<p>The Pleuronectidae, or Flat-fish, are remarkable for their asymmetrical
bodies. They rest on one side—in the greater number of species on
the left, but in some on the right side; and occasionally reversed adult
specimens occur. The lower, or resting-surface, resembles at first sight
the ventral surface of an ordinary fish; it is of a white colour, less
developed in many ways than the upper side, with the lateral fins often of
smaller size. But the eyes offer the most remarkable peculiarity; for they
are both placed on the upper side of the head. During early youth,
however, they stand opposite to each other, and the whole body is then
symmetrical, with both sides equally coloured. Soon the eye proper to the
lower side begins to glide slowly round the head to the upper side; but
does not pass right through the skull, as was formerly thought to be the
case. It is obvious that unless the lower eye did thus travel round, it
could not be used by the fish while lying in its habitual position on one
side. The lower eye would, also, have been liable to be abraded by the
sandy bottom. That the Pleuronectidae are admirably adapted by their
flattened and asymmetrical structure for their habits of life, is manifest
from several species, such as soles, flounders, etc., being extremely
common. The chief advantages thus gained seem to be protection from their
enemies, and facility for feeding on the ground. The different members,
however, of the family present, as Schiodte remarks, "a long series of
forms exhibiting a gradual transition from Hippoglossus pinguis, which
does not in any considerable degree alter the shape in which it leaves the
ovum, to the soles, which are entirely thrown to one side."</p>
<p>Mr. Mivart has taken up this case, and remarks that a sudden spontaneous
transformation in the position of the eyes is hardly conceivable, in which
I quite agree with him. He then adds: "If the transit was gradual, then
how such transit of one eye a minute fraction of the journey towards the
other side of the head could benefit the individual is, indeed, far from
clear. It seems, even, that such an incipient transformation must rather
have been injurious." But he might have found an answer to this objection
in the excellent observations published in 1867 by Malm. The
Pleuronectidae, while very young and still symmetrical, with their eyes
standing on opposite sides of the head, cannot long retain a vertical
position, owing to the excessive depth of their bodies, the small size of
their lateral fins, and to their being destitute of a swim-bladder. Hence,
soon growing tired, they fall to the bottom on one side. While thus at
rest they often twist, as Malm observed, the lower eye upward, to see
above them; and they do this so vigorously that the eye is pressed hard
against the upper part of the orbit. The forehead between the eyes
consequently becomes, as could be plainly seen, temporarily contracted in
breadth. On one occasion Malm saw a young fish raise and depress the lower
eye through an angular distance of about seventy degrees.</p>
<p>We should remember that the skull at this early age is cartilaginous and
flexible, so that it readily yields to muscular action. It is also known
with the higher animals, even after early youth, that the skull yields and
is altered in shape, if the skin or muscles be permanently contracted
through disease or some accident. With long-eared rabbits, if one ear
flops forward and downward, its weight drags forward all the bones of the
skull on the same side, of which I have given a figure. Malm states that
the newly-hatched young of perches, salmon, and several other symmetrical
fishes, have the habit of occasionally resting on one side at the bottom;
and he has observed that they often then strain their lower eyes so as to
look upward; and their skulls are thus rendered rather crooked. These
fishes, however, are soon able to hold themselves in a vertical position,
and no permanent effect is thus produced. With the Pleuronectidae, on the
other hand, the older they grow the more habitually they rest on one side,
owing to the increasing flatness of their bodies, and a permanent effect
is thus produced on the form of the head, and on the position of the eyes.
Judging from analogy, the tendency to distortion would no doubt be
increased through the principle of inheritance. Schiodte believes, in
opposition to some other naturalists, that the Pleuronectidae are not
quite symmetrical even in the embryo; and if this be so, we could
understand how it is that certain species, while young, habitually fall
over and rest on the left side, and other species on the right side. Malm
adds, in confirmation of the above view, that the adult Trachypterus
arcticus, which is not a member of the Pleuronectidae, rests on its left
side at the bottom, and swims diagonally through the water; and in this
fish, the two sides of the head are said to be somewhat dissimilar. Our
great authority on Fishes, Dr. Gunther, concludes his abstract of Malm's
paper, by remarking that "the author gives a very simple explanation of
the abnormal condition of the Pleuronectoids."</p>
<p>We thus see that the first stages of the transit of the eye from one side
of the head to the other, which Mr. Mivart considers would be injurious,
may be attributed to the habit, no doubt beneficial to the individual and
to the species, of endeavouring to look upward with both eyes, while
resting on one side at the bottom. We may also attribute to the inherited
effects of use the fact of the mouth in several kinds of flat-fish being
bent towards the lower surface, with the jaw bones stronger and more
effective on this, the eyeless side of the head, than on the other, for
the sake, as Dr. Traquair supposes, of feeding with ease on the ground.
Disuse, on the other hand, will account for the less developed condition
of the whole inferior half of the body, including the lateral fins; though
Yarrel thinks that the reduced size of these fins is advantageous to the
fish, as "there is so much less room for their action than with the larger
fins above." Perhaps the lesser number of teeth in the proportion of four
to seven in the upper halves of the two jaws of the plaice, to twenty-five
to thirty in the lower halves, may likewise be accounted for by disuse.
From the colourless state of the ventral surface of most fishes and of
many other animals, we may reasonably suppose that the absence of colour
in flat-fish on the side, whether it be the right or left, which is
under-most, is due to the exclusion of light. But it cannot be supposed
that the peculiar speckled appearance of the upper side of the sole, so
like the sandy bed of the sea, or the power in some species, as recently
shown by Pouchet, of changing their colour in accordance with the
surrounding surface, or the presence of bony tubercles on the upper side
of the turbot, are due to the action of the light. Here natural selection
has probably come into play, as well as in adapting the general shape of
the body of these fishes, and many other peculiarities, to their habits of
life. We should keep in mind, as I have before insisted, that the
inherited effects of the increased use of parts, and perhaps of their
disuse, will be strengthened by natural selection. For all spontaneous
variations in the right direction will thus be preserved; as will those
individuals which inherit in the highest degree the effects of the
increased and beneficial use of any part. How much to attribute in each
particular case to the effects of use, and how much to natural selection,
it seems impossible to decide.</p>
<p>I may give another instance of a structure which apparently owes its
origin exclusively to use or habit. The extremity of the tail in some
American monkeys has been converted into a wonderfully perfect prehensile
organ, and serves as a fifth hand. A reviewer, who agrees with Mr. Mivart
in every detail, remarks on this structure: "It is impossible to believe
that in any number of ages the first slight incipient tendency to grasp
could preserve the lives of the individuals possessing it, or favour their
chance of having and of rearing offspring." But there is no necessity for
any such belief. Habit, and this almost implies that some benefit great or
small is thus derived, would in all probability suffice for the work.
Brehm saw the young of an African monkey (Cercopithecus) clinging to the
under surface of their mother by their hands, and at the same time they
hooked their little tails round that of their mother. Professor Henslow
kept in confinement some harvest mice (Mus messorius) which do not possess
a structurally prehensive tail; but he frequently observed that they
curled their tails round the branches of a bush placed in the cage, and
thus aided themselves in climbing. I have received an analogous account
from Dr. Gunther, who has seen a mouse thus suspend itself. If the harvest
mouse had been more strictly arboreal, it would perhaps have had its tail
rendered structurally prehensile, as is the case with some members of the
same order. Why Cercopithecus, considering its habits while young, has not
become thus provided, it would be difficult to say. It is, however,
possible that the long tail of this monkey may be of more service to it as
a balancing organ in making its prodigious leaps, than as a prehensile
organ.</p>
<p>The mammary glands are common to the whole class of mammals, and are
indispensable for their existence; they must, therefore, have been
developed at an extremely remote period, and we can know nothing
positively about their manner of development. Mr. Mivart asks: "Is it
conceivable that the young of any animal was ever saved from destruction
by accidentally sucking a drop of scarcely nutritious fluid from an
accidentally hypertrophied cutaneous gland of its mother? And even if one
was so, what chance was there of the perpetuation of such a variation?"
But the case is not here put fairly. It is admitted by most evolutionists
that mammals are descended from a marsupial form; and if so, the mammary
glands will have been at first developed within the marsupial sack. In the
case of the fish (Hippocampus) the eggs are hatched, and the young are
reared for a time, within a sack of this nature; and an American
naturalist, Mr. Lockwood, believes from what he has seen of the
development of the young, that they are nourished by a secretion from the
cutaneous glands of the sack. Now, with the early progenitors of mammals,
almost before they deserved to be thus designated, is it not at least
possible that the young might have been similarly nourished? And in this
case, the individuals which secreted a fluid, in some degree or manner the
most nutritious, so as to partake of the nature of milk, would in the long
run have reared a larger number of well-nourished offspring, than would
the individuals which secreted a poorer fluid; and thus the cutaneous
glands, which are the homologues of the mammary glands, would have been
improved or rendered more effective. It accords with the widely extended
principle of specialisation, that the glands over a certain space of the
sack should have become more highly developed than the remainder; and they
would then have formed a breast, but at first without a nipple, as we see
in the Ornithorhyncus, at the base of the mammalian series. Through what
agency the glands over a certain space became more highly specialised than
the others, I will not pretend to decide, whether in part through
compensation of growth, the effects of use, or of natural selection.</p>
<p>The development of the mammary glands would have been of no service, and
could not have been affected through natural selection, unless the young
at the same time were able to partake of the secretion. There is no
greater difficulty in understanding how young mammals have instinctively
learned to suck the breast, than in understanding how unhatched chickens
have learned to break the egg-shell by tapping against it with their
specially adapted beaks; or how a few hours after leaving the shell they
have learned to pick up grains of food. In such cases the most probable
solution seems to be, that the habit was at first acquired by practice at
a more advanced age, and afterwards transmitted to the offspring at an
earlier age. But the young kangaroo is said not to suck, only to cling to
the nipple of its mother, who has the power of injecting milk into the
mouth of her helpless, half-formed offspring. On this head Mr. Mivart
remarks: "Did no special provision exist, the young one must infallibly be
choked by the intrusion of the milk into the wind-pipe. But there IS a
special provision. The larynx is so elongated that it rises up into the
posterior end of the nasal passage, and is thus enabled to give free
entrance to the air for the lungs, while the milk passes harmlessly on
each side of this elongated larynx, and so safely attains the gullet
behind it." Mr. Mivart then asks how did natural selection remove in the
adult kangaroo (and in most other mammals, on the assumption that they are
descended from a marsupial form), "this at least perfectly innocent and
harmless structure?" It may be suggested in answer that the voice, which
is certainly of high importance to many animals, could hardly have been
used with full force as long as the larynx entered the nasal passage; and
Professor Flower has suggested to me that this structure would have
greatly interfered with an animal swallowing solid food.</p>
<p>We will now turn for a short space to the lower divisions of the animal
kingdom. The Echinodermata (star-fishes, sea-urchins, etc.) are furnished
with remarkable organs, called pedicellariae, which consist, when well
developed, of a tridactyle forceps—that is, of one formed of three
serrated arms, neatly fitting together and placed on the summit of a
flexible stem, moved by muscles. These forceps can seize firmly hold of
any object; and Alexander Agassiz has seen an Echinus or sea-urchin
rapidly passing particles of excrement from forceps to forceps down
certain lines of its body, in order that its shell should not be fouled.
But there is no doubt that besides removing dirt of all kinds, they
subserve other functions; and one of these apparently is defence.</p>
<p>With respect to these organs, Mr. Mivart, as on so many previous
occasions, asks: "What would be the utility of the FIRST RUDIMENTARY
BEGINNINGS of such structures, and how could such insipient buddings have
ever preserved the life of a single Echinus?" He adds, "not even the
SUDDEN development of the snapping action would have been beneficial
without the freely movable stalk, nor could the latter have been efficient
without the snapping jaws, yet no minute, nearly indefinite variations
could simultaneously evolve these complex co-ordinations of structure; to
deny this seems to do no less than to affirm a startling paradox."
Paradoxical as this may appear to Mr. Mivart, tridactyle forcepses,
immovably fixed at the base, but capable of a snapping action, certainly
exist on some star-fishes; and this is intelligible if they serve, at
least in part, as a means of defence. Mr. Agassiz, to whose great kindness
I am indebted for much information on the subject, informs me that there
are other star-fishes, in which one of the three arms of the forceps is
reduced to a support for the other two; and again, other genera in which
the third arm is completely lost. In Echinoneus, the shell is described by
M. Perrier as bearing two kinds of pedicellariae, one resembling those of
Echinus, and the other those of Spatangus; and such cases are always
interesting as affording the means of apparently sudden transitions,
through the abortion of one of the two states of an organ.</p>
<p>With respect to the steps by which these curious organs have been evolved,
Mr. Agassiz infers from his own researches and those of Mr. Muller, that
both in star-fishes and sea-urchins the pedicellariae must undoubtedly be
looked at as modified spines. This may be inferred from their manner of
development in the individual, as well as from a long and perfect series
of gradations in different species and genera, from simple granules to
ordinary spines, to perfect tridactyle pedicellariae. The gradation
extends even to the manner in which ordinary spines and the pedicellariae,
with their supporting calcareous rods, are articulated to the shell. In
certain genera of star-fishes, "the very combinations needed to show that
the pedicellariae are only modified branching spines" may be found. Thus
we have fixed spines, with three equi-distant, serrated, movable branches,
articulated to near their bases; and higher up, on the same spine, three
other movable branches. Now when the latter arise from the summit of a
spine they form, in fact, a rude tridactyle pedicellariae, and such may be
seen on the same spine together with the three lower branches. In this
case the identity in nature between the arms of the pedicellariae and the
movable branches of a spine, is unmistakable. It is generally admitted
that the ordinary spines serve as a protection; and if so, there can be no
reason to doubt that those furnished with serrated and movable branches
likewise serve for the same purpose; and they would thus serve still more
effectively as soon as by meeting together they acted as a prehensile or
snapping apparatus. Thus every gradation, from an ordinary fixed spine to
a fixed pedicellariae, would be of service.</p>
<p>In certain genera of star-fishes these organs, instead of being fixed or
borne on an immovable support, are placed on the summit of a flexible and
muscular, though short, stem; and in this case they probably subserve some
additional function besides defence. In the sea-urchins the steps can be
followed by which a fixed spine becomes articulated to the shell, and is
thus rendered movable. I wish I had space here to give a fuller abstract
of Mr. Agassiz's interesting observations on the development of the
pedicellariae. All possible gradations, as he adds, may likewise be found
between the pedicellariae of the star-fishes and the hooks of the
Ophiurians, another group of the Echinodermata; and again between the
pedicellariae of sea-urchins and the anchors of the Holothuriae, also
belonging to the same great class.</p>
<p>Certain compound animals, or zoophytes, as they have been termed, namely
the Polyzoa, are provided with curious organs called avicularia. These
differ much in structure in the different species. In their most perfect
condition they curiously resemble the head and beak of a vulture in
miniature, seated on a neck and capable of movement, as is likewise the
lower jaw or mandible. In one species observed by me, all the avicularia
on the same branch often moved simultaneously backwards and forwards, with
the lower jaw widely open, through an angle of about 90 degrees, in the
course of five seconds; and their movement caused the whole polyzoary to
tremble. When the jaws are touched with a needle they seize it so firmly
that the branch can thus be shaken.</p>
<p>Mr. Mivart adduces this case, chiefly on account of the supposed
difficulty of organs, namely the avicularia of the Polyzoa and the
pedicellariae of the Echinodermata, which he considers as "essentially
similar," having been developed through natural selection in widely
distinct divisions of the animal kingdom. But, as far as structure is
concerned, I can see no similarity between tridactyle pedicellariae and
avicularia. The latter resembles somewhat more closely the chelae or
pincers of Crustaceans; and Mr. Mivart might have adduced with equal
appropriateness this resemblance as a special difficulty, or even their
resemblance to the head and beak of a bird. The avicularia are believed by
Mr. Busk, Dr. Smitt and Dr. Nitsche—naturalists who have carefully
studied this group—to be homologous with the zooids and their cells
which compose the zoophyte, the movable lip or lid of the cell
corresponding with the lower and movable mandible of the avicularium. Mr.
Busk, however, does not know of any gradations now existing between a
zooid and an avicularium. It is therefore impossible to conjecture by what
serviceable gradations the one could have been converted into the other,
but it by no means follows from this that such gradations have not
existed.</p>
<p>As the chelae of Crustaceans resemble in some degree the avicularia of
Polyzoa, both serving as pincers, it may be worth while to show that with
the former a long series of serviceable gradations still exists. In the
first and simplest stage, the terminal segment of a limb shuts down either
on the square summit of the broad penultimate segment, or against one
whole side, and is thus enabled to catch hold of an object, but the limb
still serves as an organ of locomotion. We next find one corner of the
broad penultimate segment slightly prominent, sometimes furnished with
irregular teeth, and against these the terminal segment shuts down. By an
increase in the size of this projection, with its shape, as well as that
of the terminal segment, slightly modified and improved, the pincers are
rendered more and more perfect, until we have at last an instrument as
efficient as the chelae of a lobster. And all these gradations can be
actually traced.</p>
<p>Besides the avicularia, the polyzoa possess curious organs called
vibracula. These generally consist of long bristles, capable of movement
and easily excited. In one species examined by me the vibracula were
slightly curved and serrated along the outer margin, and all of them on
the same polyzoary often moved simultaneously; so that, acting like long
oars, they swept a branch rapidly across the object-glass of my
microscope. When a branch was placed on its face, the vibracula became
entangled, and they made violent efforts to free themselves. They are
supposed to serve as a defence, and may be seen, as Mr. Busk remarks, "to
sweep slowly and carefully over the surface of the polyzoary, removing
what might be noxious to the delicate inhabitants of the cells when their
tentacula are protruded." The avicularia, like the vibracula, probably
serve for defence, but they also catch and kill small living animals,
which, it is believed, are afterwards swept by the currents within reach
of the tentacula of the zooids. Some species are provided with avicularia
and vibracula, some with avicularia alone and a few with vibracula alone.</p>
<p>It is not easy to imagine two objects more widely different in appearance
than a bristle or vibraculum, and an avicularium like the head of a bird;
yet they are almost certainly homologous and have been developed from the
same common source, namely a zooid with its cell. Hence, we can understand
how it is that these organs graduate in some cases, as I am informed by
Mr. Busk, into each other. Thus, with the avicularia of several species of
Lepralia, the movable mandible is so much produced and is so like a
bristle that the presence of the upper or fixed beak alone serves to
determine its avicularian nature. The vibracula may have been directly
developed from the lips of the cells, without having passed through the
avicularian stage; but it seems more probable that they have passed
through this stage, as during the early stages of the transformation, the
other parts of the cell, with the included zooid, could hardly have
disappeared at once. In many cases the vibracula have a grooved support at
the base, which seems to represent the fixed beak; though this support in
some species is quite absent. This view of the development of the
vibracula, if trustworthy, is interesting; for supposing that all the
species provided with avicularia had become extinct, no one with the most
vivid imagination would ever have thought that the vibracula had
originally existed as part of an organ, resembling a bird's head, or an
irregular box or hood. It is interesting to see two such widely different
organs developed from a common origin; and as the movable lip of the cell
serves as a protection to the zooid, there is no difficulty in believing
that all the gradations, by which the lip became converted first into the
lower mandible of an avicularium, and then into an elongated bristle,
likewise served as a protection in different ways and under different
circumstances.</p>
<p>In the vegetable kingdom Mr. Mivart only alludes to two cases, namely the
structure of the flowers of orchids, and the movements of climbing plants.
With respect to the former, he says: "The explanation of their ORIGIN is
deemed thoroughly unsatisfactory—utterly insufficient to explain the
incipient, infinitesimal beginnings of structures which are of utility
only when they are considerably developed." As I have fully treated this
subject in another work, I will here give only a few details on one alone
of the most striking peculiarities of the flowers of orchids, namely,
their pollinia. A pollinium, when highly developed, consists of a mass of
pollen-grains, affixed to an elastic foot-stalk or caudicle, and this to a
little mass of extremely viscid matter. The pollinia are by this means
transported by insects from one flower to the stigma of another. In some
orchids there is no caudicle to the pollen-masses, and the grains are
merely tied together by fine threads; but as these are not confined to
orchids, they need not here be considered; yet I may mention that at the
base of the orchidaceous series, in Cypripedium, we can see how the
threads were probably first developed. In other orchids the threads cohere
at one end of the pollen-masses; and this forms the first or nascent trace
of a caudicle. That this is the origin of the caudicle, even when of
considerable length and highly developed, we have good evidence in the
aborted pollen-grains which can sometimes be detected embedded within the
central and solid parts.</p>
<p>With respect to the second chief peculiarity, namely, the little mass of
viscid matter attached to the end of the caudicle, a long series of
gradations can be specified, each of plain service to the plant. In most
flowers belonging to other orders the stigma secretes a little viscid
matter. Now, in certain orchids similar viscid matter is secreted, but in
much larger quantities by one alone of the three stigmas; and this stigma,
perhaps in consequence of the copious secretion, is rendered sterile. When
an insect visits a flower of this kind, it rubs off some of the viscid
matter, and thus at the same time drags away some of the pollen-grains.
From this simple condition, which differs but little from that of a
multitude of common flowers, there are endless gradations—to species
in which the pollen-mass terminates in a very short, free caudicle—to
others in which the caudicle becomes firmly attached to the viscid matter,
with the sterile stigma itself much modified. In this latter case we have
a pollinium in its most highly developed and perfect condition. He who
will carefully examine the flowers of orchids for himself will not deny
the existence of the above series of gradations—from a mass of
pollen-grains merely tied together by threads, with the stigma differing
but little from that of the ordinary flowers, to a highly complex
pollinium, admirably adapted for transportal by insects; nor will he deny
that all the gradations in the several species are admirably adapted in
relation to the general structure of each flower for its fertilisation by
different insects. In this, and in almost every other case, the enquiry
may be pushed further backwards; and it may be asked how did the stigma of
an ordinary flower become viscid, but as we do not know the full history
of any one group of beings, it is as useless to ask, as it is hopeless to
attempt answering, such questions.</p>
<p>We will now turn to climbing plants. These can be arranged in a long
series, from those which simply twine round a support, to those which I
have called leaf-climbers, and to those provided with tendrils. In these
two latter classes the stems have generally, but not always, lost the
power of twining, though they retain the power of revolving, which the
tendrils likewise possess. The gradations from leaf-climbers to tendril
bearers are wonderfully close, and certain plants may be differently
placed in either class. But in ascending the series from simple twiners to
leaf-climbers, an important quality is added, namely sensitiveness to a
touch, by which means the foot-stalks of the leaves or flowers, or these
modified and converted into tendrils, are excited to bend round and clasp
the touching object. He who will read my memoir on these plants will, I
think, admit that all the many gradations in function and structure
between simple twiners and tendril-bearers are in each case beneficial in
a high degree to the species. For instance, it is clearly a great
advantage to a twining plant to become a leaf-climber; and it is probable
that every twiner which possessed leaves with long foot-stalks would have
been developed into a leaf-climber, if the foot-stalks had possessed in
any slight degree the requisite sensitiveness to a touch.</p>
<p>As twining is the simplest means of ascending a support, and forms the
basis of our series, it may naturally be asked how did plants acquire this
power in an incipient degree, afterwards to be improved and increased
through natural selection. The power of twining depends, firstly, on the
stems while young being extremely flexible (but this is a character common
to many plants which are not climbers); and, secondly, on their
continually bending to all points of the compass, one after the other in
succession, in the same order. By this movement the stems are inclined to
all sides, and are made to move round and round. As soon as the lower part
of a stem strikes against any object and is stopped, the upper part still
goes on bending and revolving, and thus necessarily twines round and up
the support. The revolving movement ceases after the early growth of each
shoot. As in many widely separated families of plants, single species and
single genera possess the power of revolving, and have thus become
twiners, they must have independently acquired it, and cannot have
inherited it from a common progenitor. Hence, I was led to predict that
some slight tendency to a movement of this kind would be found to be far
from uncommon with plants which did not climb; and that this had afforded
the basis for natural selection to work on and improve. When I made this
prediction, I knew of only one imperfect case, namely, of the young
flower-peduncles of a Maurandia which revolved slightly and irregularly,
like the stems of twining plants, but without making any use of this
habit. Soon afterwards Fritz Muller discovered that the young stems of an
Alisma and of a Linum—plants which do not climb and are widely
separated in the natural system—revolved plainly, though
irregularly, and he states that he has reason to suspect that this occurs
with some other plants. These slight movements appear to be of no service
to the plants in question; anyhow, they are not of the least use in the
way of climbing, which is the point that concerns us. Nevertheless we can
see that if the stems of these plants had been flexible, and if under the
conditions to which they are exposed it had profited them to ascend to a
height, then the habit of slightly and irregularly revolving might have
been increased and utilised through natural selection, until they had
become converted into well-developed twining species.</p>
<p>With respect to the sensitiveness of the foot-stalks of the leaves and
flowers, and of tendrils, nearly the same remarks are applicable as in the
case of the revolving movements of twining plants. As a vast number of
species, belonging to widely distinct groups, are endowed with this kind
of sensitiveness, it ought to be found in a nascent condition in many
plants which have not become climbers. This is the case: I observed that
the young flower-peduncles of the above Maurandia curved themselves a
little towards the side which was touched. Morren found in several species
of Oxalis that the leaves and their foot-stalks moved, especially after
exposure to a hot sun, when they were gently and repeatedly touched, or
when the plant was shaken. I repeated these observations on some other
species of Oxalis with the same result; in some of them the movement was
distinct, but was best seen in the young leaves; in others it was
extremely slight. It is a more important fact that according to the high
authority of Hofmeister, the young shoots and leaves of all plants move
after being shaken; and with climbing plants it is, as we know, only
during the early stages of growth that the foot-stalks and tendrils are
sensitive.</p>
<p>It is scarcely possible that the above slight movements, due to a touch or
shake, in the young and growing organs of plants, can be of any functional
importance to them. But plants possess, in obedience to various stimuli,
powers of movement, which are of manifest importance to them; for
instance, towards and more rarely from the light—in opposition to,
and more rarely in the direction of, the attraction of gravity. When the
nerves and muscles of an animal are excited by galvanism or by the
absorption of strychnine, the consequent movements may be called an
incidental result, for the nerves and muscles have not been rendered
specially sensitive to these stimuli. So with plants it appears that, from
having the power of movement in obedience to certain stimuli, they are
excited in an incidental manner by a touch, or by being shaken. Hence
there is no great difficulty in admitting that in the case of
leaf-climbers and tendril-bearers, it is this tendency which has been
taken advantage of and increased through natural selection. It is,
however, probable, from reasons which I have assigned in my memoir, that
this will have occurred only with plants which had already acquired the
power of revolving, and had thus become twiners.</p>
<p>I have already endeavoured to explain how plants became twiners, namely,
by the increase of a tendency to slight and irregular revolving movements,
which were at first of no use to them; this movement, as well as that due
to a touch or shake, being the incidental result of the power of moving,
gained for other and beneficial purposes. Whether, during the gradual
development of climbing plants, natural selection has been aided by the
inherited effects of use, I will not pretend to decide; but we know that
certain periodical movements, for instance the so-called sleep of plants,
are governed by habit.</p>
<p>I have now considered enough, perhaps more than enough, of the cases,
selected with care by a skilful naturalist, to prove that natural
selection is incompetent to account for the incipient stages of useful
structures; and I have shown, as I hope, that there is no great difficulty
on this head. A good opportunity has thus been afforded for enlarging a
little on gradations of structure, often associated with strange functions—an
important subject, which was not treated at sufficient length in the
former editions of this work. I will now briefly recapitulate the
foregoing cases.</p>
<p>With the giraffe, the continued preservation of the individuals of some
extinct high-reaching ruminant, which had the longest necks, legs, etc.,
and could browse a little above the average height, and the continued
destruction of those which could not browse so high, would have sufficed
for the production of this remarkable quadruped; but the prolonged use of
all the parts, together with inheritance, will have aided in an important
manner in their co-ordination. With the many insects which imitate various
objects, there is no improbability in the belief that an accidental
resemblance to some common object was in each case the foundation for the
work of natural selection, since perfected through the occasional
preservation of slight variations which made the resemblance at all
closer; and this will have been carried on as long as the insect continued
to vary, and as long as a more and more perfect resemblance led to its
escape from sharp-sighted enemies. In certain species of whales there is a
tendency to the formation of irregular little points of horn on the
palate; and it seems to be quite within the scope of natural selection to
preserve all favourable variations, until the points were converted, first
into lamellated knobs or teeth, like those on the beak of a goose—then
into short lamellae, like those of the domestic ducks—and then into
lamellae, as perfect as those of the shoveller-duck—and finally into
the gigantic plates of baleen, as in the mouth of the Greenland whale. In
the family of the ducks, the lamellae are first used as teeth, then partly
as teeth and partly as a sifting apparatus, and at last almost exclusively
for this latter purpose.</p>
<p>With such structures as the above lamellae of horn or whalebone, habit or
use can have done little or nothing, as far as we can judge, towards their
development. On the other hand, the transportal of the lower eye of a
flat-fish to the upper side of the head, and the formation of a prehensile
tail, may be attributed almost wholly to continued use, together with
inheritance. With respect to the mammae of the higher animals, the most
probable conjecture is that primordially the cutaneous glands over the
whole surface of a marsupial sack secreted a nutritious fluid; and that
these glands were improved in function through natural selection, and
concentrated into a confined area, in which case they would have formed a
mamma. There is no more difficulty in understanding how the branched
spines of some ancient Echinoderm, which served as a defence, became
developed through natural selection into tridactyle pedicellariae, than in
understanding the development of the pincers of crustaceans, through
slight, serviceable modifications in the ultimate and penultimate segments
of a limb, which was at first used solely for locomotion. In the
avicularia and vibracula of the Polyzoa we have organs widely different in
appearance developed from the same source; and with the vibracula we can
understand how the successive gradations might have been of service. With
the pollinia of orchids, the threads which originally served to tie
together the pollen-grains, can be traced cohering into caudicles; and the
steps can likewise be followed by which viscid matter, such as that
secreted by the stigmas of ordinary flowers, and still subserving nearly
but not quite the same purpose, became attached to the free ends of the
caudicles—all these gradations being of manifest benefit to the
plants in question. With respect to climbing plants, I need not repeat
what has been so lately said.</p>
<p>It has often been asked, if natural selection be so potent, why has not
this or that structure been gained by certain species, to which it would
apparently have been advantageous? But it is unreasonable to expect a
precise answer to such questions, considering our ignorance of the past
history of each species, and of the conditions which at the present day
determine its numbers and range. In most cases only general reasons, but
in some few cases special reasons, can be assigned. Thus to adapt a
species to new habits of life, many co-ordinated modifications are almost
indispensable, and it may often have happened that the requisite parts did
not vary in the right manner or to the right degree. Many species must
have been prevented from increasing in numbers through destructive
agencies, which stood in no relation to certain structures, which we
imagine would have been gained through natural selection from appearing to
us advantageous to the species. In this case, as the struggle for life did
not depend on such structures, they could not have been acquired through
natural selection. In many cases complex and long-enduring conditions,
often of a peculiar nature, are necessary for the development of a
structure; and the requisite conditions may seldom have concurred. The
belief that any given structure, which we think, often erroneously, would
have been beneficial to a species, would have been gained under all
circumstances through natural selection, is opposed to what we can
understand of its manner of action. Mr. Mivart does not deny that natural
selection has effected something; but he considers it as "demonstrably
insufficient" to account for the phenomena which I explain by its agency.
His chief arguments have now been considered, and the others will
hereafter be considered. They seem to me to partake little of the
character of demonstration, and to have little weight in comparison with
those in favour of the power of natural selection, aided by the other
agencies often specified. I am bound to add, that some of the facts and
arguments here used by me, have been advanced for the same purpose in an
able article lately published in the "Medico-Chirurgical Review."</p>
<p>At the present day almost all naturalists admit evolution under some form.
Mr. Mivart believes that species change through "an internal force or
tendency," about which it is not pretended that anything is known. That
species have a capacity for change will be admitted by all evolutionists;
but there is no need, as it seems to me, to invoke any internal force
beyond the tendency to ordinary variability, which through the aid of
selection, by man has given rise to many well-adapted domestic races, and
which, through the aid of natural selection, would equally well give rise
by graduated steps to natural races or species. The final result will
generally have been, as already explained, an advance, but in some few
cases a retrogression, in organisation.</p>
<p>Mr. Mivart is further inclined to believe, and some naturalists agree with
him, that new species manifest themselves "with suddenness and by
modifications appearing at once." For instance, he supposes that the
differences between the extinct three-toed Hipparion and the horse arose
suddenly. He thinks it difficult to believe that the wing of a bird "was
developed in any other way than by a comparatively sudden modification of
a marked and important kind;" and apparently he would extend the same view
to the wings of bats and pterodactyles. This conclusion, which implies
great breaks or discontinuity in the series, appears to me improbable in
the highest degree.</p>
<p>Everyone who believes in slow and gradual evolution, will of course admit
that specific changes may have been as abrupt and as great as any single
variation which we meet with under nature, or even under domestication.
But as species are more variable when domesticated or cultivated than
under their natural conditions, it is not probable that such great and
abrupt variations have often occurred under nature, as are known
occasionally to arise under domestication. Of these latter variations
several may be attributed to reversion; and the characters which thus
reappear were, it is probable, in many cases at first gained in a gradual
manner. A still greater number must be called monstrosities, such as
six-fingered men, porcupine men, Ancon sheep, Niata cattle, etc.; and as
they are widely different in character from natural species, they throw
very little light on our subject. Excluding such cases of abrupt
variations, the few which remain would at best constitute, if found in a
state of nature, doubtful species, closely related to their parental
types.</p>
<p>My reasons for doubting whether natural species have changed as abruptly
as have occasionally domestic races, and for entirely disbelieving that
they have changed in the wonderful manner indicated by Mr. Mivart, are as
follows. According to our experience, abrupt and strongly marked
variations occur in our domesticated productions, singly and at rather
long intervals of time. If such occurred under nature, they would be
liable, as formerly explained, to be lost by accidental causes of
destruction and by subsequent intercrossing; and so it is known to be
under domestication, unless abrupt variations of this kind are specially
preserved and separated by the care of man. Hence, in order that a new
species should suddenly appear in the manner supposed by Mr. Mivart, it is
almost necessary to believe, in opposition to all analogy, that several
wonderfully changed individuals appeared simultaneously within the same
district. This difficulty, as in the case of unconscious selection by man,
is avoided on the theory of gradual evolution, through the preservation of
a large number of individuals, which varied more or less in any favourable
direction, and of the destruction of a large number which varied in an
opposite manner.</p>
<p>That many species have been evolved in an extremely gradual manner, there
can hardly be a doubt. The species and even the genera of many large
natural families are so closely allied together that it is difficult to
distinguish not a few of them. On every continent, in proceeding from
north to south, from lowland to upland, etc., we meet with a host of
closely related or representative species; as we likewise do on certain
distinct continents, which we have reason to believe were formerly
connected. But in making these and the following remarks, I am compelled
to allude to subjects hereafter to be discussed. Look at the many outlying
islands round a continent, and see how many of their inhabitants can be
raised only to the rank of doubtful species. So it is if we look to past
times, and compare the species which have just passed away with those
still living within the same areas; or if we compare the fossil species
embedded in the sub-stages of the same geological formation. It is indeed
manifest that multitudes of species are related in the closest manner to
other species that still exist, or have lately existed; and it will hardly
be maintained that such species have been developed in an abrupt or sudden
manner. Nor should it be forgotten, when we look to the special parts of
allied species, instead of to distinct species, that numerous and
wonderfully fine gradations can be traced, connecting together widely
different structures.</p>
<p>Many large groups of facts are intelligible only on the principle that
species have been evolved by very small steps. For instance, the fact that
the species included in the larger genera are more closely related to each
other, and present a greater number of varieties than do the species in
the smaller genera. The former are also grouped in little clusters, like
varieties round species; and they present other analogies with varieties,
as was shown in our second chapter. On this same principle we can
understand how it is that specific characters are more variable than
generic characters; and how the parts which are developed in an
extraordinary degree or manner are more variable than other parts of the
same species. Many analogous facts, all pointing in the same direction,
could be added.</p>
<p>Although very many species have almost certainly been produced by steps
not greater than those separating fine varieties; yet it may be maintained
that some have been developed in a different and abrupt manner. Such an
admission, however, ought not to be made without strong evidence being
assigned. The vague and in some respects false analogies, as they have
been shown to be by Mr. Chauncey Wright, which have been advanced in
favour of this view, such as the sudden crystallisation of inorganic
substances, or the falling of a facetted spheroid from one facet to
another, hardly deserve consideration. One class of facts, however,
namely, the sudden appearance of new and distinct forms of life in our
geological formations supports at first sight the belief in abrupt
development. But the value of this evidence depends entirely on the
perfection of the geological record, in relation to periods remote in the
history of the world. If the record is as fragmentary as many geologists
strenuously assert, there is nothing strange in new forms appearing as if
suddenly developed.</p>
<p>Unless we admit transformations as prodigious as those advocated by Mr.
Mivart, such as the sudden development of the wings of birds or bats, or
the sudden conversion of a Hipparion into a horse, hardly any light is
thrown by the belief in abrupt modifications on the deficiency of
connecting links in our geological formations. But against the belief in
such abrupt changes, embryology enters a strong protest. It is notorious
that the wings of birds and bats, and the legs of horses or other
quadrupeds, are undistinguishable at an early embryonic period, and that
they become differentiated by insensibly fine steps. Embryological
resemblances of all kinds can be accounted for, as we shall hereafter see,
by the progenitors of our existing species having varied after early
youth, and having transmitted their newly-acquired characters to their
offspring, at a corresponding age. The embryo is thus left almost
unaffected, and serves as a record of the past condition of the species.
Hence it is that existing species during the early stages of their
development so often resemble ancient and extinct forms belonging to the
same class. On this view of the meaning of embryological resemblances, and
indeed on any view, it is incredible that an animal should have undergone
such momentous and abrupt transformations as those above indicated, and
yet should not bear even a trace in its embryonic condition of any sudden
modification, every detail in its structure being developed by insensibly
fine steps.</p>
<p>He who believes that some ancient form was transformed suddenly through an
internal force or tendency into, for instance, one furnished with wings,
will be almost compelled to assume, in opposition to all analogy, that
many individuals varied simultaneously. It cannot be denied that such
abrupt and great changes of structure are widely different from those
which most species apparently have undergone. He will further be compelled
to believe that many structures beautifully adapted to all the other parts
of the same creature and to the surrounding conditions, have been suddenly
produced; and of such complex and wonderful co-adaptations, he will not be
able to assign a shadow of an explanation. He will be forced to admit that
these great and sudden transformations have left no trace of their action
on the embryo. To admit all this is, as it seems to me, to enter into the
realms of miracle, and to leave those of science.</p>
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