Comparison with 1869 |
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identically the identically the 1866 1869 | the 1859 1860 1861 1872 |
same, same, 1866 1869 1872 | same 1859 1860 1861 |
yet some fundamental difference between them can always, or almost always, be detected. yet some fundamental difference between them can always, or almost always, be detected. 1866 1869 |
manner two parts in two organic beings, which owe but little of their structure in common to inheritance from the same ancestor. 1859 |
manner two parts in two organic beings, which beings owe but little of their structure in common to inheritance from the same ancestor. 1860 1861 |
yet fundamental differences between them can always be detected. 1872 |
↑10 blocks not present in 1859 1860 1861 1866 1869; present in 1872 | 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.
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I am inclined to believe that in nearly
the same way as two men have sometimes independently hit on the very same
invention, so natural
selection, working for the good of each being
and taking advantage of analogous
variations, has sometimes modified in very nearly the same manner two parts in two
organic
beings, which owe but little
of their structure in common to inheritance from the same ancestor. |
|
Fritz Müller, in a remarkable work recently published, has discussed a case nearly parallel with that of electric fishes, luminous insects, &c.; he undertook the laborious examination of this case in
order to test the views advanced by me
in this volume. Several families of crustaceans include a few members which are
fitted to live out of the water
and possess an air-breathing apparatus.
In two of these families, which were more especially examined by Müller, and which are nearly related to each other, the species agree most closely in all important characters:
namely in the structure of
their sense-organs, in their heart and system of circulation,
in the position of every
tuft
of hair with which their stomachs, equally complicated in both cases, are lined,
and lastly in the water-breathing
branchiæ, even to the microscopical hooks by which they are cleansed. Hence it might have been expected from mere analogy that the equally important air-breathing apparatus would have been the same
in the few species in
both families which are thus furnished; and this might
have been the more confidently expected by those who believe in the creation of each separate species;
for why should this one apparatus, given for the same special
purpose
to a few species which are so closely similar or rather identical in all
other important
points, have been made to differ?
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|
Fritz Müller then
argued
to himself
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 the main body of crustaceans of all orders,
are aquatic in their habits, it is improbable in the highest degree, that their common progenitor should have been adapted for breathing air. Müller was thus led carefully to examine and describe
the apparatus in the few
air-breathing species; and in each he found it to differ 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 anticipated,
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 differ
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 conditions, the variability of these crustaceans
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. ↑1 blocks not present in 1859 1860 1861 1869 1872; present in 1866 | Now, on the belief that species belonging to distinct families, already differing in some characters, and which whenever they varied would probably have varied in different manners, have been slowly adapted through natural selection to live more and more out of water and to breathe the air, it is quite intelligible, and might even have been con- fidently expected, that the structural contrivances thus acquired would in each case have materially differed, although serving for the same purpose.
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On the hypothesis of separate acts of creation the whole case must
remain
unintelligible,
and we can only say, so it is.
This
line of argument
seems
to have had great weight in leading this distinguished naturalist fully
to accept the views maintained by me in this volume. |
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In the several
cases
just discussed, we have seen that
in beings more or less
remotely allied, the same end is gained and the same function performed
by organs in appearance, though not in truth,
closely similar. But
the common
rule throughout nature is
that the same end is
gained, even sometimes in the case of beings
closely related to
each other,
by the most diversified means. How differently constructed is the feathered wing of a bird and the membrane-covered wing of a bat
with all its fingers developed;
and still more so the four wings of a butterfly, the two wings of a fly, and the two of a bettle with their elytra.
Bivalve shells have only
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 or by
their capsule being converted into a light ballon-like
envelope; or 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; or by
having hooks and grapnels of many kinds and serrated awns, so as to adhere to the fur of quadrupeds; or
by being furnished with wings and plumes, as diversified
in shape as elegant
in structure, so as to be wafted by every breeze. I will give one other instance; for the
subject is worthy of reflection by those who are not able to credit that organic beings have been formed in many ways for
the sake
of mere variety, like toys in a shop. 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 light
and incoherent
pollen-grains
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 cases,
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. |
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From this simple stage we may pass through an in-exhaustible
number of contrivances, all for the same purpose and effected in essentially the same manner, but entailing changes in every part of the flower;
with the nectar
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 an acme of perfect
adaptation,
as has
lately been
described by Dr. Crüger in the case of
Coryanthes. This orchid has its
labellum or lower lip hollowed out into a great bucket, into which drops of almost pure water,
not nectar,
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 curves
over the bucket, and is itself hollowed out into a sort of chamber with two lateral entrances,
within which and outside
there are some
curious fleshy ridges. |
|
The most ingenious man, if he had not witnessed what takes place, could never have imagined what purpose all these parts served. But Dr. Crüger saw crowds of large humble-bees visiting the gigantic flowers of this orchid
in the early morning, and they came, not
to suck nectar, but to gnaw off the ridges above
the bucket;
in doing this they frequently pushed each other into the bucket, and thus
their wings were wetted, so that
they could not fly out,
but had
to crawl out through the passage formed by the spout or overflow. Dr. Crüger has seen
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 through
the passage of a lately expanded flower, and are thus carried away. Dr. Crüger sent me a flower in spirits of wine, with a bee which he had killed before it had quite crawled out of the passage
with a pollen-mass 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 the water-secreting horns,
of the bucket with its spout, and
of the shape of every part
of the flower!
The construction of the flower of
another closely allied orchid, namely Catasetum,
is widely different, though serving the same end; and is equally curious. Bees visit this
flower,
as in the case
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, antenna. The
antenna
being
touched
causes
a certain membrane to rupture through its own irritability, and
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 is
thus carried to another
flower,
where
it is brought into contact with the stigma, which is viscid enough to break certain elastic threads, and to retain the pollen-mass, which then performs its office of fertilisation.
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How, it may be asked, in the foregoing and in innumerable other and similar cases,
can we understand the cause of such a wide
scale of complexity and of such
multifarious means for gaining the same end,
both in the case of forms widely remote from each other in affinity, and with forms so closely allied as are the two orchids last described?
The answer no doubt is, as already remarked, that when two forms vary, which already differ from each other even
in a
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 must
also bear in mind that every well-developed
organism has already
passed through a long course of modification;
and that each modified structure tends to be inherited, so that it
will not readily be lost,
but may be modified
again and again. Hence the structure of each part of each species, for whatever purpose used, will be
the sum of the
many inherited changes, through which that
species has passed during its successive adaptations to changed habits and conditions of life. |
|
Finally then, although Finally then, although 1866 1869 1872 |
Although 1859 1860 1861 |
in many cases it is most difficult
even to even to 1869 1872 | to 1859 1860 1861 1866 |
conjecture by what transitions
many many 1869 | an 1859 | many 1860 1861 1866 1872 |
organs organs 1860 1861 1866 1869 1872 | organ 1859 |
....... 1866 1869 1872 | could 1859 1860 1861 |
have arrived at
their their 1860 1861 1866 1869 1872 | its 1859 |
present state; yet, considering
how small how small 1869 1872 | that 1859 1860 1861 1866 |
the proportion of living and known forms
is to the extinct and unknown, is to the extinct and unknown, 1869 1872 |
to the extinct and unknown 1859 1860 1861 |
OMIT 1866 |
...OMIT 1869 1872 |
is very small, 1859 1860 1861 |
is very small 1866 |
I
have been astonished how rarely an organ can be named, towards which no transitional grade is known to lead.
It certainly is true, that new organs appearing as if specially created for some purpose, rarely or never appear suddenly in any class; as indeed is It certainly is true, that new organs appearing as if specially created for some purpose, rarely or never appear suddenly in any class; as indeed is 1869 |
The truth of this remark is indeed 1859 1860 |
It certainly is not true, that new organs often appear suddenly in any class, as if created for some special purpose; as indeed is 1861 |
It certainly is true, that new organs very rarely or never suddenly appear in any class, as if created for some special purpose; as indeed is 1866 |
It certainly is true, that new organs appearing as if created for some special purpose, rarely or never appear in any being;— as indeed is 1872 |
shown by that
old, old, 1861 1866 1869 1872 | old 1859 1860 |
but somewhat exaggerated, canon but somewhat exaggerated, canon 1861 1866 1869 1872 |
canon 1859 |
but somewhat exaggerated canon 1860 |
in natural history of "Natura non facit saltum." We meet with this admission in the writings of almost every experienced naturalist;
or or 1869 1872 | or, 1859 1860 | or 1861 1866 |
as Milne Edwards has well expressed it,
Nature Nature 1860 1861 1866 1869 1872 | nature 1859 |
is prodigal in variety, but niggard in innovation. Why, on the theory of Creation, should
there there 1866 1869 1872 | this 1859 1860 1861 |
be
so much variety and so little novelty? so much variety and so little novelty? 1866 1869 |
so? 1859 1860 1861 |
so much variety and so little real novelty? 1872 |
Why should all the parts and organs of many independent beings, each supposed to have been separately created for its proper place in nature, be so
commonly commonly 1860 1861 1866 1869 1872 | invariably 1859 |
linked together by graduated steps? Why should not Nature
....... 1866 1869 1872 | have 1859 1860 1861 |
take take 1866 1869 1872 | taken 1859 1860 1861 |
a
sudden leap sudden leap 1866 1869 1872 | leap 1859 1860 1861 |
from structure to structure? On the theory of natural selection, we can clearly understand why she should not; for natural selection
....... 1866 1869 1872 | can 1859 1860 1861 |
acts acts 1866 1869 1872 | act 1859 1860 1861 |
only by taking advantage of slight successive variations; she can never take a
sudden leap, sudden leap, 1866 1869 |
leap, 1859 1860 1861 |
great and sudden leap, 1872 |
but must advance by
short and sure though slow short and sure though slow 1866 1869 |
the shortest and slowest 1859 1860 |
short and slow 1861 |
short and sure, though slow 1872 |
steps. |
Organs
Organs
1866 1869 1872 |
Organs
1859 1860 1861 |
of
of
1866 1869 1872 |
of
1859 1860 1861 |
little
little
1866 1869 1872 |
little
1859 1860 1861 |
apparent
apparent
1866 1869 1872 |
apparent
1859 1860 1861 |
Importance, as affected by Natural Selection.
Importance, as affected by Natural Selection. 1869 |
importance
.—
1859 1860 1861 |
Importance, as affected by Natural Selection. 1866 |
Importance, as affected by Natural Selection
. 1872 |
|
As natural selection acts by life and
death,—by death,—by 1866 1869 | death,— 1859 1860 1861 1872 |
....... 1866 1869 | by 1859 1860 1861 1872 |
the
survival survival 1869 1872 | preservation 1859 1860 1861 1866 |
of
the fittest, the fittest, 1869 1872 |
individuals with any favourable variation, 1859 1860 1861 1866 |
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. 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. 1869 |
those with any unfavourable deviation of structure,— I have sometimes felt much difficulty in understanding the origin of simple parts, of which the importance does not seem sufficient to cause the preservation of successively varying individuals. 1859 1860 1861 |
those with any unfavourable deviation of structure,—I have sometimes felt much difficulty in understanding the origin of simple parts, of which the importance does not seem sufficient to cause the preservation of successively varying individuals. 1866 |
the less well-fitted individuals, 1872 |
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