Chapter 17 Speciation and Macroevolution 2023.pdf

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Title

Chapter 17
Speciation and
Macroevolution

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Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
 Outline

17.1 How New Species Evolve
17.2 Modes of Speciation
17.3 Principles of Macroevolution

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 Outcomes
17.1 How New Species Evolve
1) Compare and contrast the processes of
microevolution and macroevolution
2) Use a phylogeny (phylogenetic tree) to explain
the “anatomy“ of speciation.
3) Explain four ways that species are defined
4) Identify and compare features of prezygotic and
postzygotic reproductive isolation.

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 17.1 How New Species Evolve/Separation of
Species

1. Microevolution is any allele frequency change
within the gene pool of a population.
2. Macroevolution is evolution on a large scale.
Macroevolution involves the splitting of one
species into two or more species, or speciation
= origin of species.
Final result of changes in gene pool allelic and
genotype frequencies.
READ
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A. The Anatomy of Speciation
(Theme Evolution)
1. Phylogeny is a tool evolutionary biologists use to
investigate the history of evolution among organisms.
2. The following are some important terms used with a
phylogenetic tree:
a. Node: the point where two lineages intersect, and
represent a shared common ancestor.
b. Root: the origin of species’ shared common ancestry.
c. Extinction: an extinct taxon is represented by a
shortened branch on the phylogenetic tree.
d. Monophyletic group (monophyly): also known as a
clade. A group of species and their common ancestor.

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Fig. 17A

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B What is a Species?.

1. Taxonomists are scientists who classify
living organisms into groups.
2. These classification groups can change
over time, as new information unfolds.

3. The four species concepts are the
# morphological species concept,
# the evolutionary species concept,
# the phylogenetic species concept and
# the biological species concept
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 4. The morphological species concept
is based on differences in appearance or
morphology; it states that each species is defined by
one or more distinct physical characteristics called
diagnostic traits that distinguish one species from
another.
a. An advantage of this species concept is that it
can be used to diagnose new species in the fossil
record.
b. Another advantage is that it applies to both
sexually and asexually reproducing organisms.
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The morphological species concept (cont)

c. A disadvantage is some species do not
have many measurable traits (bacteria and
other microorganisms), and some trait
differences are subtle and difficult to detect.
d. Another disadvantage:sexual dimorphism.

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5. The evolutionary species concept
was proposed to explain speciation in the fossil
record.
a. Also relies on identification of certain
morphological diagnostic traits to distinguish
one species from another.
b. In addition, it also requires that the members
of a species share the same distinct, evolutionary
pathway.

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Fig. 17.2

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6. The phylogenetic species concept
states that an evolutionary family tree
(phylogeny) is used to identify species
based on a common ancestor.
a. An advantage of defining species
according to this concept is that it does
not rely only on morphological traits to
define a species.
b. A branch of a phylogenetic tree that
contains all of the descendants of a
common ancestor is monophyletic.
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7.The biological species concept
says that the members of one species
interbreed and have a shared gene pool,
and each species is reproductively
isolated from every other species.

a. An advantage to this species concept is
that it can designate species even when
trait differences may be difficult to
find.
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b. A disadvantage is that this concept cannot
be applied to:
1. asexually reproducing organisms
2. organisms only known by the fossil
record, or
3. species that could possibly interbreed if
they lived near one another.

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 B. Reproductive Isolating Mechanisms

1. For two species to be separate, gene
flow must not occur between them.

2. A reproductive isolating mechanism is
any structural, functional, or behavioral
characteristic that prevents successful
reproduction from occurring

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3. Prezygotic (“before formation of
a zygote”) isolating mechanisms are
anatomical or behavioral differences
between the members of two species
that prevent mating or make it unlikely
fertilization will take place if mating
occurs
Examples in textbook: read

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a. Habitat isolation occur when
two species occupy
different habitats, even within the
same geographic range, so that
they are less likely to meet and to
attempt to reproduce

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 b.Temporal isolation
occurs when two species live in the
same location, but each reproduces at a
different time of year, and so they do
not attempt to mate

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Fig. 17.5

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c. Behavioral isolation
results from differences in mating
behavior between two species.

d. Mechanical isolation
is the result of differences between
two species in reproductive structures
or other body parts, so that mating is
prevented

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e. Gamete isolation
includes incompatibility of gametes of
two different species so they cannot
fuse to form a zygote; an egg may have
receptors only for the sperm of its own
species or a plant stigma prevents
completion of pollination.

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4.Postzygotic (“after formation of a zygote”)
isolating mechanisms prevent development
of a hybrid after formation of the zygote has
taken place. Examples: Textbook
a. Hybrid inviability (zygot mortality) is
when hybrids (offspring of parents of two
different species) = zygote/embryo do not
develop properly.
b. Hybrid sterility occurs when the hybrid
offspring are sterile (e.g., mules).
c. F2 Fitness : Hybrid is fertile, but F2
hybrid has reduced fitness.
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Fig. 17.4

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 Outcomes
17.2 Modes of Speciation
1) Define two modes of speciation and give
examples of each
2) Explain adaptive radiation with the aid of an
example.
3) Discuss convergent and divergent evolution.
Refer to relevant examples.

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 17.2 Modes of Speciation

1. Speciation is the splitting of one species
into two or more species or the
transformation of one species into a new
species over time.
2. Researchers recognize two modes of
speciation: geographic isolation and
reproductive isolation.

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 A. Allopatric Speciation

1. Allopatric speciation occurs when new
species result from populations being
separated by a geographical barrier that
prevents their members from reproducing
with each other.
2. First proposed by Ernst Mayr of Harvard
University.
3. While geographically isolated, variations
accumulate until the populations are
reproductively isolated.
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 4. Examples of Allopatric Speciation

a. An ancestral population of Ensatina
salamanders migrated from northern
California to southern California. The
Central Valley prevented gene flow between
the eastern and western populations of these
salamanders. Genetic differences increased
resulting in two distinct forms of Ensatina
salamanders

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Fig. 17.8

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 b. The green iguana of South
America is believed to be the common
ancestor for the marine iguana on the
Galápagos Islands (to the west) and
the rhinoceros iguana on Hispaniola
(to the north). A few of these iguanas
may have swam to the islands and
over time formed populations separate
from each other and from the parent
population of South America
Read Paragraph
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Fig. 17.9

Read in text book and discuss also video

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 5. Reinforcement of Reproductive
Isolation

a. A side effect to adaptive changes
involving mating is reproductive
isolation.
b. As populations become reproductively
isolated, postzygotic isolating
mechanisms may arise before prezygotic
isolating mechanisms

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 5. Reinforcement of Reproductive
Isolation

c. An example is a horse reproducing with
a donkey, resulting in a sterile mule.
d. Natural selection would favor any
variation in populations that prevents the
occurrence of hybrids when they do not
have offspring.
e. Reinforcement refers to the process of
natural selection favoring variations that
lead to reproductive isolation. (read)
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 B. Sympatric Speciation

1. Speciation without the presence of a
geographical barrier is sympatric
speciation.
2. Sympatric speciation would occur when
members of a single population develop a
genetic difference (e.g., chromosome number)
that prevents them from reproducing with the
parent type.

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2. Polyploidy is when an organism has a
chromosome number beyond the diploid (2n)
number.
a. Polyploidy is predominantly seen in plants
and makes a significant contribution to the
evolution of new plants.
b. A polyploidy plant can reproduce with
itself, but cannot reproduce with the 2n
population.
c.The two types of polyploidy are autoploidy
and alloploidy.

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3. Autoploidy occurs when a diploid
plant produces diploid gametes due
to nondisjunction during meiosis.
a. A triploid (3n) plant is sterile
because the chromosomes cannot pair
during meiosis. (fruit without seeds)
b. If two diploid gametes fuse, the plant
is a tetraploid (4n) and the plant is
fertile, so long as it reproduces with
another of its own kind.
(Larger fruit) Strawberries (8n)

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4. Alloploidy requires two
different but related species of
plants to hybridize.
a. When hybridization occurs, it
is followed by chromosome
doubling.
b. However, the offspring that has
parents with different numbered
pairs of chromosomes will be
sterile.
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c.An example of alloploidy can be seen
in the wheat plant used to produce
bread.
The parents of the present day bread
wheat had 28 and 14 chromosomes.
The hybrid with 21 chromosomes is
sterile, but bread wheat with 42
chromosomes is fertile since the
chromosomes can pair during meiosis

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 C. Adaptive Radiation
1. Adaptive radiation is a type of
allopatric speciation that occurs
when a single ancestral species
rapidly gives rise to a variety of
species, each adapted to a specific
environment.
2. An ecological niche is where a
species lives and how it interacts
with other species.

Ecological release?
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3. The case of Darwin’s finches illustrates the
adaptive radiation of 13 species from one
founder mainland finch.
Words to remember:
Ancestral ˃ descendants ˃ ecological release
˃ open niches ˃ geographical isolation ˃
natural selection ˃ adaptation ˃ speciation
4.On the Hawaiian Islands, a wide
variety of honeycreepers descended
from one goldfinch-like ancestor
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Fig. 17.11

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 1. Convergent evolution occurs when a
similar biological trait evolves in two
unrelated species as a result of exposure to
similar environments.
2. Analogous traits are those that evolve
convergent in two unrelated lineages
because of a response to a similar lifestyle or
habitat.
3. Homologous traits are those that
are similar because they evolved from a
common ancestor
Divergent evolution: different selection pressures
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Analogous traits

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Analogous structures that
resemble each other due to parallel
adaptations to similar
environments are results of
convergent evolution.
The wings of these flying animals
are superficially similar but have
different anatomical bases from
unrelated lineages: bird, reptile,
and mammal
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Homologous
traits

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 Outcomes
17.3 Principles of Macroevolution
1) Discriminate between the gradualistic and
punctuated equilibrium models of evolution.
2) Explain how gene expression can influence
speciation.
3) Support, by providing an example, that
macroevolution is not goal orientated.

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 17.3 Principles of Macroevolution

1. Macroevolution is the evolution of new species and
higher levels of classification.
2. Some evolutionists support a gradualistic model of
macroevolution, meaning that speciation occurs after
populations become isolated, with each group
continuing slowly on its own evolutionary pathway.

a. According to this model, ancestral species gradually
gives rise to two separate species.

b. This model suggests that it is difficult to indicate when
speciation occurred because there would be so many
transitional links.

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Fig. 17.13

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3. Other evolutionists support a punctuated
equilibrium model to explain the pace of
evolution.
a. According to this model, periods of
equilibrium (no change) are
punctuated (or interrupted) by
speciation.
b. This model suggests that transitional
links are less likely to become fossils
and less likely to be found.

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c. Speciation is more likely to involve only an
isolated population at one locate, because a
favorable genotype could spread more rapidly
within such a population.

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Fig. 17.13

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4. These two models could both
assist in interpretation of the fossil
record. For example, some species
may fit into one model, and other
species.into the other model OR?
Textbook: Read

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A. Genetic Basis of Beak Shape in Darwin’s Finches
(Nature of Science reading) LINK

1. The finches on the Galapagos Islands are an example of
species originating from a common ancestor.
2. Each type of finch adapted to a particular way of life, and
their beak size and shape is related to their diet.
3. DNA sequencing supports that Darwin’s finches are
closely related to one another.
4. In 2006, two genes that are responsible for finch beak
shape were discovered.
a. The gene for bone morphogenic protein 4 (Bmp4)
determines how deep or tall the beak will be.
b. The gene for calmodulin (CaM) regulates how long a
beak will grow.

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 B. Developmental Genes and
Macroevolution

1. Genes can bring about radical changes in
body shapes and organs.
a.The Pax6 gene is involved in eye
formation in all organisms.
b. Homeotic (Hox) genes determine the
location of repeated structures in all vertebrates.
c. Tbx5 gene: limb development.

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2. Gene expression influences organisms’
developmental processes.

a. These genes can bring about huge
changes in body shapes and organs.

b. Despite millions of years of divergent
evolution, all animals share the same control
switches for development.
Read: Textbook
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 3. Development of the Eye

a.Eyes of species vary in size, compound or
simple, etc.
b. Despite these differences, there is one
gene, Pax6, required for eye formation.
c. The gene Pax6 was discovered by Walter
Gehrig and colleagues in 1994.
d. Interestingly, the mouse Pax6 gene can
cause an eye to develop in the leg of a fruit fly

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 4. Development of Limbs

a. The Tbx5 gene for the development of
limbs in humans and wings in birds.
b.Tbx5 triggers different genes in
birds and humans, which may explain
why the same protein is used in
developing limbs in humans and
wings in birds.
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5. Development of Overall Shape
a. Hox genes control the number and
appearance of repeated structures along the
main body axes of vertebrates (= segmented
animals)
b. Shifts when the Hox gene is expressed
can explain why some vertebrates, like the
snake, have hundreds of vertebrae, and
others, like the chick only have seven.

Read
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 7. Human Evolution

a. Human DNA base sequencing is
similar to that of chimpanzees, mice,
and all vertebrates.

b. Scientists predict that differential
gene expression and/or new functions
for “old” genes will explain how humans
evolved.
Read
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C. Macroevolution Is Not Goal-
Oriented
1. The evolution of the horse, Equus,
seems to represents a gradual, directed
straight-line evolution until its goal,
the modern horse, has been achieved.
a.The trends seen in the evolution
of the horse are: increase in overall
size, toe reduction, and change in tooth
size and shape

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2. However, based on fossils, it is easier to see
that the horse lineage is not a straight-line
evolution, but rather forming a thick bush of
many equine species.
3. One may have deducted that since the only
genus that remains is Equus and the other genera
have become extinct, that evolution was directed
towards producing Equus. However, each of the
ancestral species was adapted to its environment

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4. Adaptation occurs because the members
of a population with an advantage are able to
have more offspring than other members.

5. Natural selection is not goal-oriented, but
rather opportunistic.

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Fig. 17.17

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