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Transcript of Chapter 23: The Evolution of Populations. Chapter 23 Assignment 1. Define the terms population,...
![Page 1: Chapter 23: The Evolution of Populations. Chapter 23 Assignment 1. Define the terms population, species, gene pool, relative fitness, and neutral variation.](https://reader036.fdocuments.in/reader036/viewer/2022081508/56649e415503460f94b33b50/html5/thumbnails/1.jpg)
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Chapter 23: The Evolution of Populations
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Chapter 23 Assignment
1. Define the terms population, species, gene pool, relative fitness, and neutral variation
2. List the five conditions of Hardy-Weinberg equilibrium.
3. Hardy – Weinberg Equilibrium Problems (to be distributed later)
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Overview: The Smallest Unit of Evolution
One misconception is that organisms evolve, in the Darwinian sense, during their lifetimes
Natural selection acts on individuals, but only populations evolve
Genetic variations in populations contribute to evolution
Microevolution is a change in allele frequencies in a population over generations
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Concept 23.1: Mutation and sexual reproduction produce
the genetic variation that makes evolution possible
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Two processes, mutation and sexual reproduction, produce the variation in gene pools that contributes to differences among individuals
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Genetic Variation
Variation in individual genotype leads to variation in individual phenotype
Not all phenotypic variation is heritable
Natural selection can only act on variation with a genetic component
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Fig. 23-2
(a)
(b)
Nonheritable variation: these caterpillars display phenotypes based on their diets, not their genes.
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Variation Within a Population
Both discrete and quantitative characters contribute to variation within a population
Discrete characters can be classified on an either-or basis
Quantitative characters vary along a continuum within a population
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Average Heterozygosity
Population geneticists measure polymorphisms in a population by determining the amount of heterozygosity at the gene and molecular levels
Average heterozygosity measures the average percent of loci that are heterozygous in a population
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Variation Between Populations
Geographic variation: differences between gene pools of separate populations or population subgroups
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Fig. 23-3
13.17
19 XX10.16
9.128.11
1 2.4
3.14 5.18 6 7.15
9.10
1 2.19
11.12
13.17
15.18
3.8 4.16 5.14 6.7
XX
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• Some examples of geographic variation occur as a cline, which is a graded change in a trait along a geographic axis• Examples: frequency of an allele present
in the population`
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How do new alleles arise?
Mutations: Gene (point mutations) Chromosomal
Sexual reproduction
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Mutation
Mutations are changes in the nucleotide sequence of DNA
Mutations cause new genes and alleles to arise
Only mutations in cells that produce gametes can be passed to offspring
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Point Mutations
A point mutation is a change in one base in a gene
Point mutations can vary in severity: Noncoding regions – point mutation has no effect on
gene expression Can be more severe – sickle-cell disease
Rarely do mutations increase the organism’s fitness – most mutations have a negative effect on the organism
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Mutations That Alter Gene Number or Sequence
Chromosomal mutations that delete, disrupt, or rearrange many loci are typically harmful
Duplication of large chromosome segments is usually harmful Duplication of small pieces of DNA is sometimes less
harmful and increases the genome size Duplicated genes can take on new functions by
further mutation
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Mutation Rates
Mutation rates are low in animals and plants Why?
The average is about one mutation in every 100,000 genes per generation
Mutations rates are often lower in prokaryotes and higher in viruses Why are mutations higher in viruses?
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Sexual Reproduction
3 mechanisms: Crossing over Independent assortment Fertilization
Shuffle existing alleles into new combinations
In organisms that reproduce sexually, recombination of alleles is more important than mutation in producing the genetic differences that make adaptation possible
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Concept 23.2: The Hardy-Weinberg equation can be
used to test whether a population is evolving
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Gene Pools and Allele Frequencies
• A population is a localized group of individuals capable of interbreeding and producing fertile offspring
A gene pool consists of all the alleles for all loci in a population
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Fig. 23-5Porcupine herd
Porcupineherd range
Beaufort Sea
NORTH
WES
T
TERRITO
RIES
MAPAREA
ALA
SK
A
CA
NA
DA
Fortymileherd range
Fortymile herd
ALA
SK
A
YU
KO
N
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Hardy-Weinberg Principle
Determine if a population is evolving or not
Calculate allele frequencies of hypothetical non-evolving populations and compare to actual frequencies of sample population Allele frequencies should remain constant from one
generation to the next if there is no evolution
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The frequency of an allele in a population can be calculated For diploid organisms, the total number of alleles at a locus is
the total number of individuals x 2 The total number of dominant alleles at a locus is 2 alleles for
each homozygous dominant individual plus 1 allele for each heterozygous individual; the same logic applies for recessive alleles
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By convention, if there are 2 alleles at a locus, p and q are used to represent their frequencies
The frequency of all alleles in a population will add up to 1 For example, p + q = 1
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Fig. 23-6
Frequencies of alleles
Alleles in the population
Gametes produced
Each egg:
Each sperm:
80%chance
80%chance
20%chance
20%chance
q = frequency of
p = frequency ofCR allele = 0.8
CW allele = 0.2
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Hardy-Weinberg equilibrium describes the constant frequency of alleles in such a gene pool
If p and q represent the relative frequencies of the only two possible alleles in a population at a particular locus, then p2 + 2pq + q2 = 1 where p2 and q2 represent the frequencies of the
homozygous genotypes and 2pq represents the frequency of the heterozygous genotype
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Hardy-Weinberg Equilibrium Equation
p2 + 2pq + q2 = 1 Where p2 and q2 represent the
frequencies of the homozygous genotypes and 2pq represents the frequency of the heterozygous genotype
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Fig. 23-7-1
SpermCR
(80%)
CW
(20
%)
80% CR ( p = 0.8)
CW (20%)
20% CW (q = 0.2)
16% ( pq) CRCW
4% (q2) CW CW
CR
(80
%)
64%
( p2) CRCR
16% (qp) CRCW
Eg
gs
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Fig. 23-7-2
Gametes of this generation:
64% CRCR, 32% CRCW, and 4% CWCW
64% CR + 16% CR = 80% CR = 0.8 = p
4% CW + 16% CW = 20% CW = 0.2 = q
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Fig. 23-7-3
Gametes of this generation:
64% CRCR, 32% CRCW, and 4% CWCW
64% CR + 16% CR = 80% CR = 0.8 = p
4% CW + 16% CW = 20% CW = 0.2 = q
64% CRCR, 32% CRCW, and 4% CWCW plants
Genotypes in the next generation:
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Conditions for Hardy-Weinberg Equilibrium
The Hardy-Weinberg theorem describes a hypothetical population
In real populations, allele and genotype frequencies do change over time
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The five conditions for nonevolving populations are rarely met in nature:
No mutations
Random mating
No natural selection
Extremely large population size
No gene flow
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Natural populations can evolve at some loci, while being in Hardy-Weinberg equilibrium at other loci
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Hardy-Weinberg Practice Problems and Homework
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Practice Problem 1
1. You have sampled a population in which you know that the percentage of the homozygous recessive genotype (aa) is 36%. Using that 36%, calculate the following:• The frequency of the "aa" genotype.• The frequency of the "a" allele.• The frequency of the "A" allele.• The frequencies of the genotypes "AA" and
"Aa.“• The frequencies of the two possible phenotypes
if "A" is completely dominant over "a."
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Concept 23.3: Natural selection, genetic drift, and gene flow can alter allele
frequencies in a population
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Three major factors alter allele frequencies and bring about most evolutionary change: Natural selection Genetic drift Gene flow
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Natural Selection
Differential success in reproduction results in certain alleles being passed to the next generation in greater proportions
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Genetic Drift
The smaller a sample, the greater the chance of deviation from a predicted result
Genetic drift describes how allele frequencies fluctuate unpredictably from one generation to the next
Genetic drift tends to reduce genetic variation through losses of alleles
2 examples: Founder Effect, Bottleneck Effect
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Fig. 23-8-1
Generation 1p (frequency of CR) =
0.7q (frequency of CW ) =
0.3
CW CW
CR CR
CR CW
CR CR
CR CR
CR CR
CR CR
CR CW
CR CW
CR CW
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Fig. 23-8-2
Generation 1p (frequency of CR) =
0.7q (frequency of CW ) =
0.3
Generation 2 p =
0.5q = 0.5
CW CW
CR CR
CR CW
CR CR
CR CR
CR CR
CR CR
CR CW
CR CW
CR CW
CR CWCR CW
CR CW
CR CW
CW CW
CW CW
CW CW
CR CR
CR CR
CR CR
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Fig. 23-8-3
Generation 1
CW CW
CR CR
CR CW
CR CR
CR CR
CR CR
CR CR
CR CW
CR CW
CR CW
p (frequency of CR) = 0.7q (frequency of CW
) = 0.3
Generation 2
CR CWCR CW
CR CW
CR CW
CW CW
CW CW
CW CW
CR CR
CR CR
CR CR
p = 0.5q = 0.5
Generation 3 p =
1.0q = 0.0
CR CR
CR CR
CR CR
CR CR
CR CR
CR CR CR CR
CR CR
CR CR CR CR
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The Founder Effect
The founder effect occurs when a few individuals become isolated from a larger population
Allele frequencies in the small founder population can be different from those in the larger parent population
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The Bottleneck Effect
The bottleneck effect is a sudden reduction in population size due to a change in the environment
The resulting gene pool may no longer be reflective of the original population’s gene pool
If the population remains small, it may be further affected by genetic drift
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Fig. 23-9
Originalpopulatio
n
Bottlenecking
event
Survivingpopulatio
n
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Effects of Genetic Drift: A Summary
1. Genetic drift is significant in small populations
2. Genetic drift causes allele frequencies to change at random
3. Genetic drift can lead to a loss of genetic variation within populations
4. Genetic drift can cause harmful alleles to become fixed
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Gene Flow
Gene flow consists of the movement of alleles among populations
Alleles can be transferred through the movement of fertile individuals or gametes (for example, pollen)
Gene flow tends to reduce differences between populations over time
Gene flow is more likely than mutation to alter allele frequencies directly
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Gene flow can decrease the fitness of a population
In bent grass, alleles for copper tolerance are beneficial in populations near copper mines, but harmful to populations in other soils
Windblown pollen moves these alleles between populations
The movement of unfavorable alleles into a population results in a decrease in fit between organism and environment
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Fig. 23-12
NON-MINESOIL
MINESOIL
NON-MINESOIL
Prevailing wind direction
Ind
ex o
f cop
per
tole
ran
ce
Distance from mine edge (meters)
70
60
50
40
30
20
10
020 0 20 0 20 40 60 80 10
0120
140
160
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Gene flow can increase the fitness of a population
Insecticides have been used to target mosquitoes that carry West Nile virus and malaria
Alleles have evolved in some populations that confer insecticide resistance to these mosquitoes
The flow of insecticide resistance alleles into a population can cause an increase in fitness
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Concept 23.4: Natural selection is the only mechanism that
consistently causes adaptive evolution
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Only natural selection consistently results in adaptive evolution
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A Closer Look at Natural Selection
Natural selection brings about adaptive evolution by acting on an organism’s phenotype
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Relative Fitness
The phrases “struggle for existence” and “survival of the fittest” are misleading as they imply direct competition among individuals
Reproductive success is generally more subtle and depends on many factors
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Relative fitness is the contribution an individual makes to the gene pool of the next generation, relative to the contributions of other individuals
Selection favors certain genotypes by acting on the phenotypes of certain organisms
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Directional, Disruptive, and Stabilizing Selection
Three modes of selection: Directional selection favors individuals at one end of the
phenotypic range Disruptive selection favors individuals at both extremes
of the phenotypic range Stabilizing selection favors intermediate variants and
acts against extreme phenotypes
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Fig. 23-13a
Original population
(a) Directional selection
Phenotypes (fur color)
Fre
qu
en
cy o
f in
div
idu
als
Original population
Evolved population
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Fig. 23-13b
Original population
(b) Disruptive selection
Phenotypes (fur color)
Fre
qu
en
cy o
f in
div
idu
als
Evolved population
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Fig. 23-13c
Original population
(c) Stabilizing selection
Phenotypes (fur color)
Fre
qu
en
cy o
f in
div
idu
als
Evolved population
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The Key Role of Natural Selection in Adaptive
Evolution
Natural selection increases the frequencies of alleles that enhance survival and reproduction
Adaptive evolution occurs as the match between an organism and its environment increases
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Fig. 23-14
(a) Color-changing ability in cuttlefish
(b) Movable jaw bones in snakes
Movable bones
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Because the environment can change, adaptive evolution is a continuous process
Genetic drift and gene flow do not consistently lead to adaptive evolution as they can increase or decrease the match between an organism and its environment
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Sexual Selection
Sexual selection is natural selection for mating success
It can result in sexual dimorphism, marked differences between the sexes in secondary sexual characteristics
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Fig. 23-15
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Intrasexual selection is competition among individuals of one sex (often males) for mates of the opposite sex
Intersexual selection, often called mate choice, occurs when individuals of one sex (usually females) are choosy in selecting their mates
Male showiness due to mate choice can increase a male’s chances of attracting a female, while decreasing his chances of survival
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How do female preferences evolve?
The good genes hypothesis suggests that if a trait is related to male health, both the male trait and female preference for that trait should be selected for
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Fig. 23-16
SC male graytree frog
Female graytree frog LC male
graytree frog
EXPERIMENT
SC sperm Eggs LC sperm
Offspring ofLC father
Offspring ofSC father
Fitness of these half-sibling offspring compared
RESULTS
1995Fitness Measure
1996
Larval growth
Larval survival
Time to metamorphosis
LC better
NSD
LC better(shorter)
LC better(shorter)
NSD
LC better
NSD = no significant difference; LC better = offspring of LC malessuperior to offspring of SC males.
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Fig. 23-16a
SC male graytree frog
Female graytree frog LC male
graytree frog
SC sperm Eggs LC sperm
Offspring ofLC father
Offspring ofSC father
Fitness of these half-sibling offspring compared
EXPERIMENT
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Fig. 23-16b
RESULTS
1995Fitness Measure 1996
Larval growth
Larval survival
Time to metamorphosis
LC better
NSD
LC better(shorter)
LC better(shorter)
NSD
LC better
NSD = no significant difference; LC better = offspring of LC malessuperior to offspring of SC males.
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The Preservation of Genetic Variation
Various mechanisms help to preserve genetic variation in a population
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Diploidy
Diploidy maintains genetic variation in the form of hidden recessive alleles
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Balancing Selection
Balancing selection occurs when natural selection maintains stable frequencies of two or more phenotypic forms in a population
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Heterozygote Advantage
• Heterozygote advantage occurs when heterozygotes have a higher fitness than do both homozygotes
• Natural selection will tend to maintain two or more alleles at that locus
• The sickle-cell allele causes mutations in hemoglobin but also confers malaria resistance
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Fig. 23-17
0–2.5%
Distribution ofmalaria caused byPlasmodium falciparum(a parasitic unicellular eukaryote)
Frequencies of thesickle-cell allele
2.5–5.0%
7.5–10.0%
5.0–7.5%
>12.5%
10.0–12.5%
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Frequency-Dependent Selection
• In frequency-dependent selection, the fitness of a phenotype declines if it becomes too common in the population
• Selection can favor whichever phenotype is less common in a population
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Fig. 23-18
“Right-mouthed”
1981
“Left-mouthed”
Fre
qu
en
cy o
f“le
ft-m
ou
thed
”
ind
ivid
uals
Sample year
1.0
0.5
0’82
’83
’84
’85
’86
’87
’88
’89
’90
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Neutral Variation
Neutral variation is genetic variation that appears to confer no selective advantage or disadvantage
For example, Variation in noncoding regions of DNA Variation in proteins that have little effect on
protein function or reproductive fitness
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Why Natural Selection Cannot Fashion Perfect
Organisms
1. Selection can act only on existing variations
2. Evolution is limited by historical constraints
3. Adaptations are often compromises
4. Chance, natural selection, and the environment interact