Chapter 24 The
Origin of Species
Lecture Outline
Overview: That “Mystery of
Mysteries”
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He
realized that he was observing newly emerged species on these young islands.
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Speciation—the origin of new
species—is at the focal point of evolutionary theory because the appearance of
new species is the source of biological diversity.
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Microevolution is the study of adaptive
change in a population.
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Macroevolution addresses evolutionary
changes above the species level.
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It
deals with questions such as the appearance of evolutionary novelties (e.g.,
feathers and flight in birds) that can be used to define higher taxa.
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Speciation
addresses the question of how new species originate and develop through the
subdivision and subsequent divergence of gene pools.
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The
fossil record chronicles two patterns of speciation: anagenesis and
cladogenesis.
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Anagenesis, phyletic evolution, is
the accumulation of changes associated with the gradual transformation of one
species into another.
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Cladogenesis, branching evolution, is
the budding of one or more new species from a parent species.
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Only
cladogenesis promotes biological diversity by increasing the number of species.
Concept
24.1 The biological species concept emphasizes reproductive isolation
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Species is
a Latin word meaning “kind” or “appearance.”
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Traditionally,
morphological differences have been used to distinguish species.
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Today,
differences in body function, biochemistry, behavior, and genetic makeup are
also used to differentiate species.
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Are
organisms truly divided into the discrete units we called species, or is this
classification an arbitrary attempt to impose order on the natural world?
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In
1942, Ernst Mayr proposed the biological
species concept.
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A
species is defined as a population or group of populations whose members have
the potential to breed with each other in nature to produce viable, fertile
offspring, but who cannot produce viable, fertile offspring with members of
other species.
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A
biological species is the largest set of populations in which genetic exchange
is possible and that is genetically isolated from other populations.
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Species
are based on interfertility, not physical similarity.
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For
example, eastern and western meadowlarks have similar shapes and coloration,
but differences in song help prevent interbreeding between the two species.
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In
contrast, humans have considerable diversity, but we all belong to the same
species because of our capacity to interbreed.
Prezygotic
and postzygotic barriers isolate the gene pools of biological species.
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Because
the distinction between biological species depends on reproductive
incompatibility, the concept hinges on reproductive
isolation, the existence of biological barriers that prevent members of two
species from producing viable, fertile hybrids.
·
A
single barrier may not block all genetic exchange between species, but a
combination of several barriers can effectively isolate a species’ gene pool.
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Typically,
these barriers are intrinsic to the organisms, not due to simple geographic
separation.
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Reproductive
isolation prevents populations belonging to different species from
interbreeding, even if their ranges overlap.
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Reproductive
barriers can be categorized as prezygotic or postzygotic, depending on whether
they function before or after the formation of zygotes.
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Prezygotic barriers impede mating between
species or hinder fertilization of ova if members of different species attempt
to mate.
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These
barriers include habitat isolation, behavioral isolation, temporal isolation,
mechanical isolation, and gametic isolation.
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Habitat isolation. Two organisms that use different habitats
(even in the same geographic area) are unlikely to encounter each other to even
attempt mating.
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Two
species of garter snakes in the genus Thamnophis
occur in the same areas. Because one lives mainly in water and the other is
primarily terrestrial, they rarely encounter each other.
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Behavioral isolation. Many species use elaborate courtship behaviors
unique to the species to attract mates.
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In
many species, elaborate courtship displays identify potential mates of the
correct species and synchronize gonadal maturation.
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In
the blue-footed booby, males perform a high-step dance that calls the female’s
attention to the male’s bright blue feet.
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Temporal isolation. Two species that breed during different times
of day, different seasons, or different years cannot mix gametes.
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The
geographic ranges of the western spotted skunk and the eastern spotted skunk
overlap. However, they do not interbreed because the former mates in late
summer and the latter in late winter.
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Mechanical isolation. Closely related species may attempt to mate
but fail because they are anatomically incompatible and transfer of sperm is
not possible.
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For
example, mechanical barriers contribute to the reproductive isolation of
flowering plants that are pollinated by insects or other animals.
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With
many insects, the male and female copulatory organs of closely related species
do not fit together, preventing sperm transfer.
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Gametic isolation. The gametes of two species do not form a
zygote because of incompatibilities preventing fertilization.
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In
species with internal fertilization, the environment of the female reproductive
tract may not be conducive to the survival of sperm from other species.
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For
species with external fertilization, gamete recognition may rely on the
presence of specific molecules on the egg’s coat, which adhere only to specific
molecules on sperm cells of the same species.
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A
similar molecular recognition mechanism enables a flower to discriminate
between pollen of the same species and pollen of a different species.
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If
a sperm from one species does fertilize the ovum of another, postzygotic barriers may prevent the
hybrid zygote from developing into a viable, fertile adult.
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These
barriers include reduced hybrid viability, reduced hybrid fertility, and hybrid
breakdown.
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Reduced hybrid viability. Genetic incompatibility between the two
species may abort the development of the hybrid at some embryonic stage or
produce frail offspring.
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This
is true for the occasional hybrids between frogs in the genus Rana. Most do not complete development,
and those that do are frail.
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Reduced hybrid fertility. Even if the hybrid offspring are vigorous,
the hybrids may be infertile, and the hybrid cannot backbreed with either
parental species.
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This
infertility may be due to problems in meiosis because of differences in
chromosome number or structure.
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For
example, while a mule, the hybrid product of mating between a horse and donkey,
is a robust organism, it cannot mate (except very rarely) with either horses or
donkeys.
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Hybrid breakdown. In some cases, first generation hybrids are
viable and fertile.
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However,
when they mate with either parent species or with each other, the next
generation is feeble or sterile.
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Strains
of cultivated rice have accumulated different mutant recessive alleles at two
loci in the course of their divergence from a common ancestor.
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Hybrids
between them are vigorous and fertile, but plants in the next generation that
carry too many of these recessive alleles are small and sterile.
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These
strains are in the process of speciating.
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Reproductive
barriers can occur before mating, between mating and fertilization, or after fertilization.
The
biological species concept has some major limitations.
·
While
the biological species concept has had an important impact on evolutionary
theory, it is limited when applied to species in nature.
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For
example, one cannot test the reproductive isolation of morphologically similar
fossils, which are separated into species based on morphology.
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Even
for living species, we often lack information on interbreeding needed to apply
the biological species concept.
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In
addition, many species (e.g., bacteria) reproduce entirely asexually and are
assigned to species based mainly on structural and biochemical characteristics.
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Many
bacteria transfer genes by conjugation and other processes, but this transfer
is different from sexual recombination.
Evolutionary
biologists have proposed several alternative concepts of species.
·
Several
alternative species concepts emphasize the processes that unite the members of a species.
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The
ecological species concept defines a
species in terms of its ecological niche, the set of environmental resources
that a species uses and its role in a biological community.
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As
an example, a species that is a parasite may be defined in part by its
adaptations to a specific organism.
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This
concept accommodates asexual and sexual species.
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The
paleontological species concept
focuses on morphologically discrete species known only from the fossil record.
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There
is little or no information about the mating capability of fossil species, and
the biological species concept is not useful for them.
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The
phylogenetic species concept defines
a species as a set of organisms with a unique genetic history.
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Biologists
compare the physical characteristics or molecular sequences of species to those
of other organisms to distinguish groups of individuals that are sufficiently
different to be considered separate species.
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Sibling species are species that appear
so similar that they cannot be distinguished on morphological grounds.
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Scientists
apply the biological species concept to determine if the phylogenetic distinction
is confirmed by reproductive incompatibility.
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The
morphological species concept, the
oldest and still most practical, defines a species by a unique set of
structural features.
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The
morphological species concept has certain advantages. It can be applied to
asexual and sexual species, and it can be useful even without information about
the extent of gene flow.
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However,
this definition relies on subjective criteria, and researchers sometimes
disagree about which structural features identify a species.
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In
practice, scientists use the morphological species concept to distinguish most
species.
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Each
species concept may be useful, depending on the situation and the types of
questions we are asking.
Concept 24.2
Speciation can take place with or without geographic separation
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Two
general modes of speciation are distinguished by the way gene flow among
populations is initially interrupted.
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In
allopatric speciation, geographic
separation of populations restricts gene flow.
In sympatric
speciation, speciation occurs in geographically overlapping populations
when biological factors, such as chromosomal changes and nonrandom mating,
reduce gene flow.
Allopatric
speciation: geographic barriers can lead to the origin of species.
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Several
geological processes can fragment a population into two or more isolated
populations.
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Mountain
ranges, glaciers, land bridges, or splintering of lakes may divide one
population into isolated groups.
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Alternatively,
some individuals may colonize a new, geographically remote area and become isolated
from the parent population.
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For
example, mainland organisms that colonized the
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How
significant a barrier must be to limit gene exchange depends on the ability of
organisms to move about.
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A
geological feature that is only a minor hindrance to one species may be an
impassible barrier to another.
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The
valley of the
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For
birds that can fly across the canyon, it is no barrier.
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Once
geographic separation is established, the separated gene pools may begin to
diverge through a number of mechanisms.
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Mutations
arise.
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Sexual
selection favors different traits in the two populations.
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Different
selective pressures in differing environments act on the two populations.
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Genetic
drift alters allele frequencies.
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A
small, isolated population is more likely to have its gene pool changed
substantially over a short period of time by genetic drift and natural selection.
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For
example, less than 2 million years ago, small populations of stray plants and
animals from the South American mainland colonized the
·
However,
very few small, isolated populations develop into new species; most simply
persist or perish in their new environment.
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To
confirm that allopatric speciation has occurred, it is necessary to determine
whether the separated populations have become different enough that they can no
longer interbreed and produce fertile offspring when they come back in contact.
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In
some cases, researchers bring together members of separated populations in a
laboratory setting.
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Biologists
can also assess allopatric speciation in the wild.
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For
example, females of the Galápagos ground finch Geospiza difficilis respond to the songs of males from the same
island but ignore the songs of males of the same species from other islands.
Sympatric
speciation: a new species can originate in the geographic midst of the parent
species.
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In
sympatric speciation, new species arise within the range of the parent
populations.
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Here
reproductive barriers must evolve between sympatric populations.
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In
plants, sympatric speciation can result from accidents during cell division
that result in extra sets of chromosomes, a mutant condition known as polyploidy.
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In
animals, it may result from gene-based shifts in habitat or mate preference.
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An
individual can have more than two sets of chromosomes.
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An
autopolyploid mutant is an
individual that has more than two chromosome sets, all derived from a single
species.
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For
example, a failure of mitosis or meiosis can double a cell’s chromosome number
from diploid (2n) to tetraploid (4n).
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The
tetraploid can reproduce with itself (self-pollination) or with other
tetraploids.
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It
cannot mate with diploids from the original population, because of abnormal
meiosis by the triploid hybrid offspring.
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A
more common mechanism of producing polyploid individuals occurs when allopolyploid offspring are produced by
the mating of two different species.
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While
the hybrids are usually sterile, they may be quite vigorous and propagate
asexually.
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In
subsequent generations, various mechanisms may transform a sterile hybrid into
a fertile polyploid.
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These
polyploid hybrids are fertile with each other but cannot breed with either
parent species.
·
They
thus represent a new biological species.
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The
origin of polyploid plant species is common and rapid enough that scientists
have documented several such speciations in historical times.
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For
example, two new species of plants called goatsbeard (Tragopodon) appeared in
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They
are the results of allopolyploidy events between pairs of introduced European Tragopodon species.
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Many
plants important for agriculture are polyploid.
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For
example, wheat is an allohexaploid, with six sets of chromosomes from three
different species.
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Oats,
cotton, potatoes, and tobacco are polyploid.
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Plant
geneticists now use chemicals that induce meiotic and mitotic errors to create
new polyploid plants with special qualities.
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One
example is an artificial hybrid combining the high yield of wheat with the
hardiness and disease resistance of rye.
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While
polyploid speciation does occur in animals, other mechanisms also contribute to
sympatric speciation in animals.
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Reproductive
isolation can result when genetic factors cause individuals to exploit
resources not used by the parent.
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One
example is the North American maggot fly, Rhagoletis
pomonella.
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The
fly’s original habitat was native hawthorn trees.
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About
200 years ago, some populations colonized newly introduced apple trees.
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Because
apples mature more quickly than hawthorn fruit, the apple-feeding flies have
been selected for more rapid development and now show temporal isolation from
the hawthorn-feeding maggot flies.
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Speciation
is underway.
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Sympatric
speciation is one mechanism that has been proposed for the explosive adaptive
radiation of cichlid fishes in Lake Victoria,
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This
vast, shallow lake has filled and dried up repeatedly due to climate changes.
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The
current lake is only 12,000 years old but is home to 600 species of cichlid
fishes.
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The
species are so genetically similar that many have likely arisen since the lake
last filled.
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While
these species are clearly specialized for exploiting different food resources
and other resources, nonrandom mating in which females select males based on a
certain appearance has probably contributed, too.
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Individuals
of two closely related sympatric cichlid species will not mate under normal
light because females have specific color preferences and males differ in
color.
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However,
under light conditions that de-emphasize color differences, females will mate
with males of the other species and produce viable, fertile offspring.
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It
seems likely that the ancestral population was polymorphic for color and that
divergence began with the appearance of two ecological niches that divided the
fish into subpopulations.
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Genetic
drift resulted in chance differences in the genetic makeup of the subpopulations,
with different male colors and female preferences.
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Sexual
selection reinforced the color differences.
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The
lack of postzygotic barriers in this case suggests that speciation occurred
relatively recently.
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As
pollution clouds the waters of
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The
gene pools of these two closely related species may blend again.
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We
will summarize the differences between sympatric and allopatric speciation.
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In
allopatric speciation, a new species forms while geographically isolated from
its parent population.
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As
the isolated population accumulates genetic differences due to natural
selection and genetic drift, reproductive isolation from the ancestral species
may arise as a by-product of the genetic change.
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Such
reproductive barriers prevent breeding with the parent even if the populations
reestablish contact.
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Sympatric
speciation requires the emergence of some reproductive barrier that isolates a
subset of the population without geographic separation from the parent
population.
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In
plants, the most common mechanism is hybridization between species or errors in
cell division that lead to polyploid individuals.
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In
animals, sympatric speciation may occur when a subset of the population is
reproductively isolated by a switch in food source or by sexual selection in a
polymorphic population.
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The
evolution of many diversely adapted species from a common ancestor when new
environmental opportunities arise is called adaptive radiation.
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Adaptive
radiation occurs when a few organisms make their way into new areas or when
extinction opens up ecological niches for the survivors.
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A
major adaptive radiation of mammals followed the extinction of the dinosaurs 65
million years ago.
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The
Hawaiian archipelago is a showcase of adaptive radiation.
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Located
3,500 km from the nearest continent, the volcanic islands were formed “naked”
and gradually populated by stray organisms that arrived by wind or ocean
currents.
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The
islands are physically diverse, with a range of altitudes and rainfall.
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Multiple
invasions and allopatric and sympatric speciation events have ignited an
explosion of adaptive radiation of novel species.
Researchers
study the genetics of speciation.
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Researchers
have made great strides in understanding the role of genes in particular
speciation events.
·
Douglas
Schemske and his colleagues at
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The
two species are pollinated by bees and hummingbirds respectively, keeping their
gene pools separate through prezygotic isolation.
·
The
species show no postzygotic isolation and can be mated readily in the
greenhouse to produce hybrids with flowers that vary in color and shape.
·
Researchers
observed which pollinators visit which flowers and then investigated the
genetic differences between plants.
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Two
gene loci have been identified that are largely responsible for pollinator
choice.
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One
locus influences flower color; the other affects the amount of nectar flowers
produce.
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By
determining attractiveness of the flowers to different pollinators, allelic
diversity at these loci has led to speciation.
The tempo
of speciation is important.
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In
the fossil record, many species appear as new forms rather suddenly (in
geologic terms), persist essentially unchanged, and then disappear from the
fossil record.
·
·
Paleontologists
Niles Eldredge and Stephen Jay Gould coined the term punctuated equilibrium to describe these periods of apparent stasis
punctuated by sudden change.
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Some
scientists suggest that these patterns require an explanation outside the
Darwinian model of descent with modification.
·
However,
this is not necessarily the case.
·
Suppose
that a species survived for 5 million years, but most of its morphological
alterations occurred in the first 50,000 years of its existence—just 1% of its
total lifetime.
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Because
time periods this short often cannot be distinguished in fossil strata, the
species would seem to have appeared suddenly and then lingered with little or
no change before becoming extinct.
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Even
though the emergence of this species actually took tens of thousands of years,
this period of change left no fossil record.
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Stasis
can also be explained.
·
All
species continue to adapt after they arise, but often by changes that do not
leave a fossil record, such as small biochemical modifications.
·
Paleontologists
base hypotheses of descent almost entirely on external morphology.
·
During
periods of apparent equilibrium, changes in behavior, internal anatomy, and
physiology may not leave a fossil record.
·
If
the environment changes, the stasis will be broken by punctuations that leave
visible traces in the fossil record.
Concept 24.3
Macroevolutionary changes can accumulate through many speciation events
·
Speciation
is at the boundary between microevolution and macroevolution.
·
Microevolution
is a change over generations in a population’s allele frequencies, mainly by
genetic drift and natural selection.
·
Speciation
occurs when a population’s genetic divergence from its ancestral population
results in reproductive isolation.
·
While
the changes after any speciation event may be subtle, the cumulative change
over millions of speciation episodes must account for macroevolution, the scale
of changes seen in the fossil record.
Most
evolutionary novelties are modified versions of older structures.
·
The
Darwinian concept of descent with modification can account for the major
morphological transformations of macroevolution.
·
It
may be difficult to believe that a complex organ like the human eye could be
the product of gradual evolution, rather than a finished design created
specially for humans.
·
However,
the key is to remember is that a very simple eye can be very useful to an
animal.
·
The
simplest eyes are just clusters of photoreceptors, light-sensitive pigmented
cells.
·
These
simple eyes appear to have had a single evolutionary origin.
·
They
are now found in a variety of animals, including limpets.
·
These
simple eyes have no lenses and cannot focus an image, but they do allow the
animal to distinguish light from dark.
·
Limpets
cling tightly to their rocks when a shadow falls on them, reducing their risk
of predation.
·
Complex
eyes have evolved several times independently in the animal kingdom.
·
Examples
of various levels of complexity, from clusters of photoreceptors to camera-like
eyes, can be seen in molluscs.
·
The
most complex types did not evolve in one quantum leap, but by incremental
adaptation of organs that benefited their owners at each stage.
·
Evolutionary
novelties can also arise by gradual refinement of existing structures for new
functions.
·
Structures
that evolve in one context, but become co-opted for another function, are exaptations.
·
It
is important to recognize that natural selection can only improve a structure
in the context of its current
utility, not in anticipation of the future.
·
An
example of an exaptation is the changing function of lightweight, honeycombed
bones of birds.
·
The
fossil record indicates that light bones predated flight.
·
Therefore,
they must have had some function on the ground, perhaps as a light frame for
agile, bipedal dinosaurs.
·
Once
flight became an advantage, natural selection would have remodeled the skeleton
to better fit their additional function.
·
The
wing-like forelimbs and feathers that increased the surface area of these
forelimbs were co-opted for flight after functioning in some other capacity,
such as courtship, thermoregulation, or camouflage.
Genes that
control development play a major role in evolution.
·
“Evo-devo”
is a field of interdisciplinary research that examines how slight genetic
divergences can become magnified into major morphological differences between
species.
·
A
particular focus is on genes that program development by controlling the rate,
timing, and spatial pattern of changes in form as an organism develops from a
zygote to an adult.
·
Heterochrony, an evolutionary change in
the rate or timing of developmental events, has led to many striking
evolutionary transformations.
·
Allometric growth tracks how proportions of
structures change due to different growth rates during development.
·
Change
relative rates of growth even slightly, and you can change the adult form
substantially.
·
Different
allometric patterns contribute to the contrast of adult skull shapes between
humans and chimpanzees, which both developed from fairly similar fetal skulls.
·
Heterochrony
appears to be responsible for differences in the feet of tree-dwelling versus
ground-dwelling salamanders.
·
The
feet of the tree-dwellers are adapted for climbing vertically, with shorter
digits and more webbing.
·
This
modification may have evolved due to mutations in the alleles that control the
timing of foot development.
·
Stunted
feet may have resulted if regulatory genes switched off foot growth early.
·
In
this way, a relatively small genetic change can be amplified into substantial
morphological change.
·
Another
form of heterochrony is concerned with the relative timing of reproductive
development and somatic development.
·
If
the rate of reproductive development accelerates compared to somatic
development, then a sexually mature stage can retain juvenile structures—a
process called paedomorphosis.
·
Some
species of salamander have the typical external gills and flattened tail of an
aquatic juvenile, but have functioning gonads.
·
Macroevolution
can also result from changes in genes that control the placement and spatial
organization of body parts.
·
For
example, genes called homeotic genes
determine such basic features as where a pair of wings and a pair of legs will
develop on a bird or how a plant’s flower parts are arranged.
·
The
products of one class of homeotic genes, the Hox genes, provide positional information in an animal embryo.
·
This
information prompts cells to develop into structures appropriate for a
particular location.
·
One
major transition in the evolution of vertebrates is the development of the
walking legs of tetrapods from the fins of fishes.
·
A
fish fin that lacks external skeletal support evolved into a tetrapod limb that
extends skeletal supports (digits) to the tip of the limb.
·
This
may be the result of changes in the positional information provided by Hox genes during limb development,
determining how far digits and other bones should extend from the limb.
Evolution
is not goal oriented.
·
The
fossil record shows apparent evolutionary trends.
·
For
example, the evolution of the modern horse can be interpreted to have been a
steady series of changes from a small, browsing ancestor (Hyracotherium) with four toes to modern horses (Equus) with only one toe per foot and
teeth modified for grazing on grasses.
·
It
is possible to arrange a succession of animals intermediate between Hyracotherium and modern horses to show
trends toward increased size, reduced number of toes, and modifications of
teeth for grazing.
·
If
we look at all fossil horses, the illusion of coherent, progressive evolution
leading directly to modern horses vanishes.
·
Equus is the only surviving
twig of an evolutionary bush that included several adaptive radiations among
both grazers and browsers.
·
Differences
among species in survival can also produce a macroevolutionary trend.
·
The
species selection model developed by
Steven Stanley considers species as analogous to individuals.
·
Speciation
is their birth, extinction is their death, and new species are their offspring.
·
In
this model,
·
The
species that endure the longest and generate the greatest number of new species
determine the direction of major evolutionary trends.
·
The
species selection model suggests that “differential speciation success” plays a
role in macroevolution similar to the role of differential reproductive success
in microevolution.
·
To
the extent that speciation rates and species longevity reflect success, the
analogy to natural selection is even stronger.
·
However,
qualities unrelated to the overall success of organisms in specific
environments may be equally important in species selection.
·
As
an example, the ability of a species to disperse to new locations may
contribute to its giving rise to a large number of “daughter species.”
·
The
appearance of an evolutionary trend does not imply some intrinsic drive toward
a preordained state of being.
·
Evolution
is a response to interactions between organisms and their current environments,
leading to changes in evolutionary trends as conditions change.