PRINCIPLES OF CLASSIFICATION--BIOLOGY FORM FIVE.
Think about
an elephant. Develop a mental image of it. How would you describe it to
someone who has never seen one? Take a moment to consider carefully . . .
Click the button to see if
your mental image was accurate.
Very likely
your mental image was a visual one like the picture. Humans primarily emphasize
traits that can be seen with their eyes since they mostly rely on their sense of
vision. However, there is no reason that an elephant or any other organism could not
be described in terms of touch, smell, and/or sound as well. Think about an elephant
again but this time in terms of non-visual traits . . .
Not surprisingly, biologists
also classify organisms into different categories
mostly by judging degrees of apparent similarity and difference that they can see.
The assumption is that the greater the degree of physical similarity, the closer the
biological relationship.
On
discovering an unknown organism, researchers begin their classification by looking for anatomical
features that appear to have the same function as those found
on other species.
The next
step is determining whether or not the
similarities are due to an
independent evolutionary development or to descent from a common ancestor. If the
latter is the case, then the two species are probably closely related and should be
classified into the same or near biological categories.
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Human arm
bones
(common bird,
mammal, and
reptile forelimb
configuration)
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Homologies
are anatomical features, of different organisms, that have a similar
appearance or function because they were inherited from a common ancestor that
also had them. For instance, the forelimb of a
bear, the wing of a bird, and your arm
have the same functional types of bones as did our shared
reptilian ancestor. Therefore, these bones are homologous
structures. The more homologies two organisms
possess, the more likely it is that they have a close genetic
relationship.
There can
also be nonhomologous structural similarities between species. In these cases, the
common ancestor did not have the same anatomical structures
as its descendants. Instead, the
similarities are due to independent development in
the now separate evolutionary lines. Such
misleading similarities are called homoplasies
.
Homoplastic structures can be the result of parallelism, convergence, or mere chance.
Parallelism
,
or parallel evolution, is a similar evolutionary
development in different species lines after divergence from a common ancestor
that did not have the characteristic but did have an initial anatomical feature that led to it.
For instance, some
South American and African monkeys evolved
relatively large body sizes independently of each other. Their common
ancestor was a much smaller monkey but was otherwise
reminiscent of the later descendant species. Apparently, nature selected for
larger monkey bodies on both continents during the last 30
million years.
Convergence
, or convergent evolution, is the development of
a similar
anatomical feature in distinct species lines after divergence from a common ancestor
that did not have the initial trait that led to it. The common
ancestor is usually more distant in time than is the case
with parallelism. The similar appearance and predatory behavior of North American wolves and Tasmanian
wolves (thylacines) is an example. The former is a placental
mammal like humans and the latter is an Australian marsupial
like kangaroos.
Their common ancestor lived during the age of the dinosaurs
125 million
years ago and was very different from these descendants today.
There are, in fact, a number of other Australian marsupials that are
striking examples of convergent evolution with placental mammals elsewhere.
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Australian
Tasmanian wolf or tiger
(now extinct)
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North American wolf
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Both parallelism and convergence are thought to be due
primarily to separate species lines experiencing the same kinds of natural
selection pressures over long periods of time.
Analogies
are anatomical features that have the same
form or function in
different species that have no known common ancestor.
For instance, the wings of a bird and a butterfly are analogous structures
because they are superficially similar in shape and
function. Both of these very distinct species
lines solved the problem of getting off of the ground in essentially the same
way.
However, their wings are quite different on the inside. Bird
wings have an internal framework consisting of bones, while butterfly wings do
not have any bones at all and are kept rigid mostly through fluid pressure.
Analogies may be due to homologies or homoplasies, but the common ancestor,
if any, is unknown.
Problems in
Classifying Organisms
Listing
characteristics that distinguish one species from another has the effect of making it
appear that the species and their distinctive attributes are fixed and eternal.
We must always keep
in mind that they were brought about by evolutionary processes that operated not merely at
some time in the distant past, but which continue to operate in the present and can be
expected to give rise to new forms in the future.
Species are always changing. As a consequence, they are essentially
only a somewhat arbitrarily defined point along an evolutionary line.
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Jaguar |
It is also
important to realize that most species are physically and
genetically diverse. Many are far more varied than
humans. When you think of an
animal, such as the jaguar shown on the right, and describe it in terms of its specific traits
(fur color patterns, body shape, etc.), it is natural to generalize and to think of all
jaguars that way. To do so, however, is to ignore the reality of
diversity in
nature.
Another
problem in classifying a newly discovered organism is in determining the specific
characteristics that actually distinguish it from all other types of organisms.
There is always a lively debate among researchers over defining new species because it is
not obvious what are the most important traits. There are
two schools of thought in resolving this dilemma. The first defines new species based on minor differences
between organisms. This is the splitter approach.
The second tends to ignore minor differences and to emphasize major
similarities. This lumper approach results in fewer species being defined.
Ideally,
this dispute could be settled by breeding experiments--if two organisms can mate and
produce fertile offspring, they are probably members
of the same species. However, we must be careful
because members of very closely related species can sometimes produce
offspring together, and a small fraction of those may be fertile. This
is the case with mules, which are the product of mating between
female horses and
male donkeys. About one out of 10,000 mules is fertile.
Does this mean that horses and donkeys are in the same species?
Whatever the answer may be, it is clear that species are not absolutely
distinct entities, though by naming them, we implicitly convey the idea that
they are.
Tigons and Ligers--what happens when tigers
and lions mate
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Breeding experiments are rarely undertaken
to determine species boundaries because of
the practical difficulties. It is time
consuming and wild animals do not always cooperate.
Using this kind of reproductive data for defining species from the fossil
record is impossible since we cannot go back in time to observe
interspecies breeding patterns and results.
Likewise, we cannot carry out a breeding experiment between ourselves and
our ancestors from a million years ago.
Comparisons of DNA sequences are now becoming
more commonly used as an aid in distinguishing species. If two animals
share a great many DNA sequences, it is likely that they are at least closely
related. Unfortunately, this usually does not conclusively tell us that
they are members of the same species. Therefore, we are
still left with morphological characteristics
as the most commonly used criteria for identifying species differences.
The Linnaean scheme for classification of
living things lumps organisms together based on presumed homologies. The
assumption is that the more homologies two organisms share, the closer they
must be in terms of evolutionary distance. Higher, more inclusive
divisions of the Linnaean system (e.g., phylum and class) are created by including together closely
related clusters of the immediately lower divisions.
The result
is a hierarchical
system of classification with the
highest category consisting of all living things. The lowest category consists of a
single species. Each of the categories above species can have numerous
subcategories. In the example below, only two genera
(plural of genus) are listed per family but there could be many
more or only one.
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order |
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family |
family |
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genus |
genus |
genus |
genus |
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species |
species |
species |
species |
species |
species |
species |
species |
Most researchers today
take a cladistics
approach to classification. This involves making a distinction between derived and
primitive traits when evaluating the
importance of homologies in determining placement of organisms within the
Linnaean classification system. Derived traits are those that have
changed
from the ancestral form and/or
function.
An example is the foot of a modern horse. Its distant early mammal
ancestor had five digits. Most of the bones of these digits have been
fused together in horses giving them essentially only one toe with a
hoof.
In contrast, primates have retained the primitive characteristic of
having
five digits on the ends of their hands and feet. Animals sharing a
great many homologies that were recently derived, rather than only
ancestral, are more likely to have a recent common ancestor. This
assumption is the basis of
cladistics.
Last Tasmanian Tiger, Thylacine, 1933 (silent film): To return here, you must click
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