Chapter
22 Descent with Modification: Darwinian View of Life
Lecture Outline
Overview:
·
On
November 24, 1859, Charles Darwin published On the Origin of Species by Means
of Natural Selection.
·
·
1.
Today’s
organisms descended from ancestral species that were different from modern
species.
2.
Natural
selection provided a mechanism for this evolutionary change.
°
The
basic idea of natural selection is that a population can change over time if
individuals that possess certain heritable traits leave more offspring than
other individuals.
°
Natural
selection results in evolutionary adaptation, an accumulation of inherited
characteristics that increase the ability of an organism to survive and
reproduce in its environment.
·
Eventually,
a population may accumulate enough change that it constitutes a new species.
·
In
modern terms, we can define evolution
as a change over time in the genetic composition of a population.
°
Evolution also refers to the gradual
appearance of all biological diversity.
·
Evolution
is such a fundamental concept that its study is relevant to biology at every
level, from molecules to ecosystems.
°
Evolutionary
perspectives continue to transform medicine, agriculture, biotechnology, and
conservation biology.
Concept 22.1 The Darwinian revolution challenged traditional views
of a young Earth inhabited by unchanging species
Western culture resisted evolutionary views
of life.
·
°
The Origin of Species challenged a worldview
that had been long accepted.
·
The
Greek philosopher Aristotle (384–322 B.C.E.) opposed any concept of evolution
and viewed species as fixed and unchanging.
°
Aristotle
believed that all living forms could be arranged on a ladder of increasing
complexity (scala naturae) with
perfect, permanent species on every rung.
·
The
Old Testament account of creation held that species were individually designed
by God and, therefore, perfect.
·
In
the 1700s, natural theology viewed
the adaptations of organisms as evidence that the Creator had designed each
species for a purpose.
·
Carolus
Linnaeus (1707–1778), a Swedish physician and botanist, founded taxonomy, a system for naming species
and classifying species into a hierarchy of increasingly complex categories.
°
Linnaeus
developed the binomial system of naming organisms according to genus and
species.
°
In
contrast to the linear hierarchy of the scala
naturae, Linnaeus adopted a nested classification system, grouping similar
species into increasingly general categories.
°
For
Linnaeus, similarity between species did not imply evolutionary kinship but
rather the pattern of their creation.
·
°
Sedimentary
rocks form when mud and sand settle to the bottom of seas, lakes, and marshes.
°
New
layers of sediment cover older ones, creating layers of rock called strata.
°
Erosion
may later carve through sedimentary rock to expose older strata at the surface.
°
Fossils
within layers of sedimentary rock show that a succession of organisms have
populated Earth throughout time.
·
Paleontology, the study of fossils, was
largely developed by the French anatomist Georges Cuvier (1769–1832).
·
In
examining rock strata in the
°
Cuvier
recognized that extinction had been a common occurrence in the history of life.
°
Instead
of evolution, Cuvier advocated catastrophism,
speculating that boundaries between strata were due to local floods or droughts
that destroyed the species then present.
°
He
suggested that the denuded areas were later repopulated by species immigrating
from unaffected areas.
Theories of geologic gradualism prepared the
path for evolutionary biologists.
·
In
contrast to Cuvier’s catastrophism, Scottish geologist James Hutton (1726–1797)
proposed a theory of gradualism that
held that profound geological changes took place through the cumulative effect
of slow but continuous processes identical to those currently operating.
°
Thus,
valleys were formed by rivers flowing through rocks and sedimentary rocks were
formed from soil particles that eroded from land and were carried by rivers to
the sea.
·
Later,
geologist Charles Lyell (1797–1875) proposed a theory of uniformitarianism, which held that geological processes had not
changed throughout Earth’s history.
·
Hutton’s
and Lyell’s observations and theories had a strong influence on
°
First,
if geologic changes result from slow, continuous processes rather than sudden
events, then the Earth must be far older than the 6,000 years estimated by
theologians from biblical inference.
°
Second,
slow and subtle processes persisting for long periods of time can also act on
living organisms, producing substantial change over a long period of time.
Lamarck placed fossils in an evolutionary
context.
·
In
1809, French biologist Jean-Baptiste de Lamarck (1744–1829) published a theory
of evolution based on his observations of fossil invertebrates in the
collections of the Natural History Museum of Paris.
°
By
comparing fossils and current species, Lamarck found what appeared to be
several lines of descent.
°
Each
was a chronological series of older to younger fossils, leading to a modern
species.
·
He
explained his observations with two principles: use and disuse of parts and the inheritance
of acquired characteristics.
°
Use
and disuse was the concept that body parts that are used extensively become
larger and stronger, while those that are not used deteriorate.
°
The
inheritance of acquired characteristics stated that modifications acquired
during the life of an organism could be passed to offspring.
°
A
classic example is the long neck of the giraffe. Lamarck reasoned that the
long, muscular neck of the modern giraffe evolved over many generations as the
ancestors of giraffes reached for leaves on higher branches and passed this
characteristic to their offspring.
·
Lamarck
thought that evolutionary change was driven by the innate drive of organisms to
increasing complexity.
·
Lamarck’s
theory was a visionary attempt to explain the fossil record and the current
diversity of life with recognition of gradual evolutionary change.
°
However,
modern genetics has provided no evidence that acquired characteristics can be
inherited.
°
Acquired
traits such as a body builder’s bigger biceps do not change the genes
transmitted through gametes to offspring.
Concept 22.2 In The Origin of
Species,
·
Charles
Darwin (1809–1882) was born in western
°
As
a boy, he developed a consuming interest in nature.
°
When
·
°
At
that time, most naturalists and scientists belonged to the clergy and viewed
the world in the context of natural theology.
·
·
After
graduation
°
FitzRoy
chose
Field research helped
·
The
primary mission of the five-year voyage of the Beagle was to chart poorly known stretches of the South American
coastline.
·
·
He
collected thousands of specimens of the exotic and diverse flora and fauna of
°
·
°
Organisms
from temperate regions of South America more closely resembled those from the
tropics of South America than those from temperate regions of
°
Further,
South American fossils, though different from modern species, more closely
resembled modern species from South America than those from
·
While
on the Beagle,
°
He
experienced geological change firsthand when a violent earthquake rocked the
coast of
°
He
found fossils of ocean organisms high in the
°
These
observations reinforced
·
°
°
After
his return to
°
He
hypothesized that the islands had been colonized by plants and animals from the
mainland that had subsequently diversified on the different islands.
·
After
his return to
°
For
example, clear differences in the beaks among the 13 species of finches that
·
By
the early 1840s,
·
In
1844, he wrote a long essay on the origin of species and natural selection, but
he was reluctant to publish and continued to compile evidence to support his
theory.
·
In
June 1858, Alfred Russel Wallace (1823–1913), a young naturalist working in the
East Indies, sent
·
Later
that year, both Wallace’s paper and extracts of
·
·
While
both Darwin and Wallace developed similar ideas independently, the theory of
evolution by natural selection is attributed to
°
The
theory of evolution by natural selection was presented in The Origin of Species with immaculate logic and an avalanche of
supporting evidence.
·
Within
a decade, The Origin of Species had
convinced most biologists that biological diversity was the product of
evolution.
The Origin of Species developed two main
ideas: that evolution explains life’s unity and diversity and that natural
selection is the mechanism of adaptive evolution.
·
°
Instead
he used the phrase descent with
modification.
§
All
organisms are related through descent from a common ancestor that lived in the
remote past.
§
Over
evolutionary time, the descendents of that common ancestor have accumulated
diverse modifications, or adaptations,
that allow them to survive and reproduce in specific habitats.
·
Viewed
from the perspective of descent with modification, the history of life is like
a tree with multiple branches from a common trunk.
°
Closely
related species, the twigs on a common branch of the tree, shared the same line
of descent until their recent divergence from a common ancestor.
·
Linnaeus
recognized that some organisms resemble each other more closely than others,
but he did not explain these similarities by evolution.
°
However,
his taxonomic scheme fit well with
°
To
§
Organisms
at various taxonomic levels are united through descent from common ancestors.
·
How
does natural selection work, and how does it explain adaptation?
·
Evolutionary
biologist Ernst Mayr has dissected the logic of
°
Observation
#1: All species have such great potential fertility that their population size
would increase exponentially if all individuals that are born reproduced
successfully.
°
Observation
#2: Populations tend to remain stable in size, except for seasonal
fluctuations.
°
Observation
#3: Environmental resources are limited.
§
Inference
#1: Production of more individuals than the environment can support leads to a
struggle for existence among the individuals of a population, with only a
fraction of the offspring surviving each generation.
°
Observation
#4: Individuals of a population vary extensively in their characteristics; no
two individuals are exactly alike.
°
Observation
#5: Much of this variation is heritable.
§
Inference
#2: Survival in the struggle for existence is not random, but depends in part
on inherited traits. Those individuals whose inherited traits are best suited for
survival and reproduction in their environment are likely to leave more
offspring than less fit individuals.
§
Inference
#3: This unequal ability of individuals to survive and reproduce will lead to a
gradual change in a population, with favorable characteristics accumulating
over generations.
·
A
1798 essay on human population by Thomas Malthus heavily influenced
°
Malthus
contended that much human suffering—disease, famine, homelessness, war—was the
inescapable consequence of the potential for human populations to increase
faster than food supplies and other resources.
·
The
capacity to overproduce seems to be a characteristic of all species.
·
Only
a tiny fraction of offspring produced complete their development and reproduce
successfully to leave offspring of their own.
·
In
each generation, environmental factors filter heritable variations, favoring
some over others.
°
Differential
reproductive success—whereby organisms with traits favored by the environment
produce more offspring than do organisms without those traits—results in the
favored traits being disproportionately represented in the next generation.
°
This
increasing frequency of the favored traits in a population is evolutionary
change.
·
°
Humans
have modified a variety of domesticated plants and animals over many
generations by selecting individuals with the desired traits as breeding stock.
°
If
artificial selection can achieve so much change in a relatively short period of
time,
·
°
Natural selection is
differential success in reproduction (unequal ability of individuals to survive
and reproduce) that results from individuals that vary in heritable traits and
their environment.
°
The product of natural
selection is the increasing adaptation of organisms to their environment.
°
If an environment changes
over time, or if individuals of a species move to a new environment, natural
selection may result in adaptation to the new conditions, sometimes giving rise
to a new species in the process.
·
Three important points
need to be emphasized about evolution through natural selection.
1.
Although
natural selection occurs through interactions between individual organisms and
their environment, individuals do not evolve. A population (a group of
interbreeding individuals of a single species that share a common geographic
area) is the smallest group that can evolve. Evolutionary change is measured as
changes in relative proportions of heritable traits in a population over
successive generations.
2.
Natural
selection can act only on heritable traits, traits that are passed from
organisms to their offspring. Characteristics acquired by an organism during
its lifetime may enhance its survival and reproductive success, but there is no
evidence that such characteristics can be inherited by offspring.
3.
Environmental
factors vary from place to place and from time to time. A trait that is
favorable in one environment may be useless or even detrimental in another
environment.
·
Concept 22.3
·
The
power of evolution by natural selection as a unifying theory is its versatility
as a natural explanation for diverse data from many fields of biology.
·
We
will consider two examples of natural selection as a mechanism of evolution in
populations.
·
Our
first example concerns differential predation and guppy populations.
·
Guppies
(Poecilia reticulata) live in the
wild in pools in the
·
John
Endler and David Reznick have been studying these small fish for more than a
decade.
·
The
researchers observed significant differences between populations of guppies
that live in different pools in the river system.
°
Populations
varied in the average age and size of sexual maturity.
°
These
variations were correlated to the type of predator present in each pool.
°
In
some pools, the main predator is the small killifish, which eats juvenile
guppies.
°
In
other pools, the major predator is the large pike-cichlid, which eats adult
guppies.
°
Guppies
in populations preyed on by pike-cichlids begin reproducing at a younger age
and are smaller at maturity than guppies in populations preyed on by killifish.
·
To
test whether these differences are due to natural selection, Reznick and Endler
introduced guppies from pike-cichlid locations to new pools that contained
killifish but no guppies.
°
After
eleven years, the transplanted guppies were, on average, 14% heavier at
maturity than the nontransplanted populations.
°
Their
average age at maturity had also increased.
·
These
results support the hypothesis that natural selection caused the changes in the
transplanted population.
°
Because
pike-cichlids prey mainly on reproductively mature adults, the chance that a
guppy will survive to reproduce several times is low.
°
The
guppies with the greatest reproductive success in ponds with pike-cichlid
predators are those that mature at a young age and small size, enabling them to
produce at least one brood before growing to a size preferred by pike-cichlids.
°
In
ponds with killifish predators, guppies that survive early predation can grow
slowly and produce many broods of young.
·
A
second example of ongoing natural selection is the evolution of drug-resistant
HIV (human immunodeficiency virus).
·
Researchers
have developed numerous drugs to combat HIV, but using these medications
selects for viruses resistant to the drugs.
°
A
few drug-resistant viruses may be present by chance at the beginning of
treatment.
°
The
drug-resistant pathogens are more likely to survive treatment and pass on the
genes that enable them to resist the drug to their offspring.
°
As
a result, the frequency of drug resistance in the viral population rapidly
increases.
·
Scientists
designed the drug 3TC to interfere with reverse transcriptase, the enzyme that
HIV uses to copy its RNA genome into the DNA of the host cell.
°
Because
3TC is similar in shape to the cytosine nucleotide of DNA, HIV’s reverse
transcriptase incorporates 3TC into its growing DNA chain instead of cytosine.
This error terminates elongation of DNA and thus prevents HIV reproduction.
°
3TC-resistant
varieties of HIV have a form of reverse transcriptase that can discriminate
between cytosine and 3TC.
§
These
viruses have no advantage in the absence of 3TC. In fact, they replicate more
slowly than viruses with normal reverse transcriptase.
§
Once
3TC is added to their environment, it becomes a powerful selective agent,
favoring reproduction of resistant individuals.
·
The
examples of the guppies and HIV highlight two important points about natural
selection.
°
First,
natural selection is an editing mechanism, not a creative force. It can only
act on existing variation in the population; it cannot create favorable traits.
°
Second,
natural selection favors traits that increase fitness in the current, local
environment. What is adaptive in one situation is not adaptive in another.
§
For
example, guppies that mature at an early age and small size are at an advantage
in a pool with pike-cichlids, but at a disadvantage in a pool with killifish.
§
In
the absence of 3TC, HIV with the modified form of reverse transcriptase grows
more slowly than HIV with normal reverse transcriptase.
Evidence of evolution pervades biology.
·
In
the cases described, natural selection brought about change rapidly enough that
it could be observed directly.
·
·
Descent
with modification can explain why certain traits in related species have an
underlying similarity even if they have very different functions.
·
Similarity
in characteristic traits from common ancestry is known as homology.
°
For
example, the forelimbs of human, cats, whales, and bats share the same skeletal
elements, even though the appendages have very different functions.
°
These
forelimbs are homologous structures
that represent variations on the ancestral tetrapod forelimb.
·
Homologies
that are not obvious in adult organisms may become evident when we look at
embryonic development.
°
For
example, all vertebrate embryos have structures called pharyngeal pouches in
their throat at some stage in their development.
°
These
embryonic structures develop into very different, but still homologous, adult
structures, such as the gills of fish or the Eustacian tubes that connect the
middle ear with the throat in mammals.
·
Some
of the most interesting homologous structures are vestigial organs, structures that have marginal, if any, importance
to a living organism, but which had important functions in the organism’s
ancestors.
°
For
example, the skeletons of some snakes and of fossil whales retain vestiges of
the pelvis and leg bones of walking ancestors.
·
Comparative
anatomy confirms that evolution is a remodeling process, an alteration of
existing structures.
°
Because
evolution can only modify existing structures and functions, it may produce
structures that are less than perfect.
°
For
example, the back and knee problems of bipedal humans are an unsurprising
outcome of adapting structures originally evolved to support four-legged
mammals.
·
Similarities
among organisms can also be seen at the molecular level.
°
For
example, all species of life have the same basic genetic machinery of RNA and
DNA, and the genetic code is essentially universal.
°
The
ubiquity of the genetic code provides evidence of a single origin of life.
°
It
is likely that the language of the genetic code has been passed along through
all the branches of the tree of life ever since its inception in an early life
form.
·
Homologies
mirror the taxonomic hierarchy of the tree of life.
°
Some
homologies, such as the genetic code, are shared by all living things because
they arose in the deep ancestral past.
°
Other
homologies that evolved more recently are shared only by smaller branches of
the tree of life.
§
For
example, all tetrapods (amphibians, reptiles, birds, and mammals) share the
same five-digit limb structure.
°
Thus
homologies are found in a nested pattern, with all life sharing the deepest
layer and each smaller group adding new homologies to those they share with the
larger group.
°
This
hierarchical pattern of homology is exactly what we would expect if life
evolved and diversified from a common ancestor.
·
Anatomical
resemblances among species are generally reflected in their genes (DNA) and
gene products (proteins).
°
If
hierarchies of homology reflect evolutionary history, then we should expect to
find similar patterns whether we are comparing molecules or bones.
°
Different
kinds of homologies will coincide because they have followed the same branching
pattern through evolutionary history.
·
The
geographical distribution of species—biogeography—first
suggested evolution to
°
Species
tend to be more closely related to other species from the same area than to
other species with the same way of life that live in different areas.
§
Consider
§
Some
marsupial mammals superficially resemble eutherian mammals (which complete
their development in the uterus) from other continents.
à
For
example, the Australian sugar glider and North American flying squirrel are adapted
to the same mode of life and look somewhat similar.
à
However,
the sugar glider shares more characteristics with other Australian marsupials
than with the flying squirrel.
à
The
resemblance between the two gliders is an example of convergent evolution.
·
Islands
and island archipelagos have provided strong evidence of evolution.
°
Islands
generally have many species of plants and animals that are endemic, found nowhere else in the world.
·
As
·
In
island chains, or archipelagos, individual islands may have different, but
related, species. The first mainland invaders reached one island and then
evolved into several new species as they colonized other islands in the
archipelago.
°
Several
well-investigated examples of this phenomenon include the diversification of
finches on the
·
The
succession of fossil forms is consistent with what is known from other types of
evidence about the major branches of descent in the tree of life.
°
For
example, considerable evidence suggests that prokaryotes are the ancestors of
all life and should precede all eukaryotes in the fossil record. In fact, the
oldest known fossils are prokaryotes.
°
Fossil
fishes predate all other vertebrates, with amphibians next, followed by reptiles,
then mammals and birds.
°
This
is consistent with the history of vertebrate descent supported by many other
types of evidence.
·
The
Darwinian view of life also predicts that evolutionary transitions should leave
signs in the fossil record.
·
Paleontologists
have discovered fossils of many such transitional forms that link ancient
organisms to modern species.
°
For
example, fossil evidence documents the origin of birds from one branch of
dinosaurs.
°
Recent
discoveries include fossilized whales that link these aquatic mammals to their
terrestrial ancestors.
What is theoretical about the Darwinian view
of life?
·
Some
people dismiss the Darwinian view as “just a theory.”
°
As
we have seen,
°
The
effects of natural selection can be observed in nature.
·
What
is theoretical about evolution?
°
The
term theory has a very different
meaning in science than in everyday use.
°
The
word theory in colloquial use is
closer to the concept of a hypothesis
in science.
·
In
science, a theory is more comprehensive than a hypothesis, accounting for many
observations and data and attempting to explain and integrate a great variety
of phenomena.
·
A
unifying theory does not become widely accepted unless its predictions stand up
to thorough and continual testing by experiments and additional observation.
°
That
has certainly been the case with the theory of evolution by natural selection.
·
Scientists
continue to test this theory.
°
For
example, many evolutionary biologists now question whether natural selection is
the only mechanism responsible for evolutionary history.
°
Other
factors may have played an important role, particularly in the evolution of
genes and proteins.
·
By
attributing the diversity of life to natural causes,
°
As