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Title: Studies in the Theory of Descent (Volumes 1 and 2) Author: August Weismann Commentator: Charles Darwin Translator: Raphael Meldola Release Date: January 2, 2015 [EBook #47849] Language: English Character set encoding: UTF-8 *** START OF THIS PROJECT GUTENBERG EBOOK STUDIES IN THEORY OF DESCENT *** Produced by Marilynda Fraser-Cunliffe, Charlie Howard, and the Online Distributed Proofreading Team at http://www.pgdp.net (This file was produced from images generously made available by The Internet Archive) Transcriber’s notes The Fourth Edition of this work originally was published in two volumes; they have been combined in this eBook. The content of Volume II, including its Title page, begins after page 400. STUDIES IN THE THEORY OF DESCENT. LONDON: PRINTED BY GILBERT AND RIVINGTON, LIMITED, ST. JOHN’S SQUARE, STUDIES IN THE THEORY OF DESCENT BY DR. AUGUST WEISMANN PROFESSOR IN THE UNIVERSITY OF FREIBURG WITH NOTES AND ADDITIONS BY THE AUTHOR TRANSLATED AND EDITED, WITH NOTES, BY RAPHAEL MELDOLA, F.C.S. LATE VICE-PRESIDENT OF THE ENTOMOLOGICAL SOCIETY OF LONDON WITH A PREFATORY NOTICE BY C H A R L E S D A R W I N , L L . D . , F. R . S . Author of “The Origin of Species,” &c. IN TWO VOLUMES VOL. I. WITH EIGHT COLOURED PLATES London: SAMPSON LOW, MARSTON, SEARLE, & RIVINGTON CROWN BUILDINGS, 188, FLEET STREET 1882 [All rights reserved.] PREFATORY NOTICE. The present work by Professor Weismann, well known for his profound embryological investigations on the Diptera, will appear, I believe, to every naturalist extremely interesting and well deserving of careful study. Any one looking at the longitudinal and oblique stripes, often of various and bright colours, on the caterpillars of Sphinx-moths, would naturally be inclined to doubt whether these could be of the least use to the insect; in the olden time they would have been called freaks of Nature. But the present book shows that in most cases the colouring can hardly fail to be of high importance as a protection. This indeed was proved experimentally in one of the most curious instances described, in which the thickened anterior end of the caterpillar bears two large ocelli or eye-like spots, which give to the creature so formidable an appearance that birds were frightened away. But the mere explanation of the colouring of these caterpillars is but a very small part of the merit of the work. This mainly consists in the light thrown on the laws of variation and of inheritance by the facts given and discussed. There is also a valuable discussion on classification, as founded on characters displayed at different ages by animals belonging to the same group. Several distinguished naturalists maintain with much confidence that organic beings tend to vary and to rise in the scale, independently of the conditions to which they and their progenitors have been exposed; whilst others maintain that all variation is due to such exposure, though the manner in which the environment acts is as yet quite unknown. At the present time there is hardly any question in biology of more importance than this of the nature and causes of variability, and the reader will find in the present work an able discussion on the whole subject, which will probably lead him to pause before he admits the existence of an innate tendency to perfectibility. Finally, whoever compares the discussions in this volume with those published twenty years ago on any branch of Natural History, will see how wide and rich a field for study has been opened up through the principle of Evolution; and such fields, without the light shed on them by this principle, would for long or for ever have remained barren. Charles Darwin. v vi TRANSLATOR’S PREFACE. In offering to English readers this translation of Professor Weismann’s well-known “Studies in the Theory of Descent,” the main part of which is devoted to entomological subjects, I have been actuated by the desire of placing in the hands of English naturalists one of the most complete of recent contributions to the theory of Evolution as applied to the elucidation of certain interesting groups of facts offered by the insect world. Although many, if not most, working naturalists are already familiar with the results of Dr. Weismann’s researches, of which abstracts have from time to time appeared in English and American scientific journals, I nevertheless believe that a study of the complete work, by enabling the reader to follow closely the detailed lines of reasoning and methods of experiment employed by the author, will be found to be of considerable value to those biologists who have not been able to follow the somewhat difficult phraseology of the original. It is not my intention, nor would it be becoming in me to discuss here the merits of the results arrived at by the minute and laborious investigations with which Dr. Weismann has for many years occupied himself. I may however point out that before the appearance of the present work the author, in addition to his well-known papers on the embryology and development of insects, had published two valuable contributions to the theory of descent, viz. one entitled “Über die Berechtigung der Darwin’schen Theorie” (1868), and another “Über den Einfluss der Isolirung auf die Artbildung” (1872). These works, which are perhaps not so well known in this country as could be desired, might be advantageously studied in connection with the present volume wherein they are frequently referred to. Since every new contribution to science is a fresh starting-point for future work, I may venture without any great breach of propriety to dwell briefly upon one or two of the main points which appear to me to be suggested by Prof. Weismann’s investigations. Although the causes of Glacial Epochs is a subject which has much occupied the attention of geologists and physiographers, the question is one of such great complexity that it cannot yet be regarded as finally settled. But apart from the question of causes—a most able discussion of which is given by the author of “Island Life”—there is not the least doubt that at no very distant geological period there occurred such an epoch, which, although intermittent, was of considerable duration. The last great geological event which our globe experienced was in fact this Ice Age, and the pure naturalist has not hitherto attributed in my opinion sufficient importance to the direct modifying effects of this prolonged period of cold. It is scarcely possible that such a vast climatic change as that which came on at the close of the Pliocene Period should have left no permanent effect upon our present fauna and flora, all the species of which have survived from the glacial age. The great principle of Natural Selection leads us to see how pre-glacial forms may have become adapted to the new climatic conditions (which came on gradually) by the “survival of the fittest” or “indirect equilibration.” The influence of the last Glacial Epoch as a factor in determining the present geographical distribution of animals and plants has already been amply treated of by many writers since the broad paths were traced out by Darwin, Lyell, and Wallace. The last-named author has indeed quite recently discussed this branch of the subject most exhaustively in his work on “Island Life” above mentioned. The reference of a particular group of phenomena—the seasonal dimorphism of butterflies—to the direct action of the Glacial Period and the subsequent influence of the ameliorating climate, was however the first step taken in this neglected field by the author of the present work in 1875. It is possible, and indeed probable, that future researches will show that other characters among existing species can be traced to the same causes. The great generalizations of embryology, which science owes so largely to the researches of Karl Ernst von Baer, bear to the theory of descent the same relations that Kepler’s laws bear to the theory of gravitation. These last-named laws are nothing more than generalized statements of the motions of the planets, which were devoid of meaning till the enunciation of the theory of gravitation. Similarly the generalized facts of embryology are meaningless except in the light of the theory of descent. It has now become a recognized principle in biology that animals in the course of their development from the ovum recapitulate more or less completely the phases through which their ancestors have passed. The practical application of this principle to the determination of the line of descent of any species or group of species is surrounded by difficulties, but attempts have been made of late years—as by Haeckel in his Gastrula theory—to push the law to its legitimate consequences. In this country Sir John Lubbock, in 1874, appealed to the embryonic characters of larvæ in support of his views on the origin of insects. To the author of this work (1876) is due the first application of the principle of Ontogeny as revealing the origin of the markings of caterpillars. A most valuable method of research is thus opened up, and entomologists should not be long in availing themselves of it. Our knowledge of the subject of larval development in Lepidoptera is still most imperfect, and it cannot as yet be foreseen to what extent the existing notions of classification in this much-studied order may have to be modified when a minute study of the Comparative Ontogeny of larval characters, worked out as completely as possible for each family, has enabled a true genealogical system to be drawn up. The extent to which such a larval genealogy would coincide with our present classification cannot now be decided, but he who approaches this fruitful line of inquiry in the true spirit of an investigator, will derive much instruction from Prof. Weismann’s remarks on “Phyletic Parallelism in Metamorphic Species.” The affinities of the larger groups among Lepidoptera would most probably be made out once and for ever if systematists would devote more time to observation in this field, and to the co-ordination and working up of the numerous data scattered throughout the vast number of entomological publications. The doctrine of development by no means implies, as has sometimes been maintained, a continuous advancement in organization. Although the scale of organic nature has continued to rise as a whole, cases may occasionally occur where a lower grade of organization is better adapted to certain conditions of life. This principle of “degeneration” was recognized by Darwin as early as in the first edition of the “Origin of Species;” it was soon perceived to be applicable to the phenomenon of parasitism, and was first definitely formulated by Dr. Anton Dohrn in 1875. In a lecture delivered before the British Association at Sheffield in 1879, Prof. E. Ray Lankester ascribed to “degeneration” a distinct and well-defined function in the theory of descent. Dr. Weismann’s explanation of the vii viii ix x xi xii transformation of Axolotl given in the fourth essay of this work, may be regarded as a special contribution to this phase of Darwinism. Whilst refuting the idea held by certain naturalists, that such cases are arguments against the origin of species by the accumulation of minute variations, and prove the possibility of development per saltum, the theory here advanced (that Siredon at a former period existed at a higher stage of development as Amblystoma, and that the observed cases of metamorphosis are but reversions to this lost higher stage) suggests the question whether there may not still be in existence many other degenerated forms quite unsuspected by naturalists. Many of the opponents of Evolution have from time to time denounced this doctrine as leading to “pure materialism,” a denunciation which may appear somewhat alarming to the uninitiated, but which may not seem fraught with any serious consequences to those who have followed the course of philosophical speculation during the last few years. Those who attack the doctrine on this ground will however do well to consider Prof. Weismann’s views set forth in the last essay in this volume, before hastily assuming that the much dreaded “materialism” is incompatible with any other conception of Nature. The small amount of leisure time which I have been able to devote to the translation of this volume has delayed its completion considerably beyond the anticipated time, and it was with a view to meeting this difficulty that I departed from the original form of the German edition and issued it in parts. Owing to the extremely idiomatic character of the German text, I have throughout endeavoured to preserve only the author’s meaning, regardless of literal translation or of the construction of the original. In some few cases, however, I have intentionally adopted literal translations of certain technical expressions which might, I think, be advantageously introduced into our biological vocabularies. Some alterations have been made in the original text by the author for the present edition, and many new notes have been added. For those bearing my initials I am alone responsible. It gives me much pleasure in conclusion to express my thanks to Dr. Weismann, not only for the readily given permission to publish an English translation of his work, but also for much valuable assistance during the execution of the task. The author has been good enough to superintend the drawing of the plates for this edition, and he has also read through the greater part of the manuscript. From Mr. Darwin also I have received much kindly encouragement, and among entomologists I am especially indebted to Mr. W. H. Edwards of West Virginia, for his valuable additions to the first part. To my friends Mr. A. G. Butler, Mr. Roland Trimen, and Mr. F. Moore, I owe acknowledgments for much useful information concerning the caterpillars of exotic Sphingidæ, which I have incorporated in the notes and appendices, and Mr. W. S. Simpson has given me occasional advice in the translation of some of the more difficult passages. R. M. London, November, 1881. PREFACE TO THE ENGLISH EDITION. With the appearance of Charles Darwin’s work “On the Origin of Species,” in the year 1858, there commenced a new era in biology. Weary of the philosophical speculations which, at the beginning of this century, had at first been started with moderation but had afterwards been pushed to excess, biologists had entirely let drop all general questions and confined themselves to special investigations. The consideration even of general questions had quite fallen into disuse, and the investigation of mere details had led to a state of intellectual shortsightedness, interest being shown only for that which was immediately in view. Immense numbers of detailed facts were thus accumulated, but they could not possibly be mastered; the intellectual bond which should have bound them together was wanting. But all this was changed in a short time. At first only single and mostly the younger naturalists fell in with the new theory of development proclaimed by Darwin, but the conviction soon became general that this was the only scientifically justifiable hypothesis of the origin of the organic world. The materials accumulated in all the provinces of biology now for the first time acquired a deeper meaning and significance; unexpected inter-relations revealed themselves as though spontaneously, and what formerly appeared as unanswerable enigmas now became clear and comprehensible. Since that time what a vast modification has the subject of animal embryology undergone; how full of meaning appear the youngest developmental stages, how important the larvæ; how significant are rudimentary organs; what department of biology has not in some measure become affected by the modifying influence of the new ideas! But the doctrine of development not only enabled us to understand the facts already existing; it gave at the same time an impetus to the acquisition of unforeseen new ones. If at the present day we glance back at the development of the biological sciences within the last twenty years, we must be astonished both at the enormous array of new facts which have been evoked by the theory of development, and by the immense series of special investigations which have been called forth by this doctrine. But while the development theory for by far the greater majority of these investigations served as a light which more and more illuminated the darkness of ignorance, there appeared at the same time some other researches in which this doctrine itself became the object of investigation, and which were undertaken with a view to establish it more securely. To this latter class of work belong the “Studies” in the present volume. xiii xiv xv xvi xvii It will perhaps be objected that the theory of descent has already been sufficiently established by Darwin and Wallace. It is true that their newly-discovered principle of selection is of the very greatest importance, since it solves the riddle as to how that which is useful can arise in a purely mechanical way. Nor can the transforming influence of direct action, as upheld by Lamarck, be called in question, although its extent cannot as yet be estimated with any certainty. The secondary modifications which Darwin regards as the consequence of a change in some other organ must also be conceded. But are these three factors actually competent to explain the complete transformation of one species into another? Can they transform more than mere single characters or groups of characters? Can we consider them as the sole causes of the regular phenomena of the development of the races of animals and plants? Is there not perhaps an unknown force underlying these numberless developmental series as the true motor power—a “developmental force” urging species to vary in certain directions and thus calling into existence the chief types and sub-types of the animal and vegetable kingdoms? At the time these “Studies” first appeared (1875) they had been preceded by a whole series of attempts to introduce into science such an unknown power. The botanists, Nägeli and Askenasy, had designated it the “perfecting principle” or the “fixed direction of variation;” Kolliker as the “law of creation;” the philosophers, Von Hartmann and Huber, as the “law of organic development,” and also “the universal principle of organic nature.” It was thus not entirely superfluous to test the capabilities of the known factors of transformation. We had here before us a question of the highest importance—a question which entered deeply into all our general notions, not only of the organic world, but of the universe as a whole. This question—does there exist a special “developmental force”?—obviously cannot be decided by mere speculation; it must also be attempted to approach it by the inductive method. The five essays in this volume are attempts to arrive, from various sides, somewhat nearer at a solution of the problem indicated. The first essay on the “Seasonal Dimorphism of Butterflies” is certainly but indirectly connected with the question; it is therein attempted to discover the causes of this remarkable dimorphism, and by this means to indicate at the same time the extent of one of the transforming factors with reference to a definite case. The experiments upon which I base my views are not as numerous as I could desire, and if I were now able to repeat them they would be carried out more exactly than was possible at that time, when an experimental basis had first to be established. In spite of this, the conclusions to which I was led appear to be on the whole correct. That admirable and most conscientious observer of the North American butterflies, Mr. W. H. Edwards, has for many years experimented with American species in a manner similar to that which I employed for European species, and his results, which are published here in Appendix II. to the first essay, contain nothing as far as I can see which is not in harmony with my views. Many new questions suggest themselves, however, and it would be a grateful task if some entomologist would go further into these investigations. The second essay directly attacks the main problem above indicated. It treats of the “Origin of the Markings of Caterpillars,” and is to some extent a test of the correctness and capabilities of the Darwinian principles; it attempts to trace the differences in form in a definite although small group entirely to known factors. Why the markings of caterpillars have particularly been chosen for this purpose will appear for two reasons. The action of Natural Selection, on account of the nature of this agency, can only be exerted on those characters which are of biological importance. As it was to be tested whether, besides Natural Selection and the direct action of external conditions, together with the correlative results of these two factors, there might not lie concealed in the organism some other unknown transforming power, it was desirable to select for the investigation a group of forms which, if not absolutely excluding, nevertheless appeared possibly to restrict, the action of one of the two known factors of transformation, that of Natural Selection; a group of forms consisting essentially of so-called “purely morphological” characters, and not of those the utility of which was obvious, and of which the origin by means of Natural Selection was both possible and probable ab initio. Now, although the colouring can readily be seen to be of value to the life of its possessors, this is not the case with the quite independent markings of caterpillars; excepting perhaps those occasional forms of marking which have been regarded as special cases of protective resemblance. The markings of caterpillars must in general be considered as “purely morphological” characters, i.e. as characters which we do not know to be of any importance to the life of the species, and which cannot therefore be referred to Natural Selection. The most plausible explanation of these markings might have been that they were to be regarded as ornaments, but this view precludes the possibility of referring them either to Natural Selection or to the influence of direct changes in the environment. The markings of caterpillars offered also another advantage which cannot be lightly estimated; they precluded from the first any attempt at an explanation by means of Sexual Selection. Although I am strongly convinced of the activity and great importance of this last process of selection, its effects cannot be estimated in any particular case, and the origin of a cycle of forms could never be clearly traced to its various factors, if Sexual Selection had also to be taken into consideration. Thus, we may fairly suppose that many features in the markings of butterflies owe their origin to Sexual Selection, but we are, at least at present, quite in the dark as to how many and which of these characters can be traced to this factor. An investigation such as that which has been kept in view in this second essay would have been impracticable in the case of butterflies, as well as in the analogous case of the colouring and marking of birds, because it would have always been doubtful whether a character which did not appear to be attributable to any of the other transforming factors, should not be referred to Sexual Selection. It would have been impossible either to exclude or to infer an unknown developmental force, since we should have had to deal with two unknowns which could in no way be kept separate. We escape this dilemma in the markings of caterpillars, because the latter do not propagate in this state. If the phenomena are not here entirely referable to Natural Selection and the direct action of the environment—if there remains an inexplicable residue, this cannot be referred to Sexual Selection, but to some as yet unknown power. But it is not only in this respect that caterpillars offer especial advantages. If it is to be attempted to trace transformations in form to xviii xix xx xxi xxii the action of the environment, an exact knowledge of this environment is in the first place necessary, i.e. a precise acquaintance with the conditions of life under the influence of which the species concerned exist. With respect to caterpillars, our knowledge of the life conditions is certainly by no means as complete as might be supposed, when we consider that hundreds of Lepidopterists have constantly bred and observed them during a most extended period. Much may have been observed, but it has not been thought worthy of publication; much has also been published, but so scattered and disconnected and at the same time of such unequal credibility, that a lifetime would be required to sift and collect it. A comprehensive biology of caterpillars, based on a broad ground, is as yet wanting, although such a labour would be both most interesting and valuable. Nevertheless, we know considerably more of the life of caterpillars than of any other larvæ, and as we are also acquainted with an immense number of species and are able to compare their life and the phenomena of their development, the subject of the markings of caterpillars must from this side also appear as the most favourable for the problem set before us. To this must be added as a last, though not as the least, valuable circumstance, that we have here preserved to us in the development of the individual a fragment of the history of the species, so that we thus have at hand a means of following the course which the characters to be traced to their causes—the forms of marking—have taken during the lapse of thousands of years. If with reference to the question as to the precise conditions of life in caterpillars I was frequently driven to my own observations, it was because I found as good as no previous work bearing upon this subject. It was well known generally that many caterpillars were differently marked and coloured when young to what they were when old; in some very striking cases brief notices of this fact are to be found in the works,1 more especially, of the older writers, and principally in that of the excellent observer Rösel von Rosenhof, the Nuremberg naturalist and miniature painter. In no single case, however, do the available materials suffice when we have to draw conclusions respecting the phyletic development. We distinctly see here how doubtful is the value of those observations which are made, so to speak, at random, i.e. without some definite object in view. Many of these observations may be both good and correct, but they are frequently wanting precisely in that which would make them available for scientific purposes. Thus everything had to be established de novo, and for this reason the investigations were extended over a considerable number of years, and had to be restricted to a small and as sharply defined a group as possible—a group which was easily surveyed, viz. that of the Hawk-moths or Sphinges. Since the appearance of the German edition of this work many new observations respecting the markings of caterpillars have been published, such, for example, as those of W. H. Edwards and Fritz Müller. I have, however, made but little use of them here, as I had no intention of giving anything like a complete ontogeny of the markings in all caterpillars: larval markings were with me but means to an end, and I wished only to bring together such a number of facts as were necessary for drawing certain general conclusions. It would indeed be most interesting to extend such observations to other groups of Lepidoptera. The third essay also, for similar reasons, is based essentially upon the same materials, viz. the Lepidoptera. It is therein attempted to approach the general problem—does there or does there not exist an internal transforming force?—from a quite different and, I may say, opposite point of view. The form-relationships of Lepidoptera in their two chief stages of development, imago and larva, are therein analysed, and by an examination of the respective forms it has been attempted to discover the nature of the causes which have led thereto. I may be permitted to say that the fact here disclosed of a different morphological, with the same genealogical relationship, appears to me to be of decided importance. The agreement of the conclusions following therefrom with the results of the former investigation has, at least in my own mind, removed the last doubts as to the correctness of the latter. The fourth and shortest essay on the “Transformation of the Axolotl into Amblystoma,” starts primarily with the intention of showing that cases of sudden transformation are no proof of per saltum development. When this essay first appeared the view was still widely entertained that we had here a case proving per saltum development. That this explanation was erroneous is now generally admitted, but I believe that those who suppose that we have here to deal with some quite ordinary phenomenon which requires no explanation, now go too far towards the other extreme. The term “larval reproduction” is an expression, but no explanation; we have therefore to attempt to find out the true interpretation, but whether the one which I have given is correct must be judged of by others. These four essays lead up to a fifth and concluding one “On the Mechanical Conception of Nature.” Whilst the results obtained are here summed up, it is attempted to form them into a philosophical conception of Nature and of the Universe. It will be thought by many that this should have been left to professed philosophers, and I readily admit that I made this attempt with some misgiving. Two considerations, however, induced me to express here my own views. The first was that the facts of science are frequently misunderstood, or at any rate not estimated at their true value, by philosophers;2 the second consideration was, that even certain naturalists and certainly very many non-naturalists, turn distrustfully from the results of science, because they fear that these would infallibly lead to a view of the Universe which is to them unacceptable, viz. the materialistic view. With regard to the former I wished to show that the views of the development of organic Nature inaugurated by Darwin and defended in this work are certainly correctly designated mechanical; with reference to the latter I wished to prove that such a mechanical conception of the organic world and of Nature in general, by no means leads merely to one single philosophical conception of Nature, viz. to Materialism, but that on the contrary it rather admits of legitimate development in a quite different manner. Thus in these last four essays much that appears heterogeneous will be found in close association, viz. scientific details and general philosophical ideas. In truth, however, these are most intimately connected, and the one cannot dispense with the other. As the detailed investigations of the three essays find their highest value in the general considerations of the fourth, and were indeed only possible by constantly keeping this end in view, so the general conclusions could only grow out of the results of the special investigations as out of a solid foundation. Had the new materials here brought together been already known, the reader would certainly have been spared the trouble of going into the details of special scientific research. But as matters stood it was indispensable that the facts should be examined into and established even down to the most trifling details. The essay “On the Origin of the Markings of Caterpillars” especially, had obviously to commence with the sifting and compilation of extensive morphological materials. xxiii xxiv xxv xxvi xxvii xxviii August Weismann. Freiburg in Baden, November, 1881. CONTENTS. Part I. ON THE SEASONAL DIMORPHISM OF BUTTERFLIES. I. The Origin and Significance of Seasonal Dimorphism, p. 1. Historical preliminaries, 1. Does not occur in other orders of insects, 4. Beginning of experimental investigation, 5. Lepidopterous foes, 7. First experiments with Araschnia Levana, 10. Experiments with Pieris Napi, 13. Discussion of results, 17. Origination of Prorsa from Levana, 19. Theoretical considerations, 23. The case of Papilio Ajax, 30. Experiments with Pieris Napi var. Bryoniæ, 39. The summer generations of seasonally dimorphic butterflies the more variable, 42. II. Seasonal Dimorphism and Climatic Variation, p. 45. Distinction between climatic and local varieties, 45. The case of Euchloe Belia and its varieties, 47. The case of Polyommatus Phlæas, 49. The case of Plebeius Agestis, 50. III. Nature of the Causes producing Climatic Varieties, p. 52. Seasonal dimorphism of the same nature as climatic variation, 52. How does climatic change influence the markings of a butterfly? 52. The cause of this to be found in temperature, 54. Part played by the organism itself, 58. Analogous seasonal dimorphism in Pierinæ, 60. The part played by sexual selection, 62. IV. Why all Polygoneutic Species are not Seasonally Dimorphic, p. 63. Homochronic heredity, 63. Caterpillars, pupæ and eggs of summer and winter generations of seasonally dimorphic butterflies alike, 64. The law of cyclical heredity, 65. Climatic variation of Pararga Ægeria, 68. Continuous as distinguished from alternating heredity, 68. Return from dimorphism to monomorphism, 70. Seasonally dimorphic species hibernate as pupæ, 71. Retrogressive disturbance of winter generations, 72. The case of Plebeius Amyntas, 75. V. On Alternation of Generations, p. 80. Haeckel’s classification of the phenomena, 80. Proposed modification, 81. Derivation of metagenesis from metamorphosis, 82. Primary and secondary metagenesis, 84. Seasonal dimorphism related to heterogenesis, 86. Heterogenesis and adaptation, 89. Differences between seasonal dimorphism and other cases of heterogenesis, 89. The case of Leptodora Hyalina, 93. VI. xxix xxx General Conclusions, p. 100. Species produced by direct action of environment, 100. The transforming influences of climate, 103. The origin of variability, 107. The influence of isolation, 109. Cyclically acting causes of change produce cyclically recurring changes, 111. Specific constitution an important factor, 112. A “fixed direction of variation,” 114. Appendix I., p. 117. Experiments with Araschnia Levana, 117. Experiments with Pierinæ, 122. Appendix II., p. 126. Experiments with Papilio Ajax, 126. Additional experiments with Pap. Ajax, 131. Experiments with Phyciodes Tharos, 140: with Grapta Interrogationis, 149. Remarks on the latter, 152. Explanation of the Plates, p. 159. Part II. ON THE FINAL CAUSES OF TRANSFORMATION. I. THE ORIGIN OF THE MARKINGS OF CATERPILLARS. Introduction, p. 161. I. Ontogeny and Morphology of Sphinx-Markings, p. 177. The genus Chærocampa, 177; C. Elpenor, 177; C. Porcellus, 184. Results of the development of these species and comparison with other species of the genus, 188. The genus Deilephila, 199; D. Euphorbiæ, 201; D. Nicæa, 207; D. Dahlii, 208; D. Vespertilio, 209; D. Galii, 211; D. Livornica, 215; D. Zygophylli, 217; D. Hippophaës, 218. Summary of facts and conclusions from this genus, 223. The genus Smerinthus, 232; S. Tiliæ, 233; S. Populi, 236; S. Ocellatus, 240. Results of the development of these species, 242. The genus Macroglossa, 245; M. Stellatarum, 245; comparison of this with other species, 253. The genus Pterogon, 255; P. Œnotheræ, 256; comparison with other species, 256. The genus Sphinx, 259; S. Ligustri, 259; comparison with other species, 261. The genus Anceryx, 264; A. Pinastri, 265; comparison with other species, 268. II. Conclusions from Phylogeny, p. 270. The Ontogeny of Caterpillars is a much abbreviated but slightly falsified repetition of the Phylogeny, 270. Three laws of development, 274. The backward transference of new characters to younger stages is the result of an innate law of growth, 278. Proof that new characters always originate at the end of the development; the red spots of S. Tiliæ, 282. III. Biological Value of Marking in general, p. 285. Markings of Caterpillars most favourable to inquiry, 285. Are the Sphinx-markings purely morphological, or have they a biological value? 287. xxxi xxxii IV. Biological Value of Colour, p. 289. General prevalence of protective colouring among caterpillars, 289. Polymorphic adaptive colouring in C. Elpenor, C. Porcellus, P. Œnotheræ, D. Vespertilio, D. Galii, D. Livornica, D. Hippophaës, 295. Habit of concealment primary; its causes, 298. Polymorphism does not here depend upon contemporaneous but upon successive double adaptation; displacement of the old by a new adaptation; proof in the cases of D. Hippophaës, D. Galii, D. Vespertilio, M. Stellatarum, C. Elpenor, and S. Convolvuli, 300. V. Biological Value of special Markings, p. 308. Four chief forms of marking among Sphingidæ, 309. Complete absence of marking among small caterpillars and among those living in obscurity, 310. Longitudinal stripes among grass caterpillars, 312. Oblique striping. Coloured edges are the shadows of leaf ribs, 317. Eye-spots and ring-spots. Definition, 326: Eye-spots not originally signs of distastefulness, 328; they are means of alarm, 329; experiments with birds, 330; possibility of a later change of function in eye-spots, 334. Ring-spots. Are they signs of distastefulness? Are there caterpillars which are edible and which possess bright colours? 335; experiments with lizards, 336. In D. Galii, D. Euphorbiæ, D. Dahlii and D. Mauritanica the ring-spots are probably signs of distastefulness, 341. In D. Nicæa they are perhaps also means of exciting terror, 342. The primary ring-spot in D. Hippophaës is a means of protection, 344. Subordinate markings. Reticulation, 347. The dorsal spots of C. Elpenor and C. Porcellus, 348. The lateral dots of S. Convolvuli, 348. Origination of subordinate markings by the blending of inherited but useless markings with new ones, 349. VI. Objections to a Phyletic Vital Force, p. 352. Independent origination of ring-spots in species of the genus Deilephila, 352. Possible genealogy of this genus, 358. Independent origination of red spots in several species of Smerinthus, 360. Functional change in the elements of marking, 365. Colour change in the course of the ontogeny, 367. VII. Phyletic Development of the Markings of the Sphingidæ. Summary and Conclusion, p. 370. The oldest Sphingidæ were devoid of marking, 370. Longitudinal stripes the oldest form of marking, 371. Oblique striping, 373. Spot markings, 375. The first and second elements of marking are mutually exclusive, but not the first and third, or the second and third, 377. Results with reference to the origin of markings; picture of their origin and gradual complication, 380. General results; rejection of a phyletic vital force, 389. II. ON PHYLETIC PARALLELISM IN METAMORPHIC SPECIES. Introduction, p. 390. I. Larva and Imago vary in Structure independently of each other, p. 401. Dimorphism of one stage only, 402. Independent variability of the stages (heterochronic variability), 403. Constancy and variability are not inherent properties of certain forms of marking, 407. Heterochronic variability is not explained by assuming a phyletic vital force, 410. Rarity of greater variability in pupæ. Greater variability more common among caterpillars than among the imagines. Causes of this phenomenon, 412. Apparent independent variability of the single larval stages. Waves of variability, 416. Saturnia Carpini an instance of secondary variability, 419. Causes of the exact correlation between the larval xxxiii stages and its absence between the larva and imago, 429. II. Does the Form-relationship of the Larva coincide with that of the Imago? p. 432. Family groups, 432. Families frequently completely congruent, 435. Exception offered by the Nymphalidæ, 435. In transitional families the larvæ also show intermediate forms, 441. Genera; almost completely congruent; the Nymphalideous genera can be based on the structure of the larvæ, 444. So also can certain sub-genera, as Vanessa, 445. Incongruence in Pterogon, 450. Species; incongruence very common; S. Ocellatus and Populi, 451. Species of Deilephila show a nearer form-relationship as imagines than as larvæ, 454. Systemy not only the expression of morphological relationship, 455. Varieties; incongruence the rule; seasonal dimorphism; climatic varieties; dimorphism of caterpillars; local varieties of caterpillars, 456. Result of the investigation, 458. Causes of incongruence, 460. A phyletic vital force does not explain the phenomena, 461. This force is superfluous, 464. III. Incongruences in other Orders of Insects, p. 481. Hymenoptera. The imagines only possess ordinal characters, 481. Double incongruence: different distance and different group-formation, 483. Diptera, 488. The larvæ form two types depending on different modes of life, 489. The similarity of the grub-like larvæ of Diptera and Hymenoptera depends upon convergence, 494. These data again furnish strong arguments against a phyletic vital force, 496. The tribe Aphaniptera, 498. Results furnished by the form-relationship of Diptera and Hymenoptera, 499. Difference between typical and non-typical parts transient, 501. IV. Summary and Conclusion, p. 502. First form of incongruence, 503. Second form of incongruence, 506. General conclusion as to the elimination of a phyletic vital force, 511. Parallelism with the transformation of systems of organs, 513. Appendix I., p. 520. Additional notes on the Ontogeny, Phylogeny, &c., of Caterpillars. Ontogeny of Noctua larvæ, 520. Additional descriptions of Sphinx-larvæ, 521. Retention of the subdorsal line by ocellated larvæ, 529. Phytophagic variability, 531. Sexual variation in larvæ, 534. Appendix II., p. 536. Acræa and the Maracujà butterflies as larvæ, pupæ, and imagines, 536. Explanation of the Plates, p. 546. Part III. ON THE FINAL CAUSES OF TRANSFORMATION (continued). III. THE TRANSFORMATION OF THE MEXICAN AXOLOTL INTO AMBLYSTOMA. Introduction, p. 555. Experiments, 558. Significance of the facts, 563. The Axolotl rarely or never undergoes xxxiv xxxv metamorphosis in its native country, 565. North American Amblystomas, 570. Does the exceptional transformation depend upon a phyletic advancement of the species? 571. Theoretical bearing of the case, 574. Differences between Axolotl and Amblystoma, 575. These are not correlative results of the suppression of the gills, 578. Explanation by reversion, 581. Cases of degeneration to a lower phyletic stage: Filippi’s sexually mature “Triton larvæ,” 583. Analogous observations on Triton by Jullien and Schreibers, 591. The sterility of the artificially produced Amblystomas tells against the former importance of the transformation, 594. It is not opposed to the hypothesis of reversion, 596. Attempted explanation of the sterility from this point of view, 597. Causes which may have induced reversion in the hypothetical Mexican Amblystomas, 600. Saltness of the water combined with the drying up of the shores by winds, 604. Consequences of the reversion hypothesis, 609; Systematic, 609; an addendum to the “fundamental biogenetic law,” 611; General importance of reversion, 612. Postscript; dryness of the air the probable cause of the assumed reversion of the Amblystoma to the Axolotl, 613. Addendum, 622. IV. ON THE MECHANICAL CONCEPTION OF NATURE. Introduction, p. 634. Results of the three foregoing essays: denial of a phyletic vital force, 634. Application of these results to inductive conclusions with reference to the organic world in general, 636. The assumption of such a force is opposed to the fundamental laws of natural science, 637. The “vital force” of the older natural philosopher, 640. Why was the latter abandoned? Commencement of a mechanical theory of life, 642. I. Are the Principles of the Selection Theory Mechanical? p. 645. Refutation of Von Hartmann’s views, 645. Variability, 646. The assumption of unlimited variability no postulate of the selection theory, 647. The acknowledgment of a fixed and directed variability does not necessitate the assumption of a phyletic vital force, 647. Heredity, 657. Useful modifications do not occur only singly, 657. New characters appearing singly may also acquire predominance, 659. A mechanical theory of heredity is as yet wanting, 665. Haeckel’s “Perigenesis of the Plastidule,” 667. Correlation, 670. The “specific type” depends upon the physiological equilibrium of the parts of the organism, 671. The theoretical principles of the doctrine of selection are thus mechanical, 675. Importance of the physical constitution of the organism in determining the quality of variations, 676. All individual variability depends upon unequal external influences, 677. Deduction of the limitability of variation, 682. Deduction of local forms, 686. Parallelism between the ontogenetic and the phyletic vital force, 687. The two are inseparable, 690. II. Mechanism and Teleology, p. 694. Von Baer’s exaction from the theory of selection, 694. Justification of his claim, but the impossibility of the co-operation of a metaphysical principle with the mechanism of Nature, 695. Per saltum development (heterogeneous generation), 698. Weakness of the positive basis of this hypothesis, 699. The latter refuted by the impossibility of the co-operation of “heterogeneous generation” with natural selection, 702. The interruption by a metaphysical principle cannot be reconciled with gradual transformation, 705. The metaphysical (teleological) principle can only be conceived of as the ultimate ground of the mechanism of Nature, 709. Value of this knowledge for the harmonious conception of the Universe, 711. Explanation of the spiritual by the assumption of conscious matter, 714. The theory of selection does not necessarily lead to Materialism, 716. Index p. 719. xxxvi 1 STUDIES IN THE THEORY OF DESCENT. Part I. ON THE SEASONAL DIMORPHISM OF BUTTERFLIES. I. The Origin and Significance of Seasonal Dimorphism. The phenomena here about to be subjected to a closer investigation have been known for a long period of time. About the year 1830 it was shown that the two forms of a butterfly (Araschnia) which had till that time been regarded as distinct, in spite of their different colouring and marking really belonged to the same species, the two forms of this dimorphic species not appearing simultaneously but at different seasons of the year, the one in early spring, the other in summer. To this phenomenon the term “seasonal dimorphism” was subsequently applied by Mr. A. R. Wallace, an expression of which the heterogeneous composition may arouse the horror of the philologist, but, as it is as concise and intelligible as possible, I propose to retain it in the present work. The species of Araschnia through which the discovery of seasonal dimorphism was made, formerly bore the two specific names A. Levana and A. Prorsa. The latter is the summer and the former the winter form, the difference between the two being, to the uninitiated, so great that it is difficult to believe in their relationship. A. Levana (Figs. 1 and 2, Plate I.) is of a golden brown colour with black spots and dashes, while A. Prorsa (Figs. 5 and 6, Plate I.) is deep black with a broad white interrupted band across both wings. Notwithstanding this difference, it is an undoubted fact that both forms are merely the winter and summer generations of the same species. I have myself frequently bred the variety Prorsa from the eggs of Levana, and vice versâ. Since the discovery of this last fact a considerable number of similar cases have been established. Thus P. C. Zeller3 showed, by experiments made under confinement, that two butterflies belonging to the family of the ‘Blues,’ differing greatly in colour and marking, and especially in size, which had formerly been distinguished as Plebeius (Lycæna) Polysperchon and P. Amyntas, were merely winter and summer generations of the same species; and that excellent Lepidopterist, Dr. Staudinger, proved the same4 with species belonging to the family of the ‘Whites,’ Euchloe Belia Esp. and E. Ausonia Hüb., which are found in the Mediterranean countries. The instances are not numerous, however, in which the difference between the winter and summer forms of a species is so great as to cause them to be treated of in systematic work as distinct species. I know of only five of these cases. Lesser differences, having the systematic value of varieties, occur much more frequently. Thus, for instance, seasonal dimorphism has been proved to exist among many of our commonest butterflies belonging to the family of the ‘Whites,’ but the difference in their colour and marking can only be detected after some attention; while with other species, as for instance with the commonest of our small ‘Blues,’ Plebeius Alexis (= Icarus, Rott.), the difference is so slight that even the initiated must examine closely in order to recognize it. Indeed whole series of species m...