darwin and modern science-第50章
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ions; the descent of the human race。
VIII。 CHARLES DARWIN AS AN ANTHROPOLOGIST。
By ERNST HAECKEL。 Professor of Zoology in the University of Jena。
The great advance that anthropology has made in the second half of the nineteenth century is due in the first place; to Darwin's discovery of the origin of man。 No other problem in the whole field of research is so momentous as that of 〃Man's place in nature;〃 which was justly described by Huxley (1863) as the most fundamental of all questions。 Yet the scientific solution of this problem was impossible until the theory of descent had been established。
It is now a hundred years since the great French biologist Jean Lamarck published his 〃Philosophie Zoologique〃。 By a remarkable coincidence the year in which that work was issued; 1809; was the year of the birth of his most distinguished successor; Charles Darwin。 Lamarck had already recognised that the descent of man from a series of other Vertebratesthat is; from a series of Ape…like Primateswas essentially involved in the general theory of transformation which he had erected on a broad inductive basis; and he had sufficient penetration to detect the agencies that had been at work in the evolution of the erect bimanous man from the arboreal and quadrumanous ape。 He had; however; few empirical arguments to advance in support of his hypothesis; and it could not be established until the further development of the biological sciencesthe founding of comparative embryology by Baer (1828) and of the cell…theory by Schleiden and Schwann (1838); the advance of physiology under Johannes Muller (1833); and the enormous progress of palaeontology and comparative anatomy between 1820 and 1860provided this necessary foundation。 Darwin was the first to coordinate the ample results of these lines of research。 With no less comprehensiveness than discrimination he consolidated them as a basis of a modified theory of descent; and associated with them his own theory of natural selection; which we take to be distinctive of 〃Darwinism〃 in the stricter sense。 The illuminating truth of these cumulative arguments was so great in every branch of biology that; in spite of the most vehement opposition; the battle was won within a single decade; and Darwin secured the general admiration and recognition that had been denied to his forerunner; Lamarck; up to the hour of his death (1829)。
Before; however; we consider the momentous influence that Darwinism has had in anthropology; we shall find it useful to glance at its history in the course of the last half century; and notice the various theories that have contributed to its advance。 The first attempt to give extensive expression to the reform of biology by Darwin's work will be found in my 〃Generelle Morphologie〃 (1866) (〃Generelle Morphologie der Organismen〃; 2 vols。; Berlin; 1866。) which was followed by a more popular treatment of the subject in my 〃Naturliche Schopfungsgeschichte (1868) (English translation; 〃The History of Creation〃; London; 1876。); a compilation from the earlier work。 In the first volume of the 〃Generelle Morphologie〃 I endeavoured to show the great importance of evolution in settling the fundamental questions of biological philosophy; especially in regard to comparative anatomy。 In the second volume I dealt broadly with the principle of evolution; distinguishing ontogeny and phylogeny as its two coordinate main branches; and associating the two in the Biogenetic Law。 The Law may be formulated thus: 〃Ontogeny (embryology or the development of the individual) is a concise and compressed recapitulation of phylogeny (the palaeontological or genealogical series) conditioned by laws of heredity and adaptation。〃 The 〃Systematic introduction to general evolution;〃 with which the second volume of the 〃Generelle Morphologie〃 opens; was the first attempt to draw up a natural system of organisms (in harmony with the principles of Lamarck and Darwin) in the form of a hypothetical pedigree; and was provisionally set forth in eight genealogical tables。
In the nineteenth chapter of the 〃Generelle Morphologie〃a part of which has been republished; without any alteration; after a lapse of forty years I made a critical study of Lamarck's theory of descent and of Darwin's theory of selection; and endeavoured to bring the complex phenomena of heredity and adaptation under definite laws for the first time。 Heredity I divided into conservative and progressive: adaptation into indirect (or potential) and direct (or actual)。 I then found it possible to give some explanation of the correlation of the two physiological functions in the struggle for life (selection); and to indicate the important laws of divergence (or differentiation) and complexity (or division of labour); which are the direct and inevitable outcome of selection。 Finally; I marked off dysteleology as the science of the aimless (vestigial; abortive; atrophied; and useless) organs and parts of the body。 In all this I worked from a strictly monistic standpoint; and sought to explain all biological phenomena on the mechanical and naturalistic lines that had long been recognised in the study of inorganic nature。 Then (1866); as now; being convinced of the unity of nature; the fundamental identity of the agencies at work in the inorganic and the organic worlds; I discarded vitalism; teleology; and all hypotheses of a mystic character。
It was clear from the first that it was essential; in the monistic conception of evolution; to distinguish between the laws of conservative and progressive heredity。 Conservative heredity maintains from generation to generation the enduring characters of the species。 Each organism transmits to its descendants a part of the morphological and physiological qualities that it has received from its parents and ancestors。 On the other hand; progressive heredity brings new characters to the species characters that were not found in preceding generations。 Each organism may transmit to its offspring a part of the morphological and physiological features that it has itself acquired; by adaptation; in the course of its individual career; through the use or disuse of particular organs; the influence of environment; climate; nutrition; etc。 At that time I gave the name of 〃progressive heredity〃 to this inheritance of acquired characters; as a short and convenient expression; but have since changed the term to 〃transformative heredity〃 (as distinguished from conservative)。 This term is preferable; as inherited regressive modifications (degeneration; retrograde metamorphisis; etc。) come under the same head。
Transformative heredityor the transmission of acquired charactersis one of the most important principles in evolutionary science。 Unless we admit it most of the facts of comparative anatomy and physiology are inexplicable。 That was the conviction of Darwin no less than of Lamarck; of Spencer as well as Virchow; of Huxley as well as Gegenbaur; indeed of the great majority of speculative biologists。 This fundamental principle was for the first time called in question and assailed in 1885 by August Weismann of Freiburg; the eminent zoologist to whom the theory of evolution owes a great deal of valuable support; and who has attained distinction by his extension of the theory of selection。 In explanation of the phenomena of heredity he introduced a new theory; the 〃theory of the continuity of the germ…plasm。〃 According to him the living substance in all organisms consists of two quite distinct kinds of plasm; somatic and germinal。 The permanent germ…plasm; or the active substance of the two germ…cells (egg… cell and sperm…cell); passes unchanged through a series of generations; and is not affected by environmental influences。 The environment modifies only the soma…plasm; the organs and tissues of the body。 The modifications that these parts undergo through the influence of the environment or their own activity (use and habit); do not affect the germ…plasm; and cannot therefore be transmitted。
This theory of the continuity of the germ…plasm has been expounded by Weismann during the last twenty…four years in a number of able volumes; and is regarded by many biologists; such as Mr Francis Gal
