<p>ON THE NATURE OF THE AFFINITIES CONNECTING ORGANIC BEINGS.</p>
<p>As the modified descendants of dominant species, belonging to the larger
genera, tend to inherit the advantages which made the groups to which they
belong large and their parents dominant, they are almost sure to spread
widely, and to seize on more and more places in the economy of nature. The
larger and more dominant groups within each class thus tend to go on
increasing in size, and they consequently supplant many smaller and
feebler groups. Thus, we can account for the fact that all organisms,
recent and extinct, are included under a few great orders and under still
fewer classes. As showing how few the higher groups are in number, and how
widely they are spread throughout the world, the fact is striking that the
discovery of Australia has not added an insect belonging to a new class,
and that in the vegetable kingdom, as I learn from Dr. Hooker, it has
added only two or three families of small size.</p>
<p>In the chapter on geological succession I attempted to show, on the
principle of each group having generally diverged much in character during
the long-continued process of modification, how it is that the more
ancient forms of life often present characters in some degree intermediate
between existing groups. As some few of the old and intermediate forms
having transmitted to the present day descendants but little modified,
these constitute our so-called osculant or aberrant groups. The more
aberrant any form is, the greater must be the number of connecting forms
which have been exterminated and utterly lost. And we have evidence of
aberrant groups having suffered severely from extinction, for they are
almost always represented by extremely few species; and such species as do
occur are generally very distinct from each other, which again implies
extinction. The genera Ornithorhynchus and Lepidosiren, for example, would
not have been less aberrant had each been represented by a dozen species,
instead of as at present by a single one, or by two or three. We can, I
think, account for this fact only by looking at aberrant groups as forms
which have been conquered by more successful competitors, with a few
members still preserved under unusually favourable conditions.</p>
<p>Mr. Waterhouse has remarked that when a member belonging to one group of
animals exhibits an affinity to a quite distinct group, this affinity in
most cases is general and not special: thus, according to Mr. Waterhouse,
of all Rodents, the bizcacha is most nearly related to Marsupials; but in
the points in which it approaches this order, its relations are general,
that is, not to any one Marsupial species more than to another. As these
points of affinity are believed to be real and not merely adaptive, they
must be due in accordance with our view to inheritance from a common
progenitor. Therefore, we must suppose either that all Rodents, including
the bizcacha, branched off from some ancient Marsupial, which will
naturally have been more or less intermediate in character with respect to
all existing Marsupials; or that both Rodents and Marsupials branched off
from a common progenitor, and that both groups have since undergone much
modification in divergent directions. On either view we must suppose that
the bizcacha has retained, by inheritance, more of the character of its
ancient progenitor than have other Rodents; and therefore it will not be
specially related to any one existing Marsupial, but indirectly to all or
nearly all Marsupials, from having partially retained the character of
their common progenitor, or of some early member of the group. On the
other hand, of all Marsupials, as Mr. Waterhouse has remarked, the
Phascolomys resembles most nearly, not any one species, but the general
order of Rodents. In this case, however, it may be strongly suspected that
the resemblance is only analogical, owing to the Phascolomys having become
adapted to habits like those of a Rodent. The elder De Candolle has made
nearly similar observations on the general nature of the affinities of
distinct families of plants.</p>
<p>On the principle of the multiplication and gradual divergence in character
of the species descended from a common progenitor, together with their
retention by inheritance of some characters in common, we can understand
the excessively complex and radiating affinities by which all the members
of the same family or higher group are connected together. For the common
progenitor of a whole family, now broken up by extinction into distinct
groups and subgroups, will have transmitted some of its characters,
modified in various ways and degrees, to all the species; and they will
consequently be related to each other by circuitous lines of affinity of
various lengths (as may be seen in the diagram so often referred to),
mounting up through many predecessors. As it is difficult to show the
blood-relationship between the numerous kindred of any ancient and noble
family, even by the aid of a genealogical tree, and almost impossible to
do so without this aid, we can understand the extraordinary difficulty
which naturalists have experienced in describing, without the aid of a
diagram, the various affinities which they perceive between the many
living and extinct members of the same great natural class.</p>
<p>Extinction, as we have seen in the fourth chapter, has played an important
part in defining and widening the intervals between the several groups in
each class. We may thus account for the distinctness of whole classes from
each other—for instance, of birds from all other vertebrate animals—by
the belief that many ancient forms of life have been utterly lost, through
which the early progenitors of birds were formerly connected with the
early progenitors of the other and at that time less differentiated
vertebrate classes. There has been much less extinction of the forms of
life which once connected fishes with Batrachians. There has been still
less within some whole classes, for instance the Crustacea, for here the
most wonderfully diverse forms are still linked together by a long and
only partially broken chain of affinities. Extinction has only defined the
groups: it has by no means made them; for if every form which has ever
lived on this earth were suddenly to reappear, though it would be quite
impossible to give definitions by which each group could be distinguished,
still a natural classification, or at least a natural arrangement, would
be possible. We shall see this by turning to the diagram: the letters, A
to L, may represent eleven Silurian genera, some of which have produced
large groups of modified descendants, with every link in each branch and
sub-branch still alive; and the links not greater than those between
existing varieties. In this case it would be quite impossible to give
definitions by which the several members of the several groups could be
distinguished from their more immediate parents and descendants. Yet the
arrangement in the diagram would still hold good and would be natural;
for, on the principle of inheritance, all the forms descended, for
instance from A, would have something in common. In a tree we can
distinguish this or that branch, though at the actual fork the two unite
and blend together. We could not, as I have said, define the several
groups; but we could pick out types, or forms, representing most of the
characters of each group, whether large or small, and thus give a general
idea of the value of the differences between them. This is what we should
be driven to, if we were ever to succeed in collecting all the forms in
any one class which have lived throughout all time and space. Assuredly we
shall never succeed in making so perfect a collection: nevertheless, in
certain classes, we are tending toward this end; and Milne Edwards has
lately insisted, in an able paper, on the high importance of looking to
types, whether or not we can separate and define the groups to which such
types belong.</p>
<p>Finally, we have seen that natural selection, which follows from the
struggle for existence, and which almost inevitably leads to extinction
and divergence of character in the descendants from any one
parent-species, explains that great and universal feature in the
affinities of all organic beings, namely, their subordination in group
under group. We use the element of descent in classing the individuals of
both sexes and of all ages under one species, although they may have but
few characters in common; we use descent in classing acknowledged
varieties, however different they may be from their parents; and I believe
that this element of descent is the hidden bond of connexion which
naturalists have sought under the term of the Natural System. On this idea
of the natural system being, in so far as it has been perfected,
genealogical in its arrangement, with the grades of difference expressed
by the terms genera, families, orders, etc., we can understand the rules
which we are compelled to follow in our classification. We can understand
why we value certain resemblances far more than others; why we use
rudimentary and useless organs, or others of trifling physiological
importance; why, in finding the relations between one group and another,
we summarily reject analogical or adaptive characters, and yet use these
same characters within the limits of the same group. We can clearly see
how it is that all living and extinct forms can be grouped together within
a few great classes; and how the several members of each class are
connected together by the most complex and radiating lines of affinities.
We shall never, probably, disentangle the inextricable web of the
affinities between the members of any one class; but when we have a
distinct object in view, and do not look to some unknown plan of creation,
we may hope to make sure but slow progress.</p>
<p>Professor Haeckel in his "Generelle Morphologie" and in another works, has
recently brought his great knowledge and abilities to bear on what he
calls phylogeny, or the lines of descent of all organic beings. In drawing
up the several series he trusts chiefly to embryological characters, but
receives aid from homologous and rudimentary organs, as well as from the
successive periods at which the various forms of life are believed to have
first appeared in our geological formations. He has thus boldly made a
great beginning, and shows us how classification will in the future be
treated.</p>
<p>MORPHOLOGY.</p>
<p>We have seen that the members of the same class, independently of their
habits of life, resemble each other in the general plan of their
organisation. This resemblance is often expressed by the term "unity of
type;" or by saying that the several parts and organs in the different
species of the class are homologous. The whole subject is included under
the general term of Morphology. This is one of the most interesting
departments of natural history, and may almost be said to be its very
soul. What can be more curious than that the hand of a man, formed for
grasping, that of a mole for digging, the leg of the horse, the paddle of
the porpoise, and the wing of the bat, should all be constructed on the
same pattern, and should include similar bones, in the same relative
positions? How curious it is, to give a subordinate though striking
instance, that the hind feet of the kangaroo, which are so well fitted for
bounding over the open plains—those of the climbing, leaf-eating
koala, equally well fitted for grasping the branches of trees—those
of the ground-dwelling, insect or root-eating, bandicoots—and those
of some other Australian marsupials—should all be constructed on the
same extraordinary type, namely with the bones of the second and third
digits extremely slender and enveloped within the same skin, so that they
appear like a single toe furnished with two claws. Notwithstanding this
similarity of pattern, it is obvious that the hind feet of these several
animals are used for as widely different purposes as it is possible to
conceive. The case is rendered all the more striking by the American
opossums, which follow nearly the same habits of life as some of their
Australian relatives, having feet constructed on the ordinary plan.
Professor Flower, from whom these statements are taken, remarks in
conclusion: "We may call this conformity to type, without getting much
nearer to an explanation of the phenomenon;" and he then adds "but is it
not powerfully suggestive of true relationship, of inheritance from a
common ancestor?"</p>
<p>Geoffroy St. Hilaire has strongly insisted on the high importance of
relative position or connexion in homologous parts; they may differ to
almost any extent in form and size, and yet remain connected together in
the same invariable order. We never find, for instance, the bones of the
arm and forearm, or of the thigh and leg, transposed. Hence the same names
can be given to the homologous bones in widely different animals. We see
the same great law in the construction of the mouths of insects: what can
be more different than the immensely long spiral proboscis of a
sphinx-moth, the curious folded one of a bee or bug, and the great jaws of
a beetle? Yet all these organs, serving for such widely different
purposes, are formed by infinitely numerous modifications of an upper lip,
mandibles, and two pairs of maxillae. The same law governs the
construction of the mouths and limbs of crustaceans. So it is with the
flowers of plants.</p>
<p>Nothing can be more hopeless than to attempt to explain this similarity of
pattern in members of the same class, by utility or by the doctrine of
final causes. The hopelessness of the attempt has been expressly admitted
by Owen in his most interesting work on the "Nature of Limbs." On the
ordinary view of the independent creation of each being, we can only say
that so it is; that it has pleased the Creator to construct all the
animals and plants in each great class on a uniform plan; but this is not
a scientific explanation.</p>
<p>The explanation is to a large extent simple, on the theory of the
selection of successive slight modifications, each being profitable in
some way to the modified form, but often affecting by correlation other
parts of the organisation. In changes of this nature, there will be little
or no tendency to alter the original pattern, or to transpose the parts.
The bones of a limb might be shortened and flattened to any extent,
becoming at the same time enveloped in thick membrane, so as to serve as a
fin; or a webbed hand might have all its bones, or certain bones,
lengthened to any extent, with the membrane connecting them increased, so
as to serve as a wing; yet all these modifications would not tend to alter
the framework of the bones or the relative connexion of the parts. If we
suppose that an early progenitor—the archetype, as it may be called—of
all mammals, birds and reptiles, had its limbs constructed on the existing
general pattern, for whatever purpose they served, we can at once perceive
the plain signification of the homologous construction of the limbs
throughout the class. So with the mouths of insects, we have only to
suppose that their common progenitor had an upper lip, mandibles, and two
pairs of maxillae, these parts being perhaps very simple in form; and then
natural selection will account for the infinite diversity in structure and
function of the mouths of insects. Nevertheless, it is conceivable that
the general pattern of an organ might become so much obscured as to be
finally lost, by the reduction and ultimately by the complete abortion of
certain parts, by the fusion of other parts, and by the doubling or
multiplication of others, variations which we know to be within the limits
of possibility. In the paddles of the gigantic extinct sea-lizards, and in
the mouths of certain suctorial crustaceans, the general pattern seems
thus to have become partially obscured.</p>
<p>There is another and equally curious branch of our subject; namely, serial
homologies, or the comparison of the different parts or organs in the same
individual, and not of the same parts or organs in different members of
the same class. Most physiologists believe that the bones of the skull are
homologous—that is, correspond in number and in relative connexion—with
the elemental parts of a certain number of vertebrae. The anterior and
posterior limbs in all the higher vertebrate classes are plainly
homologous. So it is with the wonderfully complex jaws and legs of
crustaceans. It is familiar to almost every one, that in a flower the
relative position of the sepals, petals, stamens, and pistils, as well as
their intimate structure, are intelligible on the view that they consist
of metamorphosed leaves, arranged in a spire. In monstrous plants, we
often get direct evidence of the possibility of one organ being
transformed into another; and we can actually see, during the early or
embryonic stages of development in flowers, as well as in crustaceans and
many other animals, that organs, which when mature become extremely
different are at first exactly alike.</p>
<p>How inexplicable are the cases of serial homologies on the ordinary view
of creation! Why should the brain be enclosed in a box composed of such
numerous and such extraordinarily shaped pieces of bone apparently
representing vertebrae? As Owen has remarked, the benefit derived from the
yielding of the separate pieces in the act of parturition by mammals, will
by no means explain the same construction in the skulls of birds and
reptiles. Why should similar bones have been created to form the wing and
the leg of a bat, used as they are for such totally different purposes,
namely flying and walking? Why should one crustacean, which has an
extremely complex mouth formed of many parts, consequently always have
fewer legs; or conversely, those with many legs have simpler mouths? Why
should the sepals, petals, stamens, and pistils, in each flower, though
fitted for such distinct purposes, be all constructed on the same pattern?</p>
<p>On the theory of natural selection, we can, to a certain extent, answer
these questions. We need not here consider how the bodies of some animals
first became divided into a series of segments, or how they became divided
into right and left sides, with corresponding organs, for such questions
are almost beyond investigation. It is, however, probable that some serial
structures are the result of cells multiplying by division, entailing the
multiplication of the parts developed from such cells. It must suffice for
our purpose to bear in mind that an indefinite repetition of the same part
or organ is the common characteristic, as Owen has remarked, of all low or
little specialised forms; therefore the unknown progenitor of the
Vertebrata probably possessed many vertebrae; the unknown progenitor of
the Articulata, many segments; and the unknown progenitor of flowering
plants, many leaves arranged in one or more spires. We have also formerly
seen that parts many times repeated are eminently liable to vary, not only
in number, but in form. Consequently such parts, being already present in
considerable numbers, and being highly variable, would naturally afford
the materials for adaptation to the most different purposes; yet they
would generally retain, through the force of inheritance, plain traces of
their original or fundamental resemblance. They would retain this
resemblance all the more, as the variations, which afforded the basis for
their subsequent modification through natural selection, would tend from
the first to be similar; the parts being at an early stage of growth
alike, and being subjected to nearly the same conditions. Such parts,
whether more or less modified, unless their common origin became wholly
obscured, would be serially homologous.</p>
<p>In the great class of molluscs, though the parts in distinct species can
be shown to be homologous, only a few serial homologies; such as the
valves of Chitons, can be indicated; that is, we are seldom enabled to say
that one part is homologous with another part in the same individual. And
we can understand this fact; for in molluscs, even in the lowest members
of the class, we do not find nearly so much indefinite repetition of any
one part as we find in the other great classes of the animal and vegetable
kingdoms.</p>
<p>But morphology is a much more complex subject than it at first appears, as
has lately been well shown in a remarkable paper by Mr. E. Ray Lankester,
who has drawn an important distinction between certain classes of cases
which have all been equally ranked by naturalists as homologous. He
proposes to call the structures which resemble each other in distinct
animals, owing to their descent from a common progenitor with subsequent
modification, "homogenous"; and the resemblances which cannot thus be
accounted for, he proposes to call "homoplastic". For instance, he
believes that the hearts of birds and mammals are as a whole homogenous—that
is, have been derived from a common progenitor; but that the four cavities
of the heart in the two classes are homoplastic—that is, have been
independently developed. Mr. Lankester also adduces the close resemblance
of the parts on the right and left sides of the body, and in the
successive segments of the same individual animal; and here we have parts
commonly called homologous which bear no relation to the descent of
distinct species from a common progenitor. Homoplastic structures are the
same with those which I have classed, though in a very imperfect manner,
as analogous modifications or resemblances. Their formation may be
attributed in part to distinct organisms, or to distinct parts of the same
organism, having varied in an analogous manner; and in part to similar
modifications, having been preserved for the same general purpose or
function, of which many instances have been given.</p>
<p>Naturalists frequently speak of the skull as formed of metamorphosed
vertebrae; the jaws of crabs as metamorphosed legs; the stamens and
pistils in flowers as metamorphosed leaves; but it would in most cases be
more correct, as Professor Huxley has remarked, to speak of both skull and
vertebrae, jaws and legs, etc., as having been metamorphosed, not one from
the other, as they now exist, but from some common and simpler element.
Most naturalists, however, use such language only in a metaphorical sense:
they are far from meaning that during a long course of descent, primordial
organs of any kind—vertebrae in the one case and legs in the other—have
actually been converted into skulls or jaws. Yet so strong is the
appearance of this having occurred that naturalists can hardly avoid
employing language having this plain signification. According to the views
here maintained, such language may be used literally; and the wonderful
fact of the jaws, for instance, of a crab retaining numerous characters,
which they probably would have retained through inheritance, if they had
really been metamorphosed from true though extremely simple legs, is in
part explained.</p>
<p>DEVELOPMENT AND EMBRYOLOGY.</p>
<p>This is one of the most important subjects in the whole round of natural
history. The metamorphoses of insects, with which every one is familiar,
are generally effected abruptly by a few stages; but the transformations
are in reality numerous and gradual, though concealed. A certain
ephemerous insect (Chloeon) during its development, moults, as shown by
Sir J. Lubbock, above twenty times, and each time undergoes a certain
amount of change; and in this case we see the act of metamorphosis
performed in a primary and gradual manner. Many insects, and especially
certain crustaceans, show us what wonderful changes of structure can be
effected during development. Such changes, however, reach their acme in
the so-called alternate generations of some of the lower animals. It is,
for instance, an astonishing fact that a delicate branching coralline,
studded with polypi, and attached to a submarine rock, should produce,
first by budding and then by transverse division, a host of huge floating
jelly-fishes; and that these should produce eggs, from which are hatched
swimming animalcules, which attach themselves to rocks and become
developed into branching corallines; and so on in an endless cycle. The
belief in the essential identity of the process of alternate generation
and of ordinary metamorphosis has been greatly strengthened by Wagner's
discovery of the larva or maggot of a fly, namely the Cecidomyia,
producing asexually other larvae, and these others, which finally are
developed into mature males and females, propagating their kind in the
ordinary manner by eggs.</p>
<p>It may be worth notice that when Wagner's remarkable discovery was first
announced, I was asked how was it possible to account for the larvae of
this fly having acquired the power of a sexual reproduction. As long as
the case remained unique no answer could be given. But already Grimm has
shown that another fly, a Chironomus, reproduces itself in nearly the same
manner, and he believes that this occurs frequently in the order. It is
the pupa, and not the larva, of the Chironomus which has this power; and
Grimm further shows that this case, to a certain extent, "unites that of
the Cecidomyia with the parthenogenesis of the Coccidae;" the term
parthenogenesis implying that the mature females of the Coccidae are
capable of producing fertile eggs without the concourse of the male.
Certain animals belonging to several classes are now known to have the
power of ordinary reproduction at an unusually early age; and we have only
to accelerate parthenogenetic reproduction by gradual steps to an earlier
and earlier age—Chironomus showing us an almost exactly intermediate
stage, viz., that of the pupa—and we can perhaps account for the
marvellous case of the Cecidomyia.</p>
<p>It has already been stated that various parts in the same individual,
which are exactly alike during an early embryonic period, become widely
different and serve for widely different purposes in the adult state. So
again it has been shown that generally the embryos of the most distinct
species belonging to the same class are closely similar, but become, when
fully developed, widely dissimilar. A better proof of this latter fact
cannot be given than the statement by Von Baer that "the embryos of
mammalia, of birds, lizards and snakes, probably also of chelonia, are in
the earliest states exceedingly like one another, both as a whole and in
the mode of development of their parts; so much so, in fact, that we can
often distinguish the embryos only by their size. In my possession are two
little embryos in spirit, whose names I have omitted to attach, and at
present I am quite unable to say to what class they belong. They may be
lizards or small birds, or very young mammalia, so complete is the
similarity in the mode of formation of the head and trunk in these
animals. The extremities, however, are still absent in these embryos. But
even if they had existed in the earliest stage of their development we
should learn nothing, for the feet of lizards and mammals, the wings and
feet of birds, no less than the hands and feet of man, all arise from the
same fundamental form." The larvae of most crustaceans, at corresponding
stages of development, closely resemble each other, however different the
adults may become; and so it is with very many other animals. A trace of
the law of embryonic resemblance occasionally lasts till a rather late
age: thus birds of the same genus, and of allied genera, often resemble
each other in their immature plumage; as we see in the spotted feathers in
the young of the thrush group. In the cat tribe, most of the species when
adult are striped or spotted in lines; and stripes or spots can be plainly
distinguished in the whelp of the lion and the puma. We occasionally,
though rarely, see something of the same kind in plants; thus the first
leaves of the ulex or furze, and the first leaves of the phyllodineous
acacias, are pinnate or divided like the ordinary leaves of the
leguminosae.</p>
<p>The points of structure, in which the embryos of widely different animals
within the same class resemble each other, often have no direct relation
to their conditions of existence. We cannot, for instance, suppose that in
the embryos of the vertebrata the peculiar loop-like courses of the
arteries near the branchial slits are related to similar conditions—in
the young mammal which is nourished in the womb of its mother, in the egg
of the bird which is hatched in a nest, and in the spawn of a frog under
water. We have no more reason to believe in such a relation than we have
to believe that the similar bones in the hand of a man, wing of a bat, and
fin of a porpoise, are related to similar conditions of life. No one
supposes that the stripes on the whelp of a lion, or the spots on the
young blackbird, are of any use to these animals.</p>
<p>The case, however, is different when an animal, during any part of its
embryonic career, is active, and has to provide for itself. The period of
activity may come on earlier or later in life; but whenever it comes on,
the adaptation of the larva to its conditions of life is just as perfect
and as beautiful as in the adult animal. In how important a manner this
has acted, has recently been well shown by Sir J. Lubbock in his remarks
on the close similarity of the larvae of some insects belonging to very
different orders, and on the dissimilarity of the larvae of other insects
within the same order, according to their habits of life. Owing to such
adaptations the similarity of the larvae of allied animals is sometimes
greatly obscured; especially when there is a division of labour during the
different stages of development, as when the same larva has during one
stage to search for food, and during another stage has to search for a
place of attachment. Cases can even be given of the larvae of allied
species, or groups of species, differing more from each other than do the
adults. In most cases, however, the larvae, though active, still obey,
more or less closely, the law of common embryonic resemblance. Cirripedes
afford a good instance of this: even the illustrious Cuvier did not
perceive that a barnacle was a crustacean: but a glance at the larva shows
this in an unmistakable manner. So again the two main divisions of
cirripedes, the pedunculated and sessile, though differing widely in
external appearance, have larvae in all their stages barely
distinguishable.</p>
<p>The embryo in the course of development generally rises in organisation. I
use this expression, though I am aware that it is hardly possible to
define clearly what is meant by organisation being higher or lower. But no
one probably will dispute that the butterfly is higher than the
caterpillar. In some cases, however, the mature animal must be considered
as lower in the scale than the larva, as with certain parasitic
crustaceans. To refer once again to cirripedes: the larvae in the first
stage have three pairs of locomotive organs, a simple single eye, and a
probosciformed mouth, with which they feed largely, for they increase much
in size. In the second stage, answering to the chrysalis stage of
butterflies, they have six pairs of beautifully constructed natatory legs,
a pair of magnificent compound eyes, and extremely complex antennae; but
they have a closed and imperfect mouth, and cannot feed: their function at
this stage is, to search out by their well-developed organs of sense, and
to reach by their active powers of swimming, a proper place on which to
become attached and to undergo their final metamorphosis. When this is
completed they are fixed for life: their legs are now converted into
prehensile organs; they again obtain a well-constructed mouth; but they
have no antennae, and their two eyes are now reconverted into a minute,
single, simple eye-spot. In this last and complete state, cirripedes may
be considered as either more highly or more lowly organised than they were
in the larval condition. But in some genera the larvae become developed
into hermaphrodites having the ordinary structure, or into what I have
called complemental males; and in the latter the development has assuredly
been retrograde; for the male is a mere sack, which lives for a short time
and is destitute of mouth, stomach, and every other organ of importance,
excepting those for reproduction.</p>
<p>We are so much accustomed to see a difference in structure between the
embryo and the adult, that we are tempted to look at this difference as in
some necessary manner contingent on growth. But there is no reason why,
for instance, the wing of a bat, or the fin of a porpoise, should not have
been sketched out with all their parts in proper proportion, as soon as
any part became visible. In some whole groups of animals and in certain
members of other groups this is the case, and the embryo does not at any
period differ widely from the adult: thus Owen has remarked in regard to
cuttle-fish, "there is no metamorphosis; the cephalopodic character is
manifested long before the parts of the embryo are completed." Land-shells
and fresh-water crustaceans are born having their proper forms, while the
marine members of the same two great classes pass through considerable and
often great changes during their development. Spiders, again, barely
undergo any metamorphosis. The larvae of most insects pass through a
worm-like stage, whether they are active and adapted to diversified
habits, or are inactive from being placed in the midst of proper
nutriment, or from being fed by their parents; but in some few cases, as
in that of Aphis, if we look to the admirable drawings of the development
of this insect, by Professor Huxley, we see hardly any trace of the
vermiform stage.</p>
<p>Sometimes it is only the earlier developmental stages which fail. Thus,
Fritz Muller has made the remarkable discovery that certain shrimp-like
crustaceans (allied to Penoeus) first appear under the simple
nauplius-form, and after passing through two or more zoea-stages, and then
through the mysis-stage, finally acquire their mature structure: now in
the whole great malacostracan order, to which these crustaceans belong, no
other member is as yet known to be first developed under the
nauplius-form, though many appear as zoeas; nevertheless Muller assigns
reasons for his belief, that if there had been no suppression of
development, all these crustaceans would have appeared as nauplii.</p>
<p>How, then, can we explain these several facts in embryology—namely,
the very general, though not universal, difference in structure between
the embryo and the adult; the various parts in the same individual embryo,
which ultimately become very unlike, and serve for diverse purposes, being
at an early period of growth alike; the common, but not invariable,
resemblance between the embryos or larvae of the most distinct species in
the same class; the embryo often retaining, while within the egg or womb,
structures which are of no service to it, either at that or at a later
period of life; on the other hand, larvae which have to provide for their
own wants, being perfectly adapted to the surrounding conditions; and
lastly, the fact of certain larvae standing higher in the scale of
organisation than the mature animal into which they are developed? I
believe that all these facts can be explained as follows.</p>
<p>It is commonly assumed, perhaps from monstrosities affecting the embryo at
a very early period, that slight variations or individual differences
necessarily appear at an equally early period. We have little evidence on
this head, but what we have certainly points the other way; for it is
notorious that breeders of cattle, horses and various fancy animals,
cannot positively tell, until some time after birth, what will be the
merits and demerits of their young animals. We see this plainly in our own
children; we cannot tell whether a child will be tall or short, or what
its precise features will be. The question is not, at what period of life
any variation may have been caused, but at what period the effects are
displayed. The cause may have acted, and I believe often has acted, on one
or both parents before the act of generation. It deserves notice that it
is of no importance to a very young animal, as long as it is nourished and
protected by its parent, whether most of its characters are acquired a
little earlier or later in life. It would not signify, for instance, to a
bird which obtained its food by having a much-curved beak whether or not
while young it possessed a beak of this shape, as long as it was fed by
its parents.</p>
<p>I have stated in the first chapter, that at whatever age any variation
first appears in the parent, it tends to reappear at a corresponding age
in the offspring. Certain variations can only appear at corresponding
ages; for instance, peculiarities in the caterpillar, cocoon, or imago
states of the silk-moth; or, again, in the full-grown horns of cattle. But
variations which, for all that we can see might have appeared either
earlier or later in life, likewise tend to reappear at a corresponding age
in the offspring and parent. I am far from meaning that this is invariably
the case, and I could give several exceptional cases of variations (taking
the word in the largest sense) which have supervened at an earlier age in
the child than in the parent.</p>
<p>These two principles, namely, that slight variations generally appear at a
not very early period of life, and are inherited at a corresponding not
early period, explain, as I believe, all the above specified leading facts
in embryology. But first let us look to a few analogous cases in our
domestic varieties. Some authors who have written on Dogs maintain that
the greyhound and bull-dog, though so different, are really closely allied
varieties, descended from the same wild stock, hence I was curious to see
how far their puppies differed from each other. I was told by breeders
that they differed just as much as their parents, and this, judging by the
eye, seemed almost to be the case; but on actually measuring the old dogs
and their six-days-old puppies, I found that the puppies had not acquired
nearly their full amount of proportional difference. So, again, I was told
that the foals of cart and race-horses—breeds which have been almost
wholly formed by selection under domestication—differed as much as
the full-grown animals; but having had careful measurements made of the
dams and of three-days-old colts of race and heavy cart-horses, I find
that this is by no means the case.</p>
<p>As we have conclusive evidence that the breeds of the Pigeon are descended
from a single wild species, I compared the young pigeons within twelve
hours after being hatched. I 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 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 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 stage.</p>
<p>These facts are explained by the above two principles. Fanciers select
their dogs, horses, pigeons, etc., for breeding, when nearly grown up.
They are indifferent whether the desired qualities are acquired earlier or
later in life, if the full-grown animal possesses them. And the cases just
given, more especially that of the pigeons, show that the characteristic
differences which have been accumulated by man's selection, and which give
value to his breeds, do not generally appear at a very early period of
life, and are inherited at a corresponding not early period. But the case
of the short-faced tumbler, which when twelve hours old possessed its
proper characters, proves that this is not the universal rule; for here
the characteristic differences must either have appeared at an earlier
period than usual, or, if not so, the differences must have been
inherited, not at a corresponding, but at an earlier age.</p>
<p>Now, let us apply these two principles to species in a state of nature.
Let us take a group of birds, descended from some ancient form and
modified through natural selection for different habits. Then, from the
many slight successive variations having supervened in the several species
at a not early age, and having been inherited at a corresponding age, the
young will have been but little modified, and they will still resemble
each other much more closely than do the adults, just as we have seen with
the breeds of the pigeon. We may extend this view to widely distinct
structures and to whole classes. The fore-limbs, for instance, which once
served as legs to a remote progenitor, may have become, through a long
course of modification, adapted in one descendant to act as hands, in
another as paddles, in another as wings; but on the above two principles
the fore-limbs will not have been much modified in the embryos of these
several forms; although in each form the fore-limb will differ greatly in
the adult state. Whatever influence long continued use or disuse may have
had in modifying the limbs or other parts of any species, this will
chiefly or solely have affected it when nearly mature, when it was
compelled to use its full powers to gain its own living; and the effects
thus produced will have been transmitted to the offspring at a
corresponding nearly mature age. Thus the young will not be modified, or
will be modified only in a slight degree, through the effects of the
increased use or disuse of parts.</p>
<p>With some animals the successive variations may have supervened at a very
early period of life, or the steps may have been inherited at an earlier
age than that at which they first occurred. In either of these cases the
young or embryo will closely resemble the mature parent-form, as we have
seen with the short-faced tumbler. And this is the rule of development in
certain whole groups, or in certain sub-groups alone, as with cuttle-fish,
land-shells, fresh-water crustaceans, spiders, and some members of the
great class of insects. With respect to the final cause of the young in
such groups not passing through any metamorphosis, we can see that this
would follow from the following contingencies: namely, from the young
having to provide at a very early age for their own wants, and from their
following the same habits of life with their parents; for in this case it
would be indispensable for their existence that they should be modified in
the same manner as their parents. Again, with respect to the singular fact
that many terrestrial and fresh-water animals do not undergo any
metamorphosis, while marine members of the same groups pass through
various transformations, Fritz Muller has suggested that the process of
slowly modifying and adapting an animal to live on the land or in fresh
water, instead of in the sea, would be greatly simplified by its not
passing through any larval stage; for it is not probable that places well
adapted for both the larval and mature stages, under such new and greatly
changed habits of life, would commonly be found unoccupied or ill-occupied
by other organisms. In this case the gradual acquirement at an earlier and
earlier age of the adult structure would be favoured by natural selection;
and all traces of former metamorphoses would finally be lost.</p>
<p>If, on the other hand, it profited the young of an animal to follow habits
of life slightly different from those of the parent-form, and consequently
to be constructed on a slightly different plan, or if it profited a larva
already different from its parent to change still further, then, on the
principle of inheritance at corresponding ages, the young or the larvae
might be rendered by natural selection more and more different from their
parents to any conceivable extent. Differences in the larva might, also,
become correlated with successive stages of its development; so that the
larva, in the first stage, might come to differ greatly from the larva in
the second stage, as is the case with many animals. The adult might also
become fitted for sites or habits, in which organs of locomotion or of the
senses, etc., would be useless; and in this case the metamorphosis would
be retrograde.</p>
<p>From the remarks just made we can see how by changes of structure in the
young, in conformity with changed habits of life, together with
inheritance at corresponding ages, animals might come to pass through
stages of development, perfectly distinct from the primordial condition of
their adult progenitors. Most of our best authorities are now convinced
that the various larval and pupal stages of insects have thus been
acquired through adaptation, and not through inheritance from some ancient
form. The curious case of Sitaris—a beetle which passes through
certain unusual stages of development—will illustrate how this might
occur. The first larval form is described by M. Fabre, as an active,
minute insect, furnished with six legs, two long antennae, and four eyes.
These larvae are hatched in the nests of bees; and when the male bees
emerge from their burrows, in the spring, which they do before the
females, the larvae spring on them, and afterwards crawl on to the females
while paired with the males. As soon as the female bee deposits her eggs
on the surface of the honey stored in the cells, the larvae of the Sitaris
leap on the eggs and devour them. Afterwards they undergo a complete
change; their eyes disappear; their legs and antennae become rudimentary,
and they feed on honey; so that they now more closely resemble the
ordinary larvae of insects; ultimately they undergo a further
transformation, and finally emerge as the perfect beetle. Now, if an
insect, undergoing transformations like those of the Sitaris, were to
become the progenitor of a whole new class of insects, the course of
development of the new class would be widely different from that of our
existing insects; and the first larval stage certainly would not represent
the former condition of any adult and ancient form.</p>
<p>On the other hand it is highly probable that with many animals the
embryonic or larval stages show us, more or less completely, the condition
of the progenitor of the whole group in its adult state. In the great
class of the Crustacea, forms wonderfully distinct from each other,
namely, suctorial parasites, cirripedes, entomostraca, and even the
malacostraca, appear at first as larvae under the nauplius-form; and as
these larvae live and feed in the open sea, and are not adapted for any
peculiar habits of life, and from other reasons assigned by Fritz Muller,
it is probable that at some very remote period an independent adult
animal, resembling the Nauplius, existed, and subsequently produced, along
several divergent lines of descent, the above-named great Crustacean
groups. So again, it is probable, from what we know of the embryos of
mammals, birds, fishes and reptiles, that these animals are the modified
descendants of some ancient progenitor, which was furnished in its adult
state with branchiae, a swim-bladder, four fin-like limbs, and a long
tail, all fitted for an aquatic life.</p>
<p>As all the organic beings, extinct and recent, which have ever lived, can
be arranged within a few great classes; and as all within each class have,
according to our theory, been connected together by fine gradations, the
best, and, if our collections were nearly perfect, the only possible
arrangement, would be genealogical; descent being the hidden bond of
connexion which naturalists have been seeking under the term of the
Natural System. On this view we can understand how it is that, in the eyes
of most naturalists, the structure of the embryo is even more important
for classification than that of the adult. In two or more groups of
animals, however much they may differ from each other in structure and
habits in their adult condition, if they pass through closely similar
embryonic stages, we may feel assured that they are all descended from one
parent-form, and are therefore closely related. Thus, community in
embryonic structure reveals community of descent; but dissimilarity in
embryonic development does not prove discommunity of descent, for in one
of two groups the developmental stages may have been suppressed, or may
have been so greatly modified through adaptation to new habits of life as
to be no longer recognisable. Even in groups, in which the adults have
been modified to an extreme degree, community of origin is often revealed
by the structure of the larvae; we have seen, for instance, that
cirripedes, though externally so like shell-fish, are at once known by
their larvae to belong to the great class of crustaceans. As the embryo
often shows us more or less plainly the structure of the less modified and
ancient progenitor of the group, we can see why ancient and extinct forms
so often resemble in their adult state the embryos of existing species of
the same class. Agassiz believes this to be a universal law of nature; and
we may hope hereafter to see the law proved true. It can, however, be
proved true only in those cases in which the ancient state of the
progenitor of the group has not been wholly obliterated, either by
successive variations having supervened at a very early period of growth,
or by such variations having been inherited at an earlier age than that at
which they first appeared. It should also be borne in mind, that the law
may be true, but yet, owing to the geological record not extending far
enough back in time, may remain for a long period, or for ever, incapable
of demonstration. The law will not strictly hold good in those cases in
which an ancient form became adapted in its larval state to some special
line of life, and transmitted the same larval state to a whole group of
descendants; for such larval state will not resemble any still more
ancient form in its adult state.</p>
<p>Thus, as it seems to me, the leading facts in embryology, which are second
to none in importance, are explained on the principle of variations in the
many descendants from some one ancient progenitor, having appeared at a
not very early period of life, and having been inherited at a
corresponding period. Embryology rises greatly in interest, when we look
at the embryo as a picture, more or less obscured, of the progenitor,
either in its adult or larval state, of all the members of the same great
class.</p>
<p>RUDIMENTARY, ATROPHIED, AND ABORTED ORGANS.</p>
<p>Organs or parts in this strange condition, bearing the plain stamp of
inutility, are extremely common, or even general, throughout nature. It
would be impossible to name one of the higher animals in which some part
or other is not in a rudimentary condition. In the mammalia, for instance,
the males possess rudimentary mammae; in snakes one lobe of the lungs is
rudimentary; in birds the "bastard-wing" may safely be considered as a
rudimentary digit, and in some species the whole wing is so far
rudimentary that it cannot be used for flight. What can be more curious
than the presence of teeth in foetal whales, which when grown up have not
a tooth in their heads; or the teeth, which never cut through the gums, in
the upper jaws of unborn calves?</p>
<p>Rudimentary organs plainly declare their origin and meaning in various
ways. There are beetles belonging to closely allied species, or even to
the same identical species, which have either full-sized and perfect
wings, or mere rudiments of membrane, which not rarely lie under
wing-covers firmly soldered together; and in these cases it is impossible
to doubt, that the rudiments represent wings. Rudimentary organs sometimes
retain their potentiality: this occasionally occurs with the mammae of
male mammals, which have been known to become well developed and to
secrete milk. So again in the udders of the genus Bos, there are normally
four developed and two rudimentary teats; but the latter in our domestic
cows sometimes become well developed and yield milk. In regard to plants,
the petals are sometimes rudimentary, and sometimes well developed in the
individuals of the same species. In certain plants having separated sexes
Kolreuter found that by crossing a species, in which the male flowers
included a rudiment of a pistil, with an hermaphrodite species, having of
course a well-developed pistil, the rudiment in the hybrid offspring was
much increased in size; and this clearly shows that the rudimentary and
perfect pistils are essentially alike in nature. An animal may possess
various parts in a perfect state, and yet they may in one sense be
rudimentary, for they are useless: thus the tadpole of the common
salamander or water-newt, as Mr. G.H. Lewes remarks, "has gills, and
passes its existence in the water; but the Salamandra atra, which lives
high up among the mountains, brings forth its young full-formed. This
animal never lives in the water. Yet if we open a gravid female, we find
tadpoles inside her with exquisitely feathered gills; and when placed in
water they swim about like the tadpoles of the water-newt. Obviously this
aquatic organisation has no reference to the future life of the animal,
nor has it any adaptation to its embryonic condition; it has solely
reference to ancestral adaptations, it repeats a phase in the development
of its progenitors."</p>
<p>An organ, serving for two purposes, may become rudimentary or utterly
aborted for one, even the more important purpose, and remain perfectly
efficient for the other. Thus, in plants, the office of the pistil is to
allow the pollen-tubes to reach the ovules within the ovarium. The pistil
consists of a stigma supported on the style; but in some Compositae, the
male florets, which of course cannot be fecundated, have a rudimentary
pistil, for it is not crowned with a stigma; but the style remains well
developed and is clothed in the usual manner with hairs, which serve to
brush the pollen out of the surrounding and conjoined anthers. Again, an
organ may become rudimentary for its proper purpose, and be used for a
distinct one: in certain fishes the swim-bladder seems to be rudimentary
for its proper function of giving buoyancy, but has become converted into
a nascent breathing organ or lung. Many similar instances could be given.</p>
<p>Useful organs, however little they may be developed, unless we have reason
to suppose that they were formerly more highly developed, ought not to be
considered as rudimentary. They may be in a nascent condition, and in
progress towards further development. Rudimentary organs, on the other
hand, are either quite useless, such as teeth which never cut through the
gums, or almost useless, such as the wings of an ostrich, which serve
merely as sails. As organs in this condition would formerly, when still
less developed, have been of even less use than at present, they cannot
formerly have been produced through variation and natural selection, which
acts solely by the preservation of useful modifications. They have been
partially retained by the power of inheritance, and relate to a former
state of things. It is, however, often difficult to distinguish between
rudimentary and nascent organs; for we can judge only by analogy whether a
part is capable of further development, in which case alone it deserves to
be called nascent. Organs in this condition will always be somewhat rare;
for beings thus provided will commonly have been supplanted by their
successors with the same organ in a more perfect state, and consequently
will have become long ago extinct. The wing of the penguin is of high
service, acting as a fin; it may, therefore, represent the nascent state
of the wing: not that I believe this to be the case; it is more probably a
reduced organ, modified for a new function: the wing of the Apteryx, on
the other hand, is quite useless, and is truly rudimentary. Owen considers
the simple filamentary limbs of the Lepidosiren as the "beginnings of
organs which attain full functional development in higher vertebrates;"
but, according to the view lately advocated by Dr. Gunther, they are
probably remnants, consisting of the persistent axis of a fin, with the
lateral rays or branches aborted. The mammary glands of the
Ornithorhynchus may be considered, in comparison with the udders of a cow,
as in a nascent condition. The ovigerous frena of certain cirripedes,
which have ceased to give attachment to the ova and are feebly developed,
are nascent branchiae.</p>
<p>Rudimentary organs in the individuals of the same species are very liable
to vary in the degree of their development and in other respects. In
closely allied species, also, the extent to which the same organ has been
reduced occasionally differs much. This latter fact is well exemplified in
the state of the wings of female moths belonging to the same family.
Rudimentary organs may be utterly aborted; and this implies, that in
certain animals or plants, parts are entirely absent which analogy would
lead us to expect to find in them, and which are occasionally found in
monstrous individuals. Thus in most of the Scrophulariaceae the fifth
stamen is utterly aborted; yet we may conclude that a fifth stamen once
existed, for a rudiment of it is found in many species of the family, and
this rudiment occasionally becomes perfectly developed, as may sometimes
be seen in the common snap-dragon. In tracing the homologies of any part
in different members of the same class, nothing is more common, or, in
order fully to understand the relations of the parts, more useful than the
discovery of rudiments. This is well shown in the drawings given by Owen
of the leg bones of the horse, ox, and rhinoceros.</p>
<p>It is an important fact that rudimentary organs, such as teeth in the
upper jaws of whales and ruminants, can often be detected in the embryo,
but afterwards wholly disappear. It is also, I believe, a universal rule,
that a rudimentary part is of greater size in the embryo relatively to the
adjoining parts, than in the adult; so that the organ at this early age is
less rudimentary, or even cannot be said to be in any degree rudimentary.
Hence rudimentary organs in the adult are often said to have retained
their embryonic condition.</p>
<p>I have now given the leading facts with respect to rudimentary organs. In
reflecting on them, every one must be struck with astonishment; for the
same reasoning power which tells us that most parts and organs are
exquisitely adapted for certain purposes, tells us with equal plainness
that these rudimentary or atrophied organs are imperfect and useless. In
works on natural history, rudimentary organs are generally said to have
been created "for the sake of symmetry," or in order "to complete the
scheme of nature." But this is not an explanation, merely a restatement of
the fact. Nor is it consistent with itself: thus the boa-constrictor has
rudiments of hind limbs and of a pelvis, and if it be said that these
bones have been retained "to complete the scheme of nature," why, as
Professor Weismann asks, have they not been retained by other snakes,
which do not possess even a vestige of these same bones? What would be
thought of an astronomer who maintained that the satellites revolve in
elliptic courses round their planets "for the sake of symmetry," because
the planets thus revolve round the sun? An eminent physiologist accounts
for the presence of rudimentary organs, by supposing that they serve to
excrete matter in excess, or matter injurious to the system; but can we
suppose that the minute papilla, which often represents the pistil in male
flowers, and which is formed of mere cellular tissue, can thus act? Can we
suppose that rudimentary teeth, which are subsequently absorbed, are
beneficial to the rapidly growing embryonic calf by removing matter so
precious as phosphate of lime? When a man's fingers have been amputated,
imperfect nails have been known to appear on the stumps, and I could as
soon believe that these vestiges of nails are developed in order to
excrete horny matter, as that the rudimentary nails on the fin of the
manatee have been developed for this same purpose.</p>
<p>On the view of descent with modification, the origin of rudimentary organs
is comparatively simple; and we can understand to a large extent the laws
governing their imperfect development. We have plenty of cases of
rudimentary organs in our domestic productions, as the stump of a tail in
tailless breeds, the vestige of an ear in earless breeds of sheep—the
reappearance of minute dangling horns in hornless breeds of cattle, more
especially, according to Youatt, in young animals—and the state of
the whole flower in the cauliflower. We often see rudiments of various
parts in monsters; but I doubt whether any of these cases throw light on
the origin of rudimentary organs in a state of nature, further than by
showing that rudiments can be produced; for the balance of evidence
clearly indicates that species under nature do not undergo great and
abrupt changes. But we learn from the study of our domestic productions
that the disuse of parts leads to their reduced size; and that the result
is inherited.</p>
<p>It appears probable that disuse has been the main agent in rendering
organs rudimentary. It would at first lead by slow steps to the more and
more complete reduction of a part, until at last it became rudimentary—as
in the case of the eyes of animals inhabiting dark caverns, and of the
wings of birds inhabiting oceanic islands, which have seldom been forced
by beasts of prey to take flight, and have ultimately lost the power of
flying. Again, an organ, useful under certain conditions, might become
injurious under others, as with the wings of beetles living on small and
exposed islands; and in this case natural selection will have aided in
reducing the organ, until it was rendered harmless and rudimentary.</p>
<p>Any change in structure and function, which can be effected by small
stages, is within the power of natural selection; so that an organ
rendered, through changed habits of life, useless or injurious for one
purpose, might be modified and used for another purpose. An organ might,
also, be retained for one alone of its former functions. Organs,
originally formed by the aid of natural selection, when rendered useless
may well be variable, for their variations can no longer be checked by
natural selection. All this agrees well with what we see under nature.
Moreover, at whatever period of life either disuse or selection reduces an
organ, and this will generally be when the being has come to maturity and
to exert its full powers of action, the principle of inheritance at
corresponding ages will tend to reproduce the organ in its reduced state
at the same mature age, but will seldom affect it in the embryo. Thus we
can understand the greater size of rudimentary organs in the embryo
relatively to the adjoining parts, and their lesser relative size in the
adult. If, for instance, the digit of an adult animal was used less and
less during many generations, owing to some change of habits, or if an
organ or gland was less and less functionally exercised, we may infer that
it would become reduced in size in the adult descendants of this animal,
but would retain nearly its original standard of development in the
embryo.</p>
<p>There remains, however, this difficulty. After an organ has ceased being
used, and has become in consequence much reduced, how can it be still
further reduced in size until the merest vestige is left; and how can it
be finally quite obliterated? It is scarcely possible that disuse can go
on producing any further effect after the organ has once been rendered
functionless. Some additional explanation is here requisite which I cannot
give. If, for instance, it could be proved that every part of the
organisation tends to vary in a greater degree towards diminution than
toward augmentation of size, then we should be able to understand how an
organ which has become useless would be rendered, independently of the
effects of disuse, rudimentary and would at last be wholly suppressed; for
the variations towards diminished size would no longer be checked by
natural selection. The principle of the economy of growth, explained in a
former chapter, by which the materials forming any part, if not useful to
the possessor, are saved as far as is possible, will perhaps come into
play in rendering a useless part rudimentary. But this principle will
almost necessarily be confined to the earlier stages of the process of
reduction; for we cannot suppose that a minute papilla, for instance,
representing in a male flower the pistil of the female flower, and formed
merely of cellular tissue, could be further reduced or absorbed for the
sake of economising nutriment.</p>
<p>Finally, as rudimentary organs, by whatever steps they may have been
degraded into their present useless condition, are the record of a former
state of things, and have been retained solely through the power of
inheritance—we can understand, on the genealogical view of
classification, how it is that systematists, in placing organisms in their
proper places in the natural system, have often found rudimentary parts as
useful as, or even sometimes more useful than, parts of high physiological
importance. Rudimentary organs may be compared with the letters in a word,
still retained in the spelling, but become useless in the pronunciation,
but which serve as a clue for its derivation. On the view of descent with
modification, we may conclude that the existence of organs in a
rudimentary, imperfect, and useless condition, or quite aborted, far from
presenting a strange difficulty, as they assuredly do on the old doctrine
of creation, might even have been anticipated in accordance with the views
here explained.</p>
<p>SUMMARY.</p>
<p>In this chapter I have attempted to show that the arrangement of all
organic beings throughout all time in groups under groups—that the
nature of the relationships by which all living and extinct organisms are
united by complex, radiating, and circuitous lines of affinities into a
few grand classes—the rules followed and the difficulties
encountered by naturalists in their classifications—the value set
upon characters, if constant and prevalent, whether of high or of the most
trifling importance, or, as with rudimentary organs of no importance—the
wide opposition in value between analogical or adaptive characters, and
characters of true affinity; and other such rules—all naturally
follow if we admit the common parentage of allied forms, together with
their modification through variation and natural selection, with the
contingencies of extinction and divergence of character. In considering
this view of classification, it should be borne in mind that the element
of descent has been universally used in ranking together the sexes, ages,
dimorphic forms, and acknowledged varieties of the same species, however
much they may differ from each other in structure. If we extend the use of
this element of descent—the one certainly known cause of similarity
in organic beings—we shall understand what is meant by the Natural
System: it is genealogical in its attempted arrangement, with the grades
of acquired difference marked by the terms, varieties, species, genera,
families, orders, and classes.</p>
<p>On this same view of descent with modification, most of the great facts in
Morphology become intelligible—whether we look to the same pattern
displayed by the different species of the same class in their homologous
organs, to whatever purpose applied, or to the serial and lateral
homologies in each individual animal and plant.</p>
<p>On the principle of successive slight variations, not necessarily or
generally supervening at a very early period of life, and being inherited
at a corresponding period, we can understand the leading facts in
embryology; namely, the close resemblance in the individual embryo of the
parts which are homologous, and which when matured become widely different
in structure and function; and the resemblance of the homologous parts or
organs in allied though distinct species, though fitted in the adult state
for habits as different as is possible. Larvae are active embryos, which
have become specially modified in a greater or less degree in relation to
their habits of life, with their modifications inherited at a
corresponding early age. On these same principles, and bearing in mind
that when organs are reduced in size, either from disuse or through
natural selection, it will generally be at that period of life when the
being has to provide for its own wants, and bearing in mind how strong is
the force of inheritance—the occurrence of rudimentary organs might
even have been anticipated. The importance of embryological characters and
of rudimentary organs in classification is intelligible, on the view that
a natural arrangement must be genealogical.</p>
<p>Finally, the several classes of facts which have been considered in this
chapter, seem to me to proclaim so plainly, that the innumerable species,
genera and families, with which this world is peopled, are all descended,
each within its own class or group, from common parents, and have all been
modified in the course of descent, that I should without hesitation adopt
this view, even if it were unsupported by other facts or arguments.</p>
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