<p>Every one knows how the horns of stags become more and more branched, and the plumes of some birds become more
finely developed, as they grow older. Professor Cope states that the teeth
of certain lizards change much in shape with advancing years. With
crustaceans not only many trivial, but some important parts assume a new
character, as recorded by Fritz Muller, after maturity. In all such cases—and
many could be given—if the age for reproduction were retarded, the
character of the species, at least in its adult state, would be modified;
nor is it improbable that the previous and earlier stages of development
would in some cases be hurried through and finally lost. Whether species
have often or ever been modified through this comparatively sudden mode of
transition, I can form no opinion; but if this has occurred, it is
probable that the differences between the young and the mature, and
between the mature and the old, were primordially acquired by graduated
steps.</p>
<p>SPECIAL DIFFICULTIES OF THE THEORY OF NATURAL SELECTION.</p>
<p>Although we must be extremely cautious in concluding that any organ could
not have been produced by successive, small, transitional gradations, yet
undoubtedly serious cases of difficulty occur.</p>
<p>One of the most serious is that of neuter insects, which are often
differently constructed from either the males or fertile females; but this
case will be treated of in the next chapter. The electric organs of fishes
offer another case of special difficulty; for it is impossible to conceive
by what steps these wondrous organs have been produced. But this is not
surprising, for we do not even know of what use they are. In the gymnotus
and torpedo they no doubt serve as powerful means of defence, and perhaps
for securing prey; yet in the ray, as observed by Matteucci, an analogous
organ in the tail manifests but little electricity, even when the animal
is greatly irritated; so little that it can hardly be of any use for the
above purposes. Moreover, in the ray, besides the organ just referred to,
there is, as Dr. R. McDonnell has shown, another organ near the head, not
known to be electrical, but which appears to be the real homologue of the
electric battery in the torpedo. It is generally admitted that there
exists between these organs and ordinary muscle a close analogy, in
intimate structure, in the distribution of the nerves, and in the manner
in which they are acted on by various reagents. It should, also, be
especially observed that muscular contraction is accompanied by an
electrical discharge; and, as Dr. Radcliffe insists, "in the electrical
apparatus of the torpedo during rest, there would seem to be a charge in
every respect like that which is met with in muscle and nerve during the
rest, and the discharge of the torpedo, instead of being peculiar, may be
only another form of the discharge which attends upon the action of muscle
and motor nerve." Beyond this we cannot at present go in the way of
explanation; but as we know so little about the uses of these organs, and
as we know nothing about the habits and structure of the progenitors of
the existing electric fishes, it would be extremely bold to maintain that
no serviceable transitions are possible by which these organs might have
been gradually developed.</p>
<p>These organs appear at first to offer another and far more serious
difficulty; for they occur in about a dozen kinds of fish, of which
several are widely remote in their affinities. When the same organ is
found in several members of the same class, especially if in members
having very different habits of life, we may generally attribute its
presence to inheritance from a common ancestor; and its absence in some of
the members to loss through disuse or natural selection. So that, if the
electric organs had been inherited from some one ancient progenitor, we
might have expected that all electric fishes would have been specially
related to each other; but this is far from the case. Nor does geology at
all lead to the belief that most fishes formerly possessed electric
organs, which their modified descendants have now lost. But when we look
at the subject more closely, we find in the several fishes provided with
electric organs, that these are situated in different parts of the body,
that they differ in construction, as in the arrangement of the plates,
and, according to Pacini, in the process or means by which the electricity
is excited—and lastly, in being supplied with nerves proceeding from
different sources, and this is perhaps the most important of all the
differences. Hence in the several fishes furnished with electric organs,
these cannot be considered as homologous, but only as analogous in
function. Consequently there is no reason to suppose that they have been
inherited from a common progenitor; for had this been the case they would
have closely resembled each other in all respects. Thus the difficulty of
an organ, apparently the same, arising in several remotely allied species,
disappears, leaving only the lesser yet still great difficulty: namely, by
what graduated steps these organs have been developed in each separate
group of fishes.</p>
<p>The luminous organs which occur in a few insects, belonging to widely
different families, and which are situated in different parts of the body,
offer, under our present state of ignorance, a difficulty almost exactly
parallel with that of the electric organs. Other similar cases could be
given; for instance in plants, the very curious contrivance of a mass of
pollen-grains, borne on a foot-stalk with an adhesive gland, is apparently
the same in Orchis and Asclepias, genera almost as remote as is possible
among flowering plants; but here again the parts are not homologous. In
all cases of beings, far removed from each other in the scale of
organisation, which are furnished with similar and peculiar organs, it
will be found that although the general appearance and function of the
organs may be the same, yet fundamental differences between them can
always be detected. For instance, the eyes of Cephalopods or cuttle-fish
and of vertebrate animals appear wonderfully alike; and in such widely
sundered groups no part of this resemblance can be due to inheritance from
a common progenitor. Mr. Mivart has advanced this case as one of special
difficulty, but I am unable to see the force of his argument. An organ for
vision must be formed of transparent tissue, and must include some sort of
lens for throwing an image at the back of a darkened chamber. Beyond this
superficial resemblance, there is hardly any real similarity between the
eyes of cuttle-fish and vertebrates, as may be seen by consulting Hensen's
admirable memoir on these organs in the Cephalopoda. It is impossible for
me here to enter on details, but I may specify a few of the points of
difference. The crystalline lens in the higher cuttle-fish consists of two
parts, placed one behind the other like two lenses, both having a very
different structure and disposition to what occurs in the vertebrata. The
retina is wholly different, with an actual inversion of the elemental
parts, and with a large nervous ganglion included within the membranes of
the eye. The relations of the muscles are as different as it is possible
to conceive, and so in other points. Hence it is not a little difficult to
decide how far even the same terms ought to be employed in describing the
eyes of the Cephalopoda and Vertebrata. It is, of course, open to any one
to deny that the eye in either case could have been developed through the
natural selection of successive slight variations; but if this be admitted
in the one case it is clearly possible in the other; and fundamental
differences of structure in the visual organs of two groups might have
been anticipated, in accordance with this view of their manner of
formation. As two men have sometimes independently hit on the same
invention, so in the several foregoing cases it appears that natural
selection, working for the good of each being, and taking advantage of all
favourable variations, has produced similar organs, as far as function is
concerned, in distinct organic beings, which owe none of their structure
in common to inheritance from a common progenitor.</p>
<p>Fritz Muller, in order to test the conclusions arrived at in this volume,
has followed out with much care a nearly similar line of argument. Several
families of crustaceans include a few species, possessing an air-breathing
apparatus and fitted to live out of the water. In two of these families,
which were more especially examined by Muller, and which are nearly
related to each other, the species agree most closely in all important
characters: namely in their sense organs, circulating systems, in the
position of the tufts of hair within their complex stomachs, and lastly in
the whole structure of the water-breathing branchiae, even to the
microscopical hooks by which they are cleansed. Hence it might have been
expected that in the few species belonging to both families which live on
the land, the equally important air-breathing apparatus would have been
the same; for why should this one apparatus, given for the same purpose,
have been made to differ, while all the other important organs were
closely similar, or rather, identical.</p>
<p>Fritz Muller argues that this close similarity in so many points of
structure must, in accordance with the views advanced by me, be accounted
for by inheritance from a common progenitor. But as the vast majority of
the species in the above two families, as well as most other crustaceans,
are aquatic in their habits, it is improbable in the highest degree that
their common progenitor should have been adapted for breathing air. Muller
was thus led carefully to examine the apparatus in the air-breathing
species; and he found it to differ in each in several important points, as
in the position of the orifices, in the manner in which they are opened
and closed, and in some accessory details. Now such differences are
intelligible, and might even have been expected, on the supposition that
species belonging to distinct families had slowly become adapted to live
more and more out of water, and to breathe the air. For these species,
from belonging to distinct families, would have differed to a certain
extent, and in accordance with the principle that the nature of each
variation depends on two factors, viz., the nature of the organism and
that of the surrounding conditions, their variability assuredly would not
have been exactly the same. Consequently natural selection would have had
different materials or variations to work on, in order to arrive at the
same functional result; and the structures thus acquired would almost
necessarily have differed. On the hypothesis of separate acts of creation
the whole case remains unintelligible. This line of argument seems to have
had great weight in leading Fritz Muller to accept the views maintained by
me in this volume.</p>
<p>Another distinguished zoologist, the late Professor Claparede, has argued
in the same manner, and has arrived at the same result. He shows that
there are parasitic mites (Acaridae), belonging to distinct sub-families
and families, which are furnished with hair-claspers. These organs must
have been independently developed, as they could not have been inherited
from a common progenitor; and in the several groups they are formed by the
modification of the fore legs, of the hind legs, of the maxillae or lips,
and of appendages on the under side of the hind part of the body.</p>
<p>In the foregoing cases, we see the same end gained and the same function
performed, in beings not at all or only remotely allied, by organs in
appearance, though not in development, closely similar. On the other hand,
it is a common rule throughout nature that the same end should be gained,
even sometimes in the case of closely related beings, by the most
diversified means. How differently constructed is the feathered wing of a
bird and the membrane-covered wing of a bat; and still more so the four
wings of a butterfly, the two wings of a fly, and the two wings with the
elytra of a beetle. Bivalve shells are made to open and shut, but on what
a number of patterns is the hinge constructed, from the long row of neatly
interlocking teeth in a Nucula to the simple ligament of a Mussel! Seeds
are disseminated by their minuteness, by their capsule being converted
into a light balloon-like envelope, by being embedded in pulp or flesh,
formed of the most diverse parts, and rendered nutritious, as well as
conspicuously coloured, so as to attract and be devoured by birds, by
having hooks and grapnels of many kinds and serrated awns, so as to adhere
to the fur of quadrupeds, and by being furnished with wings and plumes, as
different in shape as they are elegant in structure, so as to be wafted by
every breeze. I will give one other instance: for this subject of the same
end being gained by the most diversified means well deserves attention.
Some authors maintain that organic beings have been formed in many ways
for the sake of mere variety, almost like toys in a shop, but such a view
of nature is incredible. With plants having separated sexes, and with
those in which, though hermaphrodites, the pollen does not spontaneously
fall on the stigma, some aid is necessary for their fertilisation. With
several kinds this is effected by the pollen-grains, which are light and
incoherent, being blown by the wind through mere chance on to the stigma;
and this is the simplest plan which can well be conceived. An almost
equally simple, though very different plan occurs in many plants in which
a symmetrical flower secretes a few drops of nectar, and is consequently
visited by insects; and these carry the pollen from the anthers to the
stigma.</p>
<p>From this simple stage we may pass through an inexhaustible number of
contrivances, all for the same purpose and effected in essentially the
same manner, but entailing changes in every part of the flower. The nectar
may be stored in variously shaped receptacles, with the stamens and
pistils modified in many ways, sometimes forming trap-like contrivances,
and sometimes capable of neatly adapted movements through irritability or
elasticity. From such structures we may advance till we come to such a
case of extraordinary adaptation as that lately described by Dr. Cruger in
the Coryanthes. This orchid has part of its labellum or lower lip hollowed
out into a great bucket, into which drops of almost pure water continually
fall from two secreting horns which stand above it; and when the bucket is
half-full, the water overflows by a spout on one side. The basal part of
the labellum stands over the bucket, and is itself hollowed out into a
sort of chamber with two lateral entrances; within this chamber there are
curious fleshy ridges. The most ingenious man, if he had not witnessed
what takes place, could never have imagined what purpose all these parts
serve. But Dr. Cruger saw crowds of large humble-bees visiting the
gigantic flowers of this orchid, not in order to suck nectar, but to gnaw
off the ridges within the chamber above the bucket; in doing this they
frequently pushed each other into the bucket, and their wings being thus
wetted they could not fly away, but were compelled to crawl out through
the passage formed by the spout or overflow. Dr. Cruger saw a "continual
procession" of bees thus crawling out of their involuntary bath. The
passage is narrow, and is roofed over by the column, so that a bee, in
forcing its way out, first rubs its back against the viscid stigma and
then against the viscid glands of the pollen-masses. The pollen-masses are
thus glued to the back of the bee which first happens to crawl out through
the passage of a lately expanded flower, and are thus carried away. Dr.
Cruger sent me a flower in spirits of wine, with a bee which he had killed
before it had quite crawled out, with a pollen-mass still fastened to its
back. When the bee, thus provided, flies to another flower, or to the same
flower a second time, and is pushed by its comrades into the bucket and
then crawls out by the passage, the pollen-mass necessarily comes first
into contact with the viscid stigma, and adheres to it, and the flower is
fertilised. Now at last we see the full use of every part of the flower,
of the water-secreting horns of the bucket half-full of water, which
prevents the bees from flying away, and forces them to crawl out through
the spout, and rub against the properly placed viscid pollen-masses and
the viscid stigma.</p>
<p>The construction of the flower in another closely allied orchid, namely,
the Catasetum, is widely different, though serving the same end; and is
equally curious. Bees visit these flowers, like those of the Coryanthes,
in order to gnaw the labellum; in doing this they inevitably touch a long,
tapering, sensitive projection, or, as I have called it, the antenna. This
antenna, when touched, transmits a sensation or vibration to a certain
membrane which is instantly ruptured; this sets free a spring by which the
pollen-mass is shot forth, like an arrow, in the right direction, and
adheres by its viscid extremity to the back of the bee. The pollen-mass of
the male plant (for the sexes are separate in this orchid) is thus carried
to the flower of the female plant, where it is brought into contact with
the stigma, which is viscid enough to break certain elastic threads, and
retain the pollen, thus effecting fertilisation.</p>
<p>How, it may be asked, in the foregoing and in innumerable other instances,
can we understand the graduated scale of complexity and the multifarious
means for gaining the same end. The answer no doubt is, as already
remarked, that when two forms vary, which already differ from each other
in some slight degree, the variability will not be of the same exact
nature, and consequently the results obtained through natural selection
for the same general purpose will not be the same. We should also bear in
mind that every highly developed organism has passed through many changes;
and that each modified structure tends to be inherited, so that each
modification will not readily be quite lost, but may be again and again
further altered. Hence, the structure of each part of each species, for
whatever purpose it may serve, is the sum of many inherited changes,
through which the species has passed during its successive adaptations to
changed habits and conditions of life.</p>
<p>Finally, then, although in many cases it is most difficult even to
conjecture by what transitions organs could have arrived at their present
state; yet, considering how small the proportion of living and known forms
is to the extinct and unknown, I have been astonished how rarely an organ
can be named, towards which no transitional grade is known to lead. It is
certainly true, that new organs appearing as if created for some special
purpose rarely or never appear in any being; as indeed is shown by that
old, but somewhat exaggerated, canon in natural history of "Natura non
facit saltum." We meet with this admission in the writings of almost every
experienced naturalist; or, as Milne Edwards has well expressed it,
"Nature is prodigal in variety, but niggard in innovation." Why, on the
theory of Creation, should there be so much variety and so little real
novelty? Why should all the parts and organs of many independent beings,
each supposed to have been separately created for its own proper place in
nature, be so commonly linked together by graduated steps? Why should not
Nature take a sudden leap from structure to structure? On the theory of
natural selection, we can clearly understand why she should not; for
natural selection acts only by taking advantage of slight successive
variations; she can never take a great and sudden leap, but must advance
by the short and sure, though slow steps.</p>
<p>ORGANS OF LITTLE APPARENT IMPORTANCE, AS AFFECTED BY NATURAL SELECTION.</p>
<p>As natural selection acts by life and death, by the survival of the
fittest, and by the destruction of the less well-fitted individuals, I
have sometimes felt great difficulty in understanding the origin or
formation of parts of little importance; almost as great, though of a very
different kind, as in the case of the most perfect and complex organs.</p>
<p>In the first place, we are much too ignorant in regard to the whole
economy of any one organic being to say what slight modifications would be
of importance or not. In a former chapter I have given instances of very
trifling characters, such as the down on fruit and the colour of its
flesh, the colour of the skin and hair of quadrupeds, which, from being
correlated with constitutional differences, or from determining the
attacks of insects, might assuredly be acted on by natural selection. The
tail of the giraffe looks like an artificially constructed fly-flapper;
and it seems at first incredible that this could have been adapted for its
present purpose by successive slight modifications, each better and better
fitted, for so trifling an object as to drive away flies; yet we should
pause before being too positive even in this case, for we know that the
distribution and existence of cattle and other animals in South America
absolutely depend on their power of resisting the attacks of insects: so
that individuals which could by any means defend themselves from these
small enemies, would be able to range into new pastures and thus gain a
great advantage. It is not that the larger quadrupeds are actually
destroyed (except in some rare cases) by flies, but they are incessantly
harassed and their strength reduced, so that they are more subject to
disease, or not so well enabled in a coming dearth to search for food, or
to escape from beasts of prey.</p>
<p>Organs now of trifling importance have probably in some cases been of high
importance to an early progenitor, and, after having been slowly perfected
at a former period, have been transmitted to existing species in nearly
the same state, although now of very slight use; but any actually
injurious deviations in their structure would of course have been checked
by natural selection. Seeing how important an organ of locomotion the tail
is in most aquatic animals, its general presence and use for many purposes
in so many land animals, which in their lungs or modified swim-bladders
betray their aquatic origin, may perhaps be thus accounted for. A
well-developed tail having been formed in an aquatic animal, it might
subsequently come to be worked in for all sorts of purposes, as a
fly-flapper, an organ of prehension, or as an aid in turning, as in the
case of the dog, though the aid in this latter respect must be slight, for
the hare, with hardly any tail, can double still more quickly.</p>
<p>In the second place, we may easily err in attributing importance to
characters, and in believing that they have been developed through natural
selection. We must by no means overlook the effects of the definite action
of changed conditions of life, of so-called spontaneous variations, which
seem to depend in a quite subordinate degree on the nature of the
conditions, of the tendency to reversion to long-lost characters, of the
complex laws of growth, such as of correlation, comprehension, of the
pressure of one part on another, etc., and finally of sexual selection, by
which characters of use to one sex are often gained and then transmitted
more or less perfectly to the other sex, though of no use to the sex. But
structures thus indirectly gained, although at first of no advantage to a
species, may subsequently have been taken advantage of by its modified
descendants, under new conditions of life and newly acquired habits.</p>
<p>If green woodpeckers alone had existed, and we did not know that there
were many black and pied kinds, I dare say that we should have thought
that the green colour was a beautiful adaptation to conceal this
tree-frequenting bird from its enemies; and consequently that it was a
character of importance, and had been acquired through natural selection;
as it is, the colour is probably in chief part due to sexual selection. A
trailing palm in the Malay Archipelago climbs the loftiest trees by the
aid of exquisitely constructed hooks clustered around the ends of the
branches, and this contrivance, no doubt, is of the highest service to the
plant; but as we see nearly similar hooks on many trees which are not
climbers, and which, as there is reason to believe from the distribution
of the thorn-bearing species in Africa and South America, serve as a
defence against browsing quadrupeds, so the spikes on the palm may at
first have been developed for this object, and subsequently have been
improved and taken advantage of by the plant, as it underwent further
modification and became a climber. The naked skin on the head of a vulture
is generally considered as a direct adaptation for wallowing in putridity;
and so it may be, or it may possibly be due to the direct action of putrid
matter; but we should be very cautious in drawing any such inference, when
we see that the skin on the head of the clean-feeding male turkey is
likewise naked. The sutures in the skulls of young mammals have been
advanced as a beautiful adaptation for aiding parturition, and no doubt
they facilitate, or may be indispensable for this act; but as sutures
occur in the skulls of young birds and reptiles, which have only to escape
from a broken egg, we may infer that this structure has arisen from the
laws of growth, and has been taken advantage of in the parturition of the
higher animals.</p>
<p>We are profoundly ignorant of the cause of each slight variation or
individual difference; and we are immediately made conscious of this by
reflecting on the differences between the breeds of our domesticated
animals in different countries, more especially in the less civilized
countries, where there has been but little methodical selection. Animals
kept by savages in different countries often have to struggle for their
own subsistence, and are exposed to a certain extent to natural selection,
and individuals with slightly different constitutions would succeed best
under different climates. With cattle susceptibility to the attacks of
flies is correlated with colour, as is the liability to be poisoned by
certain plants; so that even colour would be thus subjected to the action
of natural selection. Some observers are convinced that a damp climate
affects the growth of the hair, and that with the hair the horns are
correlated. Mountain breeds always differ from lowland breeds; and a
mountainous country would probably affect the hind limbs from exercising
them more, and possibly even the form of the pelvis; and then by the law
of homologous variation, the front limbs and the head would probably be
affected. The shape, also, of the pelvis might affect by pressure the
shape of certain parts of the young in the womb. The laborious breathing
necessary in high regions tends, as we have good reason to believe, to
increase the size of the chest; and again correlation would come into
play. The effects of lessened exercise, together with abundant food, on
the whole organisation is probably still more important, and this, as H.
von Nathusius has lately shown in his excellent Treatise, is apparently
one chief cause of the great modification which the breeds of swine have
undergone. But we are far too ignorant to speculate on the relative
importance of the several known and unknown causes of variation; and I
have made these remarks only to show that, if we are unable to account for
the characteristic differences of our several domestic breeds, which
nevertheless are generally admitted to have arisen through ordinary
generation from one or a few parent-stocks, we ought not to lay too much
stress on our ignorance of the precise cause of the slight analogous
differences between true species.</p>
<p>UTILITARIAN DOCTRINE, HOW FAR TRUE: BEAUTY, HOW ACQUIRED.</p>
<p>The foregoing remarks lead me to say a few words on the protest lately
made by some naturalists against the utilitarian doctrine that every
detail of structure has been produced for the good of its possessor. They
believe that many structures have been created for the sake of beauty, to
delight man or the Creator (but this latter point is beyond the scope of
scientific discussion), or for the sake of mere variety, a view already
discussed. Such doctrines, if true, would be absolutely fatal to my
theory. I fully admit that many structures are now of no direct use to
their possessors, and may never have been of any use to their progenitors;
but this does not prove that they were formed solely for beauty or
variety. No doubt the definite action of changed conditions, and the
various causes of modifications, lately specified, have all produced an
effect, probably a great effect, independently of any advantage thus
gained. But a still more important consideration is that the chief part of
the organisation of every living creature is due to inheritance; and
consequently, though each being assuredly is well fitted for its place in
nature, many structures have now no very close and direct relation to
present habits of life. Thus, we can hardly believe that the webbed feet
of the upland goose, or of the frigate-bird, are of special use to these
birds; we cannot believe that the similar bones in the arm of the monkey,
in the fore leg of the horse, in the wing of the bat, and in the flipper
of the seal, are of special use to these animals. We may safely attribute
these structures to inheritance. But webbed feet no doubt were as useful
to the progenitor of the upland goose and of the frigate-bird, as they now
are to the most aquatic of living birds. So we may believe that the
progenitor of the seal did not possess a flipper, but a foot with five
toes fitted for walking or grasping; and we may further venture to believe
that the several bones in the limbs of the monkey, horse and bat, were
originally developed, on the principle of utility, probably through the
reduction of more numerous bones in the fin of some ancient fish-like
progenitor of the whole class. It is scarcely possible to decide how much
allowance ought to be made for such causes of change, as the definite
action of external conditions, so-called spontaneous variations, and the
complex laws of growth; but with these important exceptions, we may
conclude that the structure of every living creature either now is, or was
formerly, of some direct or indirect use to its possessor.</p>
<p>With respect to the belief that organic beings have been created beautiful
for the delight of man—a belief which it has been pronounced is
subversive of my whole theory—I may first remark that the sense of
beauty obviously depends on the nature of the mind, irrespective of any
real quality in the admired object; and that the idea of what is
beautiful, is not innate or unalterable. We see this, for instance, in the
men of different races admiring an entirely different standard of beauty
in their women. If beautiful objects had been created solely for man's
gratification, it ought to be shown that before man appeared there was
less beauty on the face of the earth than since he came on the stage. Were
the beautiful volute and cone shells of the Eocene epoch, and the
gracefully sculptured ammonites of the Secondary period, created that man
might ages afterwards admire them in his cabinet? Few objects are more
beautiful than the minute siliceous cases of the diatomaceae: were these
created that they might be examined and admired under the higher powers of
the microscope? The beauty in this latter case, and in many others, is
apparently wholly due to symmetry of growth. Flowers rank among the most
beautiful productions of nature; but they have been rendered conspicuous
in contrast with the green leaves, and in consequence at the same time
beautiful, so that they may be easily observed by insects. I have come to
this conclusion from finding it an invariable rule that when a flower is
fertilised by the wind it never has a gaily-coloured corolla. Several
plants habitually produce two kinds of flowers; one kind open and coloured
so as to attract insects; the other closed, not coloured, destitute of
nectar, and never visited by insects. Hence, we may conclude that, if
insects had not been developed on the face of the earth, our plants would
not have been decked with beautiful flowers, but would have produced only
such poor flowers as we see on our fir, oak, nut and ash trees, on
grasses, spinach, docks and nettles, which are all fertilised through the
agency of the wind. A similar line of argument holds good with fruits;
that a ripe strawberry or cherry is as pleasing to the eye as to the
palate—that the gaily-coloured fruit of the spindle-wood tree and
the scarlet berries of the holly are beautiful objects—will be
admitted by everyone. But this beauty serves merely as a guide to birds
and beasts, in order that the fruit may be devoured and the matured seeds
disseminated. I infer that this is the case from having as yet found no
exception to the rule that seeds are always thus disseminated when
embedded within a fruit of any kind (that is within a fleshy or pulpy
envelope), if it be coloured of any brilliant tint, or rendered
conspicuous by being white or black.</p>
<p>On the other hand, I willingly admit that a great number of male animals,
as all our most gorgeous birds, some fishes, reptiles, and mammals, and a
host of magnificently coloured butterflies, have been rendered beautiful
for beauty's sake. But this has been effected through sexual selection,
that is, by the more beautiful males having been continually preferred by
the females, and not for the delight of man. So it is with the music of
birds. We may infer from all this that a nearly similar taste for
beautiful colours and for musical sounds runs through a large part of the
animal kingdom. When the female is as beautifully coloured as the male,
which is not rarely the case with birds and butterflies, the cause
apparently lies in the colours acquired through sexual selection having
been transmitted to both sexes, instead of to the males alone. How the
sense of beauty in its simplest form—that is, the reception of a
peculiar kind of pleasure from certain colours, forms and sounds—was
first developed in the mind of man and of the lower animals, is a very
obscure subject. The same sort of difficulty is presented if we enquire
how it is that certain flavours and odours give pleasure, and others
displeasure. Habit in all these cases appears to have come to a certain
extent into play; but there must be some fundamental cause in the
constitution of the nervous system in each species.</p>
<p>Natural selection cannot possibly produce any modification in a species
exclusively for the good of another species; though throughout nature one
species incessantly takes advantage of, and profits by the structures of
others. But natural selection can and does often produce structures for
the direct injury of other animals, as we see in the fang of the adder,
and in the ovipositor of the ichneumon, by which its eggs are deposited in
the living bodies of other insects. If it could be proved that any part of
the structure of any one species had been formed for the exclusive good of
another species, it would annihilate my theory, for such could not have
been produced through natural selection. Although many statements may be
found in works on natural history to this effect, I cannot find even one
which seems to me of any weight. It is admitted that the rattlesnake has a
poison-fang for its own defence and for the destruction of its prey; but
some authors suppose that at the same time it is furnished with a rattle
for its own injury, namely, to warn its prey. I would almost as soon
believe that the cat curls the end of its tail when preparing to spring,
in order to warn the doomed mouse. It is a much more probable view that
the rattlesnake uses its rattle, the cobra expands its frill and the
puff-adder swells while hissing so loudly and harshly, in order to alarm
the many birds and beasts which are known to attack even the most venomous
species. Snakes act on the same principle which makes the hen ruffle her
feathers and expand her wings when a dog approaches her chickens. But I
have not space here to enlarge on the many ways by which animals endeavour
to frighten away their enemies.</p>
<p>Natural selection will never produce in a being any structure more
injurious than beneficial to that being, for natural selection acts solely
by and for the good of each. No organ will be formed, as Paley has
remarked, for the purpose of causing pain or for doing an injury to its
possessor. If a fair balance be struck between the good and evil caused by
each part, each will be found on the whole advantageous. After the lapse
of time, under changing conditions of life, if any part comes to be
injurious, it will be modified; or if it be not so, the being will become
extinct, as myriads have become extinct.</p>
<p>Natural selection tends only to make each organic being as perfect as, or
slightly more perfect than the other inhabitants of the same country with
which it comes into competition. And we see that this is the standard of
perfection attained under nature. The endemic productions of New Zealand,
for instance, are perfect, one compared with another; but they are now
rapidly yielding before the advancing legions of plants and animals
introduced from Europe. Natural selection will not produce absolute
perfection, nor do we always meet, as far as we can judge, with this high
standard under nature. The correction for the aberration of light is said
by Muller not to be perfect even in that most perfect organ, the human
eye. Helmholtz, whose judgment no one will dispute, after describing in
the strongest terms the wonderful powers of the human eye, adds these
remarkable words: "That which we have discovered in the way of inexactness
and imperfection in the optical machine and in the image on the retina, is
as nothing in comparison with the incongruities which we have just come
across in the domain of the sensations. One might say that nature has
taken delight in accumulating contradictions in order to remove all
foundation from the theory of a pre-existing harmony between the external
and internal worlds." If our reason leads us to admire with enthusiasm a
multitude of inimitable contrivances in nature, this same reason tells us,
though we may easily err on both sides, that some other contrivances are
less perfect. Can we consider the sting of the bee as perfect, which, when
used against many kinds of enemies, cannot be withdrawn, owing to the
backward serratures, and thus inevitably causes the death of the insect by
tearing out its viscera?</p>
<p>If we look at the sting of the bee, as having existed in a remote
progenitor, as a boring and serrated instrument, like that in so many
members of the same great order, and that it has since been modified but
not perfected for its present purpose, with the poison originally adapted
for some other object, such as to produce galls, since intensified, we can
perhaps understand how it is that the use of the sting should so often
cause the insect's own death: for if on the whole the power of stinging be
useful to the social community, it will fulfil all the requirements of
natural selection, though it may cause the death of some few members. If
we admire the truly wonderful power of scent by which the males of many
insects find their females, can we admire the production for this single
purpose of thousands of drones, which are utterly useless to the community
for any other purpose, and which are ultimately slaughtered by their
industrious and sterile sisters? It may be difficult, but we ought to
admire the savage instinctive hatred of the queen-bee, which urges her to
destroy the young queens, her daughters, as soon as they are born, or to
perish herself in the combat; for undoubtedly this is for the good of the
community; and maternal love or maternal hatred, though the latter
fortunately is most rare, is all the same to the inexorable principles of
natural selection. If we admire the several ingenious contrivances by
which orchids and many other plants are fertilised through insect agency,
can we consider as equally perfect the elaboration of dense clouds of
pollen by our fir-trees, so that a few granules may be wafted by chance on
to the ovules?</p>
<p>SUMMARY: THE LAW OF UNITY OF TYPE AND OF THE CONDITIONS<br/> OF EXISTENCE
EMBRACED BY THE THEORY OF NATURAL SELECTION.</p>
<p>We have in this chapter discussed some of the difficulties and objections
which may be urged against the theory. Many of them are serious; but I
think that in the discussion light has been thrown on several facts, which
on the belief of independent acts of creation are utterly obscure. We have
seen that species at any one period are not indefinitely variable, and are
not linked together by a multitude of intermediate gradations, partly
because the process of natural selection is always very slow, and at any
one time acts only on a few forms; and partly because the very process of
natural selection implies the continual supplanting and extinction of
preceding and intermediate gradations. Closely allied species, now living
on a continuous area, must often have been formed when the area was not
continuous, and when the conditions of life did not insensibly graduate
away from one part to another. When two varieties are formed in two
districts of a continuous area, an intermediate variety will often be
formed, fitted for an intermediate zone; but from reasons assigned, the
intermediate variety will usually exist in lesser numbers than the two
forms which it connects; consequently the two latter, during the course of
further modification, from existing in greater numbers, will have a great
advantage over the less numerous intermediate variety, and will thus
generally succeed in supplanting and exterminating it.</p>
<p>We have seen in this chapter how cautious we should be in concluding that
the most different habits of life could not graduate into each other; that
a bat, for instance, could not have been formed by natural selection from
an animal which at first only glided through the air.</p>
<p>We have seen that a species under new conditions of life may change its
habits, or it may have diversified habits, with some very unlike those of
its nearest congeners. Hence we can understand, bearing in mind that each
organic being is trying to live wherever it can live, how it has arisen
that there are upland geese with webbed feet, ground woodpeckers, diving
thrushes, and petrels with the habits of auks.</p>
<p>Although the belief that an organ so perfect as the eye could have been
formed by natural selection, is enough to stagger any one; yet in the case
of any organ, if we know of a long series of gradations in complexity,
each good for its possessor, then under changing conditions of life, there
is no logical impossibility in the acquirement of any conceivable degree
of perfection through natural selection. In the cases in which we know of
no intermediate or transitional states, we should be extremely cautious in
concluding that none can have existed, for the metamorphoses of many
organs show what wonderful changes in function are at least possible. For
instance, a swim-bladder has apparently been converted into an
air-breathing lung. The same organ having performed simultaneously very
different functions, and then having been in part or in whole specialised
for one function; and two distinct organs having performed at the same
time the same function, the one having been perfected whilst aided by the
other, must often have largely facilitated transitions.</p>
<p>We have seen that in two beings widely remote from each other in the
natural scale, organs serving for the same purpose and in external
appearance closely similar may have been separately and independently
formed; but when such organs are closely examined, essential differences
in their structure can almost always be detected; and this naturally
follows from the principle of natural selection. On the other hand, the
common rule throughout nature is infinite diversity of structure for
gaining the same end; and this again naturally follows from the same great
principle.</p>
<p>In many cases we are far too ignorant to be enabled to assert that a part
or organ is so unimportant for the welfare of a species, that
modifications in its structure could not have been slowly accumulated by
means of natural selection. In many other cases, modifications are
probably the direct result of the laws of variation or of growth,
independently of any good having been thus gained. But even such
structures have often, as we may feel assured, been subsequently taken
advantage of, and still further modified, for the good of species under
new conditions of life. We may, also, believe that a part formerly of high
importance has frequently been retained (as the tail of an aquatic animal
by its terrestrial descendants), though it has become of such small
importance that it could not, in its present state, have been acquired by
means of natural selection.</p>
<p>Natural selection can produce nothing in one species for the exclusive
good or injury of another; though it may well produce parts, organs, and
excretions highly useful or even indispensable, or highly injurious to
another species, but in all cases at the same time useful to the
possessor. In each well-stocked country natural selection acts through the
competition of the inhabitants and consequently leads to success in the
battle for life, only in accordance with the standard of that particular
country. Hence the inhabitants of one country, generally the smaller one,
often yield to the inhabitants of another and generally the larger
country. For in the larger country there will have existed more
individuals, and more diversified forms, and the competition will have
been severer, and thus the standard of perfection will have been rendered
higher. Natural selection will not necessarily lead to absolute
perfection; nor, as far as we can judge by our limited faculties, can
absolute perfection be everywhere predicated.</p>
<p>On the theory of natural selection we can clearly understand the full
meaning of that old canon in natural history, "Natura non facit saltum."
This canon, if we look to the present inhabitants alone of the world, is
not strictly correct; but if we include all those of past times, whether
known or unknown, it must on this theory be strictly true.</p>
<p>It is generally acknowledged that all organic beings have been formed on
two great laws—Unity of Type, and the Conditions of Existence. By
unity of type is meant that fundamental agreement in structure which we
see in organic beings of the same class, and which is quite independent of
their habits of life. On my theory, unity of type is explained by unity of
descent. The expression of conditions of existence, so often insisted on
by the illustrious Cuvier, is fully embraced by the principle of natural
selection. For natural selection acts by either now adapting the varying
parts of each being to its organic and inorganic conditions of life; or by
having adapted them during past periods of time: the adaptations being
aided in many cases by the increased use or disuse of parts, being
affected by the direct action of external conditions of life, and
subjected in all cases to the several laws of growth and variation. Hence,
in fact, the law of the Conditions of Existence is the higher law; as it
includes, through the inheritance of former variations and adaptations,
that of Unity of Type.</p>
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