Mole, <a href='#Page_1'>1</a>, <a href='#Page_2'>2</a>, <a href='#Page_18'>18</a>, <a href='#Page_227'>227</a>.</li>
-  <li class='c035'>Mole-cricket, <a href='#Page_1'>1</a>, <a href='#Page_2'>2</a>.</li>
-  <li class='c035'>Molothrus, <a href='#Page_140'>140</a>.</li>
-  <li class='c035'>Monkeys, <a href='#Page_207'>207</a>, <a href='#Page_208'>208</a>.</li>
-  <li class='c035'>Mons, Van, <a href='#Page_332'>332</a>.</li>
-  <li class='c035'>Montgomery, <a href='#Page_432'>432</a>.</li>
-  <li class='c035'>Moor-hen, <a href='#Page_453'>453</a>.</li>
-  <li class='c035'>Moquin-Tandon, <a href='#Page_303'>303</a>.</li>
-  <li class='c035'>Morton, Lord, <a href='#Page_238'>238</a>.</li>
-  <li class='c035'>Moschus, <a href='#Page_206'>206</a>.</li>
-  <li class='c035'>Moths, <a href='#Page_184'>184</a>, <a href='#Page_387'>387</a>, <a href='#Page_388'>388</a>.</li>
-  <li class='c035'>Moussu, <a href='#Page_257'>257</a>.</li>
-  <li class='c035'>Mozart, <a href='#Page_218'>218</a>.</li>
-  <li class='c035'>Mulberry, <a href='#Page_313'>313</a>.</li>
-  <li class='c035'>Müller, <a href='#Page_182'>182</a>, <a href='#Page_188'>188</a>.</li>
-  <li class='c035'>Müller, Fritz, <a href='#Page_148'>148</a>.</li>
-  <li class='c035'>Muscles, <a href='#Page_12'>12</a>.</li>
-  <li class='c035'>Mycetes, <a href='#Page_205'>205</a>.</li>
-  <li class='c035'>Myzostomum, <a href='#Page_422'>422</a>.</li>
-  <li class='c006'>Nägeli, <a href='#Page_161'>161</a>, <a href='#Page_325'>325</a>-<a href='#Page_339'>339</a>, <a href='#Page_459'>459</a>.</li>
-  <li class='c035'>Natural selection, <a href='#Page_104'>104</a>-<a href='#Page_107'>107</a>, <a href='#Page_108'>108</a>, <a href='#Page_109'>109</a>, <a href='#Page_110'>110</a>, etc.;
-    <ul>
-      <li>definition of, <a href='#Page_117'>117</a>.</li>
-    </ul>
-  </li>
-  <li class='c035'>Nauplius, <a href='#Page_69'>69</a>.</li>
-  <li class='c035'>Nectar, <a href='#Page_124'>124</a>.</li>
-  <li class='c035'>Nectar-feeding insects, <a href='#Page_126'>126</a>, <a href='#Page_127'>127</a>.</li>
-  <li class='c035'>Nectarines, <a href='#Page_134'>134</a>.</li>
-  <li class='c035'>Negroes, <a href='#Page_212'>212</a>.</li>
-  <li class='c035'>Nematode, number of eggs, <a href='#Page_110'>110</a>.</li>
-  <li class='c035'>Nematus, <a href='#Page_425'>425</a>.</li>
-  <li class='c035'>Nemertian worms, <a href='#Page_176'>176</a>.</li>
-  <li class='c035'>Neo-Lamarckians, <a href='#Page_240'>240</a>, <a href='#Page_259'>259</a>-<a href='#Page_260'>260</a>.</li>
-  <li class='c035'>Nepenthes, <a href='#Page_10'>10</a>.</li>
-  <li class='c035'>Nephela, <a href='#Page_178'>178</a>.</li>
-  <li class='c035'>Nest of birds, <a href='#Page_4'>4</a>, <a href='#Page_407'>407</a>-<a href='#Page_408'>408</a>.</li>
-  <li class='c035'>Neuters, <a href='#Page_142'>142</a>.</li>
-  <li class='c035'>Nicotine, <a href='#Page_13'>13</a>.</li>
-  <li class='c035'>Nostocs, <a href='#Page_320'>320</a>.</li>
-  <li class='c035'>Notochord, <a href='#Page_64'>64</a>, <a href='#Page_65'>65</a>.</li>
-  <li class='c035'>Nussbaum, <a href='#Page_424'>424</a>.</li>
-  <li class='c006'>Ocneria, <a href='#Page_428'>428</a>.</li>
-  <li class='c035'>Œnothera, <a href='#Page_294'>294</a>-<a href='#Page_297'>297</a>.</li>
-  <li class='c035'>Oken, <a href='#Page_56'>56</a>, <a href='#Page_58'>58</a>.</li>
-  <li class='c035'>Old age, <a href='#Page_21'>21</a>, <a href='#Page_25'>25</a>.</li>
-  <li class='c035'>Onites, <a href='#Page_232'>232</a>.</li>
-  <li class='c035'>Onychodromus, <a href='#Page_442'>442</a>.</li>
-  <li class='c035'>Opossum, <a href='#Page_410'>410</a>.</li>
-  <li class='c035'>Organs of little use, <a href='#Page_22'>22</a>.</li>
-  <li class='c035'>“Origin of Species,” <a href='#Page_129'>129</a>.</li>
-  <li class='c035'>Ornithorynchus, <a href='#Page_54'>54</a>.</li>
-  <li class='c035'>Orobanchia, <a href='#Page_330'>330</a>.</li>
-  <li class='c035'>Osborn, <a href='#Page_259'>259</a>.</li>
-  <li class='c035'><span class='pageno' id='Page_473'>473</span>Oscillaria, <a href='#Page_320'>320</a>.</li>
-  <li class='c035'>Ostrich, <a href='#Page_203'>203</a>, <a href='#Page_354'>354</a>.</li>
-  <li class='c035'>Oxalis, <a href='#Page_290'>290</a>, <a href='#Page_404'>404</a>.</li>
-  <li class='c035'>Oxen, <a href='#Page_304'>304</a>.</li>
-  <li class='c035'>Oxide, <a href='#Page_29'>29</a>.</li>
-  <li class='c006'>Packard, <a href='#Page_231'>231</a>, <a href='#Page_260'>260</a>.</li>
-  <li class='c035'>Paludina, <a href='#Page_320'>320</a>, <a href='#Page_322'>322</a>.</li>
-  <li class='c035'>Pangenesis, <a href='#Page_233'>233</a>-<a href='#Page_240'>240</a>.</li>
-  <li class='c035'>Papilio, <a href='#Page_158'>158</a>, <a href='#Page_360'>360</a>,  <a href='#Page_388'>388</a>;
-    <ul>
-      <li>polyxenes, <a href='#Page_3'>3</a>.</li>
-    </ul>
-  </li>
-  <li class='c035'>Paradisea, <a href='#Page_197'>197</a>.</li>
-  <li class='c035'>Paramæcium, <a href='#Page_395'>395</a>-<a href='#Page_398'>398</a>, <a href='#Page_442'>442</a>-<a href='#Page_447'>447</a>.</li>
-  <li class='c035'>Parasitism, <a href='#Page_352'>352</a>-<a href='#Page_353'>353</a>.</li>
-  <li class='c035'>Parker, <a href='#Page_393'>393</a>.</li>
-  <li class='c035'>Parrots, <a href='#Page_6'>6</a>.</li>
-  <li class='c035'>Partridge, <a href='#Page_410'>410</a>.</li>
-  <li class='c035'>Passerella, <a href='#Page_311'>311</a>.</li>
-  <li class='c035'>Passiflora, <a href='#Page_148'>148</a>.</li>
-  <li class='c035'>Pavo, <a href='#Page_317'>317</a>.</li>
-  <li class='c035'>Peach, <a href='#Page_134'>134</a>.</li>
-  <li class='c035'>Peacock, <a href='#Page_200'>200</a>, <a href='#Page_317'>317</a>-<a href='#Page_318'>318</a>.</li>
-  <li class='c035'>Peafowl, <a href='#Page_198'>198</a>.</li>
-  <li class='c035'>Pearson, <a href='#Page_265'>265</a>, <a href='#Page_267'>267</a>, <a href='#Page_268'>268</a>-<a href='#Page_270'>270</a>.</li>
-  <li class='c035'>Peas, <a href='#Page_281'>281</a>-<a href='#Page_286'>286</a>.</li>
-  <li class='c035'>Peckham, <a href='#Page_178'>178</a>, <a href='#Page_408'>408</a>.</li>
-  <li class='c035'>Pelobates, <a href='#Page_421'>421</a>.</li>
-  <li class='c035'>Pflüger, <a href='#Page_424'>424</a>, <a href='#Page_430'>430</a>.</li>
-  <li class='c035'>Phosphorescent organs, <a href='#Page_22'>22</a>, <a href='#Page_133'>133</a>.</li>
-  <li class='c035'>Physa, <a href='#Page_320'>320</a>, <a href='#Page_322'>322</a>.</li>
-  <li class='c035'>Pigeons, selection in, <a href='#Page_102'>102</a>.</li>
-  <li class='c035'>Pipilo, <a href='#Page_311'>311</a>.</li>
-  <li class='c035'>Pisum, <a href='#Page_278'>278</a>.</li>
-  <li class='c035'>Pithecia, <a href='#Page_208'>208</a>.</li>
-  <li class='c035'>Planaria, <a href='#Page_380'>380</a>.</li>
-  <li class='c035'>Planarians, <a href='#Page_394'>394</a>.</li>
-  <li class='c035'>Plants, <a href='#Page_403'>403</a>,  <a href='#Page_415'>415</a>;
-    <ul>
-      <li>color of,  <a href='#Page_24'>24</a>;</li>
-      <li>influence of light, <a href='#Page_17'>17</a>.</li>
-    </ul>
-  </li>
-  <li class='c035'>Plato, <a href='#Page_304'>304</a>.</li>
-  <li class='c035'>Plover, <a href='#Page_202'>202</a>.</li>
-  <li class='c035'>Poisons, <a href='#Page_13'>13</a>, <a href='#Page_14'>14</a>, <a href='#Page_15'>15</a>, <a href='#Page_18'>18</a>, <a href='#Page_20'>20</a>, <a href='#Page_377'>377</a>.</li>
-  <li class='c035'>Polar bear, <a href='#Page_6'>6</a>.</li>
-  <li class='c035'>Pollen, <a href='#Page_2'>2</a>, <a href='#Page_125'>125</a>.</li>
-  <li class='c035'>Polygon, <a href='#Page_262'>262</a>.</li>
-  <li class='c035'>Porthesia, <a href='#Page_389'>389</a>.</li>
-  <li class='c035'>Primula, <a href='#Page_361'>361</a>-<a href='#Page_365'>365</a>.</li>
-  <li class='c035'>Prionidæ, <a href='#Page_182'>182</a>.</li>
-  <li class='c035'>Probosces of insects, <a href='#Page_127'>127</a>.</li>
-  <li class='c035'>Protective coloration, <a href='#Page_5'>5</a>, <a href='#Page_6'>6</a>, <a href='#Page_16'>16</a>, <a href='#Page_158'>158</a>, <a href='#Page_159'>159</a>.</li>
-  <li class='c035'>Proteus, <a href='#Page_227'>227</a>.</li>
-  <li class='c035'>Protohippus, <a href='#Page_51'>51</a>.</li>
-  <li class='c035'>Przibram, <a href='#Page_347'>347</a>.</li>
-  <li class='c035'>Psyche, <a href='#Page_419'>419</a>.</li>
-  <li class='c035'>Ptarmigan, <a href='#Page_5'>5</a>.</li>
-  <li class='c035'>Pyrodes, <a href='#Page_182'>182</a>.</li>
-  <li class='c006'>Quetelet, <a href='#Page_289'>289</a>.</li>
-  <li class='c035'>Quiscalus, major, <a href='#Page_173'>173</a>.</li>
-  <li class='c006'><span class='pageno' id='Page_474'>474</span>Rabbit, Porto Santo, <a href='#Page_316'>316</a>-<a href='#Page_317'>317</a>.</li>
-  <li class='c035'>Rabbits, <a href='#Page_304'>304</a>.</li>
-  <li class='c035'>Rabbits in Australia, <a href='#Page_112'>112</a>.</li>
-  <li class='c035'>Race-horse, <a href='#Page_134'>134</a>.</li>
-  <li class='c035'>Ranunculus, <a href='#Page_305'>305</a>.</li>
-  <li class='c035'>Ray-florets, <a href='#Page_135'>135</a>.</li>
-  <li class='c035'>Rays, electric organs of, <a href='#Page_22'>22</a>.</li>
-  <li class='c035'>Réaumur, <a href='#Page_388'>388</a>.</li>
-  <li class='c035'>Recapitulation theory, <a href='#Page_58'>58</a>-<a href='#Page_83'>83</a>.</li>
-  <li class='c035'>Reduction division, <a href='#Page_432'>432</a>-<a href='#Page_433'>433</a>.</li>
-  <li class='c035'>Regeneration, <a href='#Page_15'>15</a>, <a href='#Page_16'>16</a>, <a href='#Page_27'>27</a>, <a href='#Page_379'>379</a>.</li>
-  <li class='c035'>Regulations, <a href='#Page_27'>27</a>, <a href='#Page_28'>28</a>.</li>
-  <li class='c035'>Reproductive organs, <a href='#Page_19'>19</a>.</li>
-  <li class='c035'>Reptiles, fossil, <a href='#Page_52'>52</a>, <a href='#Page_53'>53</a>.</li>
-  <li class='c035'>Rengger, <a href='#Page_205'>205</a>.</li>
-  <li class='c035'>Rhododendron, <a href='#Page_330'>330</a>.</li>
-  <li class='c035'>Rhynchæa, <a href='#Page_201'>201</a>.</li>
-  <li class='c035'>Riley, <a href='#Page_424'>424</a>.</li>
-  <li class='c035'>Rivers, <a href='#Page_28'>28</a>.</li>
-  <li class='c035'>Robinia, <a href='#Page_404'>404</a>.</li>
-  <li class='c035'>Romanes, <a href='#Page_132'>132</a>, <a href='#Page_250'>250</a>-<a href='#Page_256'>256</a>, <a href='#Page_412'>412</a>.</li>
-  <li class='c035'>Rose, <a href='#Page_307'>307</a>.</li>
-  <li class='c035'>Rothert, <a href='#Page_398'>398</a>.</li>
-  <li class='c035'>Rotifers, <a href='#Page_118'>118</a>, <a href='#Page_353'>353</a>, <a href='#Page_424'>424</a>.</li>
-  <li class='c035'>Roulin, <a href='#Page_304'>304</a>.</li>
-  <li class='c035'>Roundworms, <a href='#Page_176'>176</a>, <a href='#Page_353'>353</a>.</li>
-  <li class='c035'>Rudimentary organs, <a href='#Page_22'>22</a>.</li>
-  <li class='c035'>Ryder, <a href='#Page_260'>260</a>.</li>
-  <li class='c006'>Sacculina, <a href='#Page_353'>353</a>.</li>
-  <li class='c035'>Sachs, <a href='#Page_10'>10</a>.</li>
-  <li class='c035'>Salmon, <a href='#Page_19'>19</a>.</li>
-  <li class='c035'>Salter, <a href='#Page_314'>314</a>.</li>
-  <li class='c035'>Salvin, <a href='#Page_201'>201</a>.</li>
-  <li class='c035'>Saphirina, <a href='#Page_176'>176</a>.</li>
-  <li class='c035'>Savages, <a href='#Page_210'>210</a>.</li>
-  <li class='c035'>Saw-flies, <a href='#Page_425'>425</a>.</li>
-  <li class='c035'>Scarlet tanager, <a href='#Page_198'>198</a>.</li>
-  <li class='c035'>Schaefer, <a href='#Page_244'>244</a>.</li>
-  <li class='c035'>Sclater, <a href='#Page_198'>198</a>.</li>
-  <li class='c035'>Scops, <a href='#Page_312'>312</a>.</li>
-  <li class='c035'>Scott, <a href='#Page_148'>148</a>, <a href='#Page_259'>259</a>.</li>
-  <li class='c035'>Sea-anemone, <a href='#Page_341'>341</a>.</li>
-  <li class='c035'>Sea-urchin, <a href='#Page_341'>341</a>.</li>
-  <li class='c035'>Secondary sexual characters, <a href='#Page_21'>21</a>.</li>
-  <li class='c035'>Selection, <a href='#Page_116'>116</a>.</li>
-  <li class='c035'>Selection, artificial, <a href='#Page_91'>91</a>, <a href='#Page_92'>92</a>, <a href='#Page_96'>96</a>, <a href='#Page_97'>97</a>, <a href='#Page_98'>98</a>.</li>
-  <li class='c035'>Self-fertilization, <a href='#Page_126'>126</a>.</li>
-  <li class='c035'>Semper, <a href='#Page_260'>260</a>.</li>
-  <li class='c035'>Setchel, <a href='#Page_320'>320</a>.</li>
-  <li class='c035'>Sexual characters, secondary, <a href='#Page_372'>372</a>-<a href='#Page_374'>374</a>.</li>
-  <li class='c035'>Sexual selection, <a href='#Page_167'>167</a>.</li>
-  <li class='c035'>Sharp, <a href='#Page_350'>350</a>, <a href='#Page_425'>425</a>.</li>
-  <li class='c035'>Sheep, <a href='#Page_208'>208</a>.</li>
-  <li class='c035'>Sherrington, <a href='#Page_244'>244</a>.</li>
-  <li class='c035'>Shrew mice, <a href='#Page_206'>206</a>.</li>
-  <li class='c035'>Silkworm, <a href='#Page_428'>428</a>, <a href='#Page_447'>447</a>.</li>
-  <li class='c035'><span class='pageno' id='Page_475'>475</span>Silver-bill, <a href='#Page_410'>410</a>.</li>
-  <li class='c035'>Sirex, <a href='#Page_181'>181</a>.</li>
-  <li class='c035'>Siricidæ, <a href='#Page_181'>181</a>.</li>
-  <li class='c035'>Sitaria, <a href='#Page_194'>194</a>.</li>
-  <li class='c035'>Skin, thickening of, <a href='#Page_12'>12</a>, <a href='#Page_13'>13</a>.</li>
-  <li class='c035'>Skull, <a href='#Page_37'>37</a>, <a href='#Page_65'>65</a>.</li>
-  <li class='c035'>Skunk, <a href='#Page_3'>3</a>.</li>
-  <li class='c035'>Slaves of ants, <a href='#Page_141'>141</a>.</li>
-  <li class='c035'>Sleep in plants, <a href='#Page_404'>404</a>.</li>
-  <li class='c035'>Sloth, <a href='#Page_229'>229</a>.</li>
-  <li class='c035'>Snail, <a href='#Page_417'>417</a>.</li>
-  <li class='c035'>Snails, color of, <a href='#Page_23'>23</a>.</li>
-  <li class='c035'>Snakes, <a href='#Page_14'>14</a>, <a href='#Page_193'>193</a>-<a href='#Page_194'>194</a>, <a href='#Page_227'>227</a>.</li>
-  <li class='c035'>Snowy owl, <a href='#Page_6'>6</a>.</li>
-  <li class='c035'>Solenobia, <a href='#Page_419'>419</a>.</li>
-  <li class='c035'>Soles, <a href='#Page_137'>137</a>, <a href='#Page_228'>228</a>.</li>
-  <li class='c035'>Sparassus, <a href='#Page_178'>178</a>.</li>
-  <li class='c035'>Sparrow,  <a href='#Page_200'>200</a>;
-    <ul>
-      <li>English, <a href='#Page_112'>112</a>.</li>
-    </ul>
-  </li>
-  <li class='c035'>Species, <a href='#Page_31'>31</a>, <a href='#Page_32'>32</a>,  <a href='#Page_33'>33</a>;
-    <ul>
-      <li>adaptation for good of,  <a href='#Page_19'>19</a>;</li>
-      <li>sharp separation of, <a href='#Page_131'>131</a>.</li>
-    </ul>
-  </li>
-  <li class='c035'>Spencer, <a href='#Page_240'>240</a>-<a href='#Page_246'>246</a>, <a href='#Page_247'>247</a>, <a href='#Page_290'>290</a>.</li>
-  <li class='c035'>Spermatozoa, <a href='#Page_150'>150</a>, <a href='#Page_430'>430</a>-<a href='#Page_433'>433</a>.</li>
-  <li class='c035'>Sphinx, <a href='#Page_186'>186</a>, <a href='#Page_388'>388</a>.</li>
-  <li class='c035'>Spiders, <a href='#Page_177'>177</a>-<a href='#Page_178'>178</a>, <a href='#Page_179'>179</a>,  <a href='#Page_406'>406</a>;
-    <ul>
-      <li>web, <a href='#Page_3'>3</a>.</li>
-    </ul>
-  </li>
-  <li class='c035'>Spirogyra, <a href='#Page_420'>420</a>.</li>
-  <li class='c035'>Spontaneous variability, <a href='#Page_134'>134</a>.</li>
-  <li class='c035'>Spores, <a href='#Page_322'>322</a>.</li>
-  <li class='c035'>Squilla, <a href='#Page_177'>177</a>.</li>
-  <li class='c035'>Squirrels, <a href='#Page_210'>210</a>.</li>
-  <li class='c035'>Stag-beetle, <a href='#Page_179'>179</a>.</li>
-  <li class='c035'>Stags, <a href='#Page_203'>203</a>-<a href='#Page_204'>204</a>, <a href='#Page_219'>219</a>.</li>
-  <li class='c035'>Sterility, <a href='#Page_147'>147</a>-<a href='#Page_152'>152</a>.</li>
-  <li class='c035'>Strasburger, <a href='#Page_395'>395</a>.</li>
-  <li class='c035'>Stridulating organs, <a href='#Page_188'>188</a>, <a href='#Page_189'>189</a>.</li>
-  <li class='c035'>Struggle for existence, <a href='#Page_109'>109</a>, <a href='#Page_110'>110</a>.</li>
-  <li class='c035'>Stylonychia, <a href='#Page_442'>442</a>.</li>
-  <li class='c035'>Survival of the fittest, <a href='#Page_107'>107</a>, <a href='#Page_108'>108</a>, <a href='#Page_109'>109</a>, <a href='#Page_117'>117</a>.</li>
-  <li class='c035'>Sutton, <a href='#Page_432'>432</a>.</li>
-  <li class='c035'>Swallow, <a href='#Page_115'>115</a>.</li>
-  <li class='c035'>Sweating, <a href='#Page_12'>12</a>.</li>
-  <li class='c006'>Tadpole, <a href='#Page_321'>321</a>, <a href='#Page_428'>428</a>.</li>
-  <li class='c035'>Tail, <a href='#Page_2'>2</a>.</li>
-  <li class='c035'>Tanager, <a href='#Page_6'>6</a>.</li>
-  <li class='c035'>Tapeworm,  <a href='#Page_353'>353</a>;
-    <ul>
-      <li>number of eggs, <a href='#Page_110'>110</a>.</li>
-    </ul>
-  </li>
-  <li class='c035'>Taraxacum, <a href='#Page_305'>305</a>.</li>
-  <li class='c035'>Tear-sacs, <a href='#Page_206'>206</a>.</li>
-  <li class='c035'>Teeth, bird’s, <a href='#Page_67'>67</a>, <a href='#Page_68'>68</a>.</li>
-  <li class='c035'>Telegony, <a href='#Page_95'>95</a>, <a href='#Page_234'>234</a>, <a href='#Page_237'>237</a>, <a href='#Page_238'>238</a>, <a href='#Page_239'>239</a>.</li>
-  <li class='c035'>Tenthredinidæ, <a href='#Page_181'>181</a>, <a href='#Page_425'>425</a>.</li>
-  <li class='c035'>Termite, number of eggs, <a href='#Page_110'>110</a>.</li>
-  <li class='c035'>Termitidæ, <a href='#Page_350'>350</a>.</li>
-  <li class='c035'>Thrush, <a href='#Page_115'>115</a>.</li>
-  <li class='c035'>Tipulæ, <a href='#Page_188'>188</a>.</li>
-  <li class='c035'>Toad, <a href='#Page_7'>7</a>.</li>
-  <li class='c035'>Torpedo, <a href='#Page_132'>132</a>.</li>
-  <li class='c035'>Towle, <a href='#Page_392'>392</a>.</li>
-  <li class='c035'><span class='pageno' id='Page_476'>476</span>Transitional forms, <a href='#Page_42'>42</a>.</li>
-  <li class='c035'>Transmutation theory, <a href='#Page_31'>31</a>, <a href='#Page_34'>34</a>.</li>
-  <li class='c035'>Traquair, <a href='#Page_138'>138</a>.</li>
-  <li class='c035'>Treadwell, <a href='#Page_72'>72</a>.</li>
-  <li class='c035'>Treat, <a href='#Page_424'>424</a>.</li>
-  <li class='c035'>Tree-frogs, <a href='#Page_7'>7</a>.</li>
-  <li class='c035'>Trichina, <a href='#Page_353'>353</a>.</li>
-  <li class='c035'>Trifolium, <a href='#Page_404'>404</a>.</li>
-  <li class='c035'>Triton, <a href='#Page_193'>193</a>.</li>
-  <li class='c035'>Turkeys, <a href='#Page_314'>314</a>.</li>
-  <li class='c035'>Turnix, <a href='#Page_201'>201</a>, <a href='#Page_202'>202</a>.</li>
-  <li class='c035'>Turtles, <a href='#Page_193'>193</a>.</li>
-  <li class='c006'>Umbelliferæ, <a href='#Page_135'>135</a>.</li>
-  <li class='c035'>Uria lacrymans, <a href='#Page_124'>124</a>.</li>
-  <li class='c035'>Utricularia, <a href='#Page_10'>10</a>,</li>
-  <li class='c006'>Vanessa, <a href='#Page_360'>360</a>.</li>
-  <li class='c035'>Variability, <a href='#Page_92'>92</a>, <a href='#Page_93'>93</a>, <a href='#Page_95'>95</a>, <a href='#Page_96'>96</a>, <a href='#Page_318'>318</a>-<a href='#Page_319'>319</a>.</li>
-  <li class='c035'>Variation, <a href='#Page_261'>261</a>, <a href='#Page_340'>340</a>.</li>
-  <li class='c035'>Variation, fluctuating, <a href='#Page_100'>100</a>, <a href='#Page_118'>118</a>, <a href='#Page_123'>123</a>.</li>
-  <li class='c035'>Variation under domestication, <a href='#Page_136'>136</a>.</li>
-  <li class='c035'>Varieties, <a href='#Page_106'>106</a>, <a href='#Page_107'>107</a>, <a href='#Page_148'>148</a>.</li>
-  <li class='c035'>Varigny, De, <a href='#Page_303'>303</a>-<a href='#Page_306'>306</a>, <a href='#Page_314'>314</a>-<a href='#Page_315'>315</a>, <a href='#Page_322'>322</a>.</li>
-  <li class='c035'>Venus fly-trap, <a href='#Page_9'>9</a>.</li>
-  <li class='c035'>Verbascum, <a href='#Page_148'>148</a>, <a href='#Page_149'>149</a>.</li>
-  <li class='c035'>Vertebrates, evolution of, <a href='#Page_40'>40</a>, <a href='#Page_45'>45</a>.</li>
-  <li class='c035'>Vilmorin, <a href='#Page_303'>303</a>, <a href='#Page_314'>314</a>.</li>
-  <li class='c035'>Vinson, <a href='#Page_178'>178</a>.</li>
-  <li class='c035'>Vries, De, <a href='#Page_97'>97</a>, <a href='#Page_278'>278</a>, <a href='#Page_289'>289</a>-<a href='#Page_298'>298</a>, <a href='#Page_340'>340</a>.</li>
-  <li class='c035'>Vulpine, <a href='#Page_209'>209</a>.</li>
-  <li class='c006'>Wallace, <a href='#Page_7'>7</a>, <a href='#Page_162'>162</a>, <a href='#Page_186'>186</a>, <a href='#Page_202'>202</a>, <a href='#Page_221'>221</a>, <a href='#Page_249'>249</a>.</li>
-  <li class='c035'>Walrus, <a href='#Page_203'>203</a>.</li>
-  <li class='c035'>Walsh, <a href='#Page_181'>181</a>.</li>
-  <li class='c035'>Walther, <a href='#Page_59'>59</a>.</li>
-  <li class='c035'>Wasp, <a href='#Page_3'>3</a>, <a href='#Page_5'>5</a>, <a href='#Page_408'>408</a>, <a href='#Page_409'>409</a>.</li>
-  <li class='c035'>Waterton, <a href='#Page_198'>198</a>.</li>
-  <li class='c035'>Web, spider’s, <a href='#Page_3'>3</a>, <a href='#Page_4'>4</a>.</li>
-  <li class='c035'>Weir, <a href='#Page_171'>171</a>.</li>
-  <li class='c035'>Weismann, <a href='#Page_154'>154</a>-<a href='#Page_166'>166</a>, <a href='#Page_441'>441</a>, <a href='#Page_448'>448</a>-<a href='#Page_450'>450</a>.</li>
-  <li class='c035'>Westwood, <a href='#Page_188'>188</a>.</li>
-  <li class='c035'>Whale, <a href='#Page_227'>227</a>, <a href='#Page_301'>301</a>.</li>
-  <li class='c035'>Wilson, E. B., <a href='#Page_72'>72</a>.</li>
-  <li class='c035'>Wing of bat, <a href='#Page_2'>2</a>.</li>
-  <li class='c035'>Wolf, <a href='#Page_308'>308</a>, <a href='#Page_376'>376</a>.</li>
-  <li class='c035'>Wolves, <a href='#Page_412'>412</a>.</li>
-  <li class='c035'>Women, <a href='#Page_210'>210</a>.</li>
-  <li class='c035'>Woodpecker, <a href='#Page_228'>228</a>.</li>
-  <li class='c035'>Wounds, healing of, <a href='#Page_15'>15</a>.</li>
-  <li class='c006'>Yarrell, <a href='#Page_138'>138</a>.</li>
-  <li class='c035'>Yung, <a href='#Page_424'>424</a>, <a href='#Page_436'>436</a>.</li>
-  <li class='c006'>Zebu cattle, <a href='#Page_208'>208</a>.</li>
-  <li class='c035'>Zeleny, <a href='#Page_348'>348</a>.</li>
-  <li class='c035'>Zoea, <a href='#Page_69'>69</a>, <a href='#Page_70'>70</a>.</li>
-</ul>
-<div class='pbb'>
- <hr class='pb c006' />
-<p>&nbsp;</p>
-</div>
-<p class='c010'>&nbsp;</p>
-<div class='tnbox'>
-
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-    <li>Transcriber’s Notes:
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-        form was found in this book.
-        </li>
-        <li>The cover image was created by the transcriber and is placed in
-        the public domain.
-        </li>
-      </ul>
-    </li>
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