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The Evolution Of Populations

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Title: The Evolution Of Populations


1
The Evolution Of Populations
2
Evolution and Variation
  • Microevolution- small scale evolution change in
    allele frequencies in a population over
    generations.
  • Discrete Characters- classified on an either-or
    basis
  • Quantitative Characters- vary along a continuum
  • Average Heterozygosity- (gene variability) the
    average percent of loci that are heterozygous.
  • Nucleotide Variability- comparing DNA sequences
    of two individuals
  • Geographic Variation- differences in genetic
    composition of separate populations.

3
Mutation
  • Mutation- the ultimate source of new alleles
  • Point mutations- a change in one base in a gene
  • Neutral and Beneficial Mutations
  • Mutations Rates
  • Plants/Animals- 1/100,000 genes per generation
  • Prokaryotes- fewer mutations, shorter generation
    span, more genetic variation
  • Viruses- more mutations, shorter generation span,
    RNA genome with fewer repair mechanisms

4
Gene Pools and Allele Frequency
  • Population- a group of individuals of the same
    species that live in the same area and
    interbreed, producing fertile offspring.
  • Gene pool- all of the alleles for all the loci in
    all individuals of the population.
  • Fixed- only one allele exists for a particular
    locus and all individuals are homozygous for that
    allele

5
Hardy-Weinberg Principle
  • H-W Equilibrium describes a constant frequency of
    alleles within a gene pool.
  • p2 2pq q2 1
  • where p2 and q2 represent the frequencies of the
    homozygous genotypes and 2pq represents the
    frequency of the heterozygous genotype

Alleles in the population
Frequencies of alleles
Gametes produced
p frequency of
Each egg
Each sperm
CR allele 0.8
q frequency of
80 chance
80 chance
20 chance
20 chance
CW allele 0.2
6
Hardy-Weinberg Assumptions
  • No mutations
  • Random mating
  • No natural selection
  • Extremely large population size
  • No gene flow
  • Departure from any of these conditions usually
    results in evolutionary change.

7
Practice Hardy-Weinberg Problem
  • For a locus with two alleles (A and a) in a
    population at risk from an infections
    neurodegenerative disease, 16 people had genotype
    AA, 92 had genotype Aa, and 12 had genotype aa.
    Use the Hardy-Weinberg equation to determine
    whether this population appears to be evolving.

8
mechanisms that alter allele frequency
  • Natural selection
  • Leads to adaptive radiation
  • Genetic drift
  • Founder Effect- a few individuals become isolated
    from the larger population- establish new
    population with different allele frequencies.
  • Bottleneck Effect- a sudden change in the
    environment causing reduction in population size
    and altering allele frequency. Ex fires, flood
  • Gene Flow- the transfer of alleles into or out of
    a population due to the movement of fertile
    individuals or their gametes.

9
Founder Effect
10
B
Fig. 23-9
Original population
Bottlenecking event
Surviving population
11
Effects of Genetic Drift
  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

12
Natural Selection and Adaptive Evolution
  • Relative Fitness- the contribution an individual
    makes to the gene pool of the next generation,
    relative to the contributions of other
    individuals.

13
Directional Selection
Original population
Frequency of individuals
  • Occurs when conditions favor individuals
    exhibiting one extreme of a phenotypic range.

Phenotypes (fur color)
Original population
Evolved population
(a) Directional selection
14
Disruptive Selection
Fig. 23-13b
Original population
Frequency of individuals
  • Occurs when conditions favor individuals at both
    extremes of a phenotypic range over individuals
    with intermediate phenotypes.

Phenotypes (fur color)
Evolved population
(b) Disruptive selection
15
StabilizingSelection
Fig. 23-13c
Original population
Frequency of individuals
  • Acts against both extreme phenotypes and favors
    intermediate variants.

Phenotypes (fur color)
Evolved population
(c) Stabilizing selection
16
  • Sexual Selection
  • a form of natural selection in which individuals
    with certain inherited characteristics are more
    likely than other individuals to obtain mates.
  • Sexual Dimorphism
  • marked differences between the two sexes in
    secondary sexual characteristics, which are not
    directly associated with reproduction or
    survival.
  • Intrasexual Selection
  • Selection within the same sex. Individuals of
    one sex compete directly for mates of the
    opposite sex.
  • Intersexual Selection
  • mate choice- individuals of one sex (usually
    females) are choosy in selecting their mates from
    the other sex.

17
Preservation of Genetic Variation
  • Diploidy
  • Hides genetic variation from selection in the
    form of recessive alleles
  • Balancing Selection
  • Occurs when natural selection maintains two or
    more forms in a population.
  • Heterozygote Advantage
  • Individuals who are heterozygous at a particular
    locus have greater fitness than do both kinds of
    homozygotes
  • Frequency-Dependent Selection
  • The fitness of a phenotype declines if it becomes
    too common in the population
  • Neutral Variation
  • Has no selective advantage or disadvantage

18
Why Natural Selection Cannot Fashion Perfect
Organisms
  • Selection can only act on existing variations.
  • Evolution is limited by historical constraints.
  • Adaptations are often compromises
  • Chance, natural selection, and the environment
    interact.

19
Exit Slip
  • Of all the mutations that occur in a population,
    why do only a small fraction become widespread
    among the populations members?
  • If a population stopped reproducing sexually (but
    still reproduced asexually), how would its
    genetic variation be affected over time? Explain.
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