mechanisms of evolution: how evolution happens to populations
DESCRIPTION
Three female African Swallowtail Butterflies ( Papillio dardanus ) from the same population. Mechanisms of Evolution: How evolution happens to populations. Lecture Outline 1. Introductory terms and concepts 2. Darwin, Mendel and the Modern Synthesis 3. Genetic Variation within Populations - PowerPoint PPT PresentationTRANSCRIPT
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Mechanisms of Evolution:
How evolution happens to populations
Three female African Swallowtail Butterflies (Papillio dardanus) from the same population.
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Lecture Outline
1. Introductory terms and concepts
2. Darwin, Mendel and the Modern Synthesis
3. Genetic Variation within Populations
4. Genetic composition of a population may change intergenerationally; this is evolution, and one or more processes may contribute to that change
5. The effect of natural selection on frequency distribution of phenotypes and genotypes within a population varies depending on the nature of the selective force or forces operating on individuals
6. We know that variability is often maintained (not lost) over time in populations [ie, recognize a pattern], and we know something about the processes by which variability is maintained.
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1. Introductory terms and concepts
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Concepts and Terms
Species: A group of populations whose individuals have the potential to interbreed and produce fertile offspring in nature
Population: Localized group of individuals belonging to the same species
Deme: Locally interbreeding group within a population
Gene Flow: Consequence of migration between populations, followed by breeding.
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Homologous pair of chromosomes in diploid parent cell
Homologous Pair of replicated chromosomesSister Chromatids
Homologous chromosomes separate
Sister chromatids separate
Chromosomes replicate
Meiosis: Diploid parent cell to haploid daughter cells (gametes)
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Meiosis I; homologs distributed to daughter cells
Meiosis II; chromatids distributed to daughter cells
Review terms:
-Sexual reproduction-Meiosis, Mitosis-Diploid organism-Homologous chromosomes-Sister chromatids-Gene-Locus-Allele
Sexual Reproduction fosters genetic diversity
•Random selection of half a parents diploid chromosome set to make a haploid gamete
•Fusion of two such haploid gametes to produce a diploid organism
Products of Meiosis are genetically diverse for two reasons
•Crossing over results in recombinant chromatids that contain some genetic material from each chromososome
•It is a matter of chance as to which member of a homologous pair of chromosomes goes to which daughter cellOverview of Meiosis
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Genotype; The genetic constitution governing a heritable trait of an organism
Phenotype: Physical expression of an organism’s genotype
Gene Pool: Sum of all alleles in a population
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How to quantify the genetic structure of a population, for a discrete trait controlled by a single gene locus with one recessive and one dominant allele.:
•Allele Frequency
•Genotype Frequency
Phenotypes
Genotypes
Genotype Frequencies
Allele Frequencies
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Consider a population with 500 diploid cats and the single gene locus that controls fur color.
•For individuals in this or any other diploid species, how many times is each locus represented?
•Two (each individual has two “copies” of the gene).
•How many different allelic forms are there in the population?
•Two (B, b)
•How many alleles in the population?
•1000
•What defines an individual “homozygous” at a particular locus?
Same allele at both loci BB or bb
•What defines an individual that is “heterozygous” at a particular locus?
Different alleles at the two loci Bb
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Genotype frequencies: BB 36% Bb 48% bb 16%
In a population of 500 individuals, how many individuals have genotype:
BB 500 (.36) = 180 individuals
Bb 500 (.48) = 240 individuals
bb 500 (.16) = 80 individuals
In a population of 500 individuals, how many copies of the B allele are there?
360 alleles from the BB individuals (all the alleles from BB cats)
+ 240 alleles from the Bb individuals (1/2 the alleles from Bb cats)
= 600 copies of the B allele
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Genotype frequencies: BB 36% Bb 48% bb 16%
In a population of 500 individuals, how many individuals have genotype:
BB 500 (.36) = 180 individuals
Bb 500 (.48) = 240 individuals
bb 500 (.16) = 80 individuals
In a population of 500 individuals, how many copies of the B allele are there?
360 from the BB individuals
+ 140 from the Bb individuals
= 500 copies of the B allele
(500)(.36)+
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Consider a population with 500 diploid cats and the single gene locus that controls fur color.
How many copies of the gene for fur color are there? 1000
Consider our genotype frequencies:
BB 36% Bb 48% bb 16%
In a population of 500 individuals, how many individuals are:
BB 500 (.36) = 180 individuals
Bb 500 (.48) = 240 individuals
bb 500 (.16) = 80 individuals
copies of the B allele are there?
(500)(.36)+
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Model of polygenic inheritance based on three genes
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Connecting population genetics and evolutionary change
• Adaptive Evolution
-Of the agents of evolutionary change, only selection is likely to adapt a population to its environment–Adaptive evolution involves random chance in the form of mutation and sexual recombination and probabilistic sorting in terms of the sifting action of natural selection
• Individual Fitness
–Relative contribution of individual to gene pool of the next generation -- relative to contribution of other individuals in population. Alternatively – can measure “lifetime fitness” – lifetime contribution to the gene pool)
• Genotype Fitness
–Contribution of genotype at a given locus to the next generation relative to contribution of other genotypes in population
• Fitness Quantified
– Relative scale from 0.0 to 1.0, where individual with greatest contribution in population has fitness of 1.0
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2. Darwin, Mendel and the Modern Synthesis
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R.A. Fisher J.B.S. Haldane Seawall Wright (1890-1962) (1892-1964) (1889-1988)
Architects of the modern synthesis -- theoretical population geneticists whose work reconciled Mendelian theory of heredity with Darwin’s theory of natural selection
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Ernst Mayr, on the right, on an ornithological expedition in New Guinea in 1928, with his Malay assistant
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Fundamental Perspectives of the Modern Synthesis
•The units of Evolution: Populations are the fundamental units of evolution
•The mechanism of Evolution. Natural Selection is the most important mechanism of evolution in that it alone results in adaptive evolutionary change
•The tempo of evolution: Gradualism -- large change can and does evolve as an accumulation of small changes over long periods of time.
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The Breach between Darwinism and Mendelism
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3. Genetic variation within populations
Examine the “instantaneous” genetic structure of a sexually reproducing diploid population.
•Allele frequencies
•Genotype frequencies
Examine the “intergenerational behavior” of genetic structure in a sexually reproducing diploid population that is not evolving
•“Hardy-Weinberg Equilibrium”
Consider the causes of microevolution (“non-equilibrium”)
•Natural selection
•Mutation
•Genetic drift
•Gene flow
•Non-Random mating
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Determining the Genetic Structure of a Population (at one locus)
•Genotype Frequencies
•Allele Frequencies
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The genetic (allelic) structure of a population may remain relatively constant over time, ie stay in “equilibrium”
Allele frequencies may change intergenerationally; this is evolution, and one or more processes may cause that change
“Microevolution” refers to evolutionary change within and among populations – ie, within species.
One or more of five processes may drive microevolution:
mutation, selection, drift (chance), nonrandom mating, migration
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Hardy-Weinberg Theorem
Mathematical theorem that shows, based on probability theory, that frequencies of alleles and genotypes in a population's gene pool remain constant over generations unless acted on by agents other than sexual recombination:
•Recombination of alleles, via gametes, due to meiosis and random fertilization has no effect on overall genetic structure of a population
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Assumptions of “Hardy-Weinberg” Equilibrium of Genetic Structure of Populations:
No Mutation No Random changes in genetic material
No Migration [Gene Flow]No Movement of individuals among populations and subsequent breeding
No Genetic Drift No Changes in genetic structure due to chance (dumb luck)
•No Non-Random Mating Gametes (eggs and sperm) are not combined in a completely random fashion
•No Natural Selection Differential reproduction
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Hardy-Weinberg Theorem
•Each gamete carries one allele for flower color
•Allele frequencies among gametes is same as among diploid cells in parent population
For A, p = .8
For a, q = .2
Note: p+q=1
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Hardy-Weinberg Theorem
•One assumption of model (theorem) is that mating in population is completely random
•All sperm and egg unions (fertilizations) are completely random - analogous to putting all gametes in a bag and randomly drawing sperm and eggs, one pair at a time, for each zygote
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Hardy-Weinberg Theorem
Use multiplication rule of probability to determine frequency of genotypes in the next generation:
Probability of two independent events “co-occurring” equals the product of the probabilities of each independent event occurring.
(“Co-occur” = be in the same zygote via fertilization of egg by sperm)
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p2 + 2 pq + q 2 = 1
Freq. Freq. Freqof AA of Aa of aa
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Hardy-Weinberg Theorem -- Its Importance in the Study of Evolution
H-W is a “model” that defines a pattern in nature; the line of reasoning is grounded in mathematics -- probability theory and algebra
•H-W has predictive value
•H-W tells us what genetic structure to expect if a population is not evolving or can tell us about the extent to which a population is evolving
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Using the Hardy-Weinberg Equation
Frequency of allele for an inherited disease; the recessive allele coding for PKU in the U.S. population (A=normal, a=pku)
p2 + 2pq + q2 = 1Freq. AA Freq. Aa Freq. aa 100%
•PKU genotype = aa Carrier genotype = Aa
•Freq. of PKU genotype = q2 Freq. Carrier genotype = 2pq
•Occurrence of PKU = 1 in 10,000 births = .0001
•Freq. of q2 = .0001 Freq. of q = (.0001)1/2 = 0.01
•Freq. of p = 1 - q = 1 - .01 = .99
•Freq. of carriers (heterozyotes) = 2pq = (2)(.99)(.01) = .0198 (=~2%)
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Allele frequencies may change intergenerationally; this is evolution, and one or more processes may cause that change
mutation, selection, drift (chance), nonrandom mating, migration
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Natural Selection Can Cause Evolution
• Inclusive Fitness
Cooperation among Florida Scrub Jays. Helpers, mostly offspring from previous breeding season, improve inclusive fitness by feeding nestlings, defending nest, etc. (p.1126)
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Mutation Can Cause Evolution
•Heritable change in DNA. Various forms of mutation, but most common is point mutation’ substitution of one nucleotide for another “accidentally” during the synthesis of a new DNA strand
•Rate at which mutations occur vary among nucleotide sites in a gene, among genes in an organism
•Mutation frequency typically less than one mutation per 104 genes per DNA duplication
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Non-Random Mating Can Cause Evolution
For H-W equilibrium to hold, individuals must select mates completely at random from a population, but often not the case
•Assortative Mating (individuals select as mates individuals that look like them - e.g.humans)
•Selection of “nearby” mates (promotes inbreeding -- mating of closely related individuals)•Self fertilization - common in plants (extreme case of inbreeding)
Assortative mating in toads (Bufo bufo); males and females tend to mate with individuals similar in size to themselves (in Campbell 1999).
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Thought Experiment:
•What is your expectation regarding the probability of getting heads when you flip a coin? Tails? Why?
• Flip a coin 4 times, record results.
•Flip a coin 4000 times, record results.
• What is your expectation for both sets of trials?
•Which set of trials would you expect to be closer to your expectation?
•Why?
Genetic Drift Can Cause EvolutionGenetic Drift:
Random change in genetic structure of a population
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Sampling Error and Genetic Drift
Sampling Error. Chance events (random departures from expectations based on underlying probabilities) are more likely to occur in small populations than in large populations...
•Chance events are random deviations from expected outcomes.
•Chance events are more likely in small “samples” than in large “samples”
•This phenomenon is know as “sampling error”
Let’s go from dimes and nickels to gametes and alleles…
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Relevance of Sampling Error/Genetic Drift to Population-Level Evolutionary Processes
•Following reproduction in small populations, genetic structure may change, i.e., evolution may happen, strictly due to random deviations from expected outcomes (allele and genotype frequencies in the next generation -- in the Punnett Square)
•A population that experiences a bottleneck -- size reduced to a small number -- may well experience an evolutionary shift in allele and genotype frequencies due to “sampling error” (small sample size of individuals that survive)
•A small founding population, isolated from population at large either by dispersal or vicariance, may well give rise to a new species in time, but will have started that trajectory towards speciation with allele and genotype frequencies different from the larger population from which the founding population arose
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Original population has about equal frequencies of red and yellow alleles
A chance environmental event greatly reduces the populations size
The surviving individuals have different allele frequencies from the original population...
…which generates a new populations with more red than yellow alleles
Bottleneck Effect: The likely consequence of a decrease in population size to very small number of individuals is that genetic structure of the surviving population is not representative of the original population
…in extreme cases, alleles are lost…purged from the population...
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Northern Elephant seals. Reduced to ~20 individuals in 1890’s. Now populations are large and growing, but show extremely low genetic variation. Is low variation a problem, a potential problem? Why?
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Migration can cause evolution
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AA AA Aa
Aa aa Aa
AA Aa
AA Aa
Populations Size
N = 10 individuals
Allele Frequencies
A = 13/20 = .65
a = 7/20 = .35
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A A A A A a
A a a a A a
A A A a
A A A a
Allele frequencies in the “pool of gametes” is the same;
A = .65
a = .35
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A A A A A a
A a a a A a
A A A a
A A A a
Allele frequencies in the “pool of gametes” is the same;
A = .65
a = .35
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A A A A A a
A a a a A a
A A A a
A A A a
Of evolutionary importance are point mutations and other mutations in germ line cells
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A A A A A a
A a a A A a
A A A a
A A A a
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A A A A A a
A a a a A a
A A A a
A A A a
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A A A A A a
A a a A a a
A A A a
A A A aNo net mutational change
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AA AA Aa
Aa aa Aa
Aa aa
Aa Aa
Aa Aa
aa Aa
Aa
Aa aa
AA
Aa Aa
Ri v
er
Deer Mouse population on west side of river
Deer Mouse population on east side of river
Migration and Gene Flow Migration (Gene Flow) Can Cause Evolution
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AA AA Aa
Aa aa Aa
Aa aa
Aa Aa
Aa Aa
aa Aa
Aa
Aa aa
AA
Aa Aa
Ri v
er
Deer Mouse population on west side of river
Deer Mouse population on east side of river
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AA AA Aa
Aa aa Aa
Aa aa
Aa Aa
Aa Aa
aa Aa
Aa
Aa aa
AA
Aa Aa
Ri v
er
Deer Mouse population on west side of river
Deer Mouse population on east side of river
No Net Migration
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0
10
20
30
40
50
60
70
80
90
100
0 100 200 300 400 500 600 700 800 900 1000 1100
Distance (m)
Fru
it S
et (%
)
VA
MS
WI
Pollination and Gene Flow
Dr. Galloway’s grad student, Linda Johnson is studying whether or not the origin of the plants affected the distances that birds carried the pollen and fertilized “target” flowers.
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The effect of natural selection on frequency distribution of phenotypes and genotypes within a population varies depending on the nature of the selective force or forces operating on individuals
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Natural Selection Affects Frequency Distribution of Phenotypes and Underlying Genotypes
• Organismal-level process generates population-level pattern
• The outcome (pattern) depends on which forms of a heritable trait are favored by natural selection. Three principal “modes” of selection are:
• Stabilizing Directional Diversifying
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Stabilizing Selection
• Culls extreme phenotypes at both ends of distribution; phenotypes near mean are favored (pass on more alleles)
• Reduces variation and preserves existing mean phenotype, which is also most common if distribution is normal (bell-shaped)
• Counters evolutionary change because it counters shift in genetic structure
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Example of Stabilizing Selection
Human infants with extremely high and low both weights have higher death rates.
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Directional Selection
• Individuals at one extreme of distribution are “favored”
• Sustained directional selection leads to evolutionary trend
• Such trends may be reversed when environment changes
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Example of Directional Selection
• Cover fisheries march 96
Pink Salmon and Artificial Selection
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Example of Directional Selection
• Directional selection pink salmon page 75 in Ridley,
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Example of Directional Selection in Galapagos
Finches
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Disruptive Selection
• Environment favors phenotypic extremes; selection against intermediate phenotypes
• Sustained selection can leads to bimodal frequency distribution -- balanced polymorphism
• Occurrence rarely documented in nature
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Example of Disruptive Selection
• Black billed Seed-crackers of West Africa
• Two main types of food available; large, hard seed, and small soft seeds
• Two bill polymorphisms are specialized to seed types - intermediates have low survival
Fig 20.10 from Purves
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We know that variability is maintained (not lost) over time in populations [ie, recognize a pattern], and we know something about the processes by which variability is maintained
Genetic variation is the substrate of evolutionGenetic variation is distributed in time and spaceThe extent of genetic variation represents an equilibrium between agents that tend to reduce it, and agents that tend to create or maintain it.Agents such as genetic drift, stabilizing selection, and directional selection tend to reduce genetic variation in a populationWhat agents maintain genetic variation???
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Maintaining Genetic Variation
Genetic polymorphism: • Two or more alleles at a locus
in a population• Polymorphism exists in genes…
and gene products • Table shows degree of genetic
polymorphism in populations• Genetic polymorphism is
extensive in populations, although many of the alleles are present in low frequencies
Fig 18-1 from solomon
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Neutral Variation
Genetic variation that is invisible to natural selection; e.g. silent mutations
Example:
Variable nucleotide sites (top line) in mitochondrial gene in Margined Madtom (Noturus insignis
101 150AGCAGTAGAA GCCGCCACCA AATACTTCTT AGCCCAAGCC GCAG?CCGCACGCAGTAGAA GCCGCC?CCA AATACTTCTT AGCCCAAGCT GCAGCCCGCA
151 200GCAACCATCT TATTTGCCAG TACTATTAAC GCTTGAACTA TAGGAGAGTGGCAACTATCT TATTCGCCAG TACTATTAAT GCTTGAACCA TAGGAGAATG
201 250AAACATCTCT TGTTTAACCC ACCCCGCCGC AACCATTTTA ATTACTATAGAAACATCTCT TGGTTAACCC ACCCCGCCGC AACCATTCTA ATTATAATAG
251 ___ 300CACTGGCTCT TAAAGTGGGA CT??GCCCCA TGCACTTCTG AATGCCCCCCCACTGGCTCT TAAAGTTGGA CTCGCCCCCA TACACTTCTG AATGCCCCCC301 350GTTATGCAAG GCCTAGATCT AATCACCGGA CTAATTATAG CCACCTGACAGTTATACAAG GCCTAGATCT AGTCACCGGA CTAATTATAG CTACCTGACA
3' End of NADH2 gene; N. insignis (variable sites in blue)Compared to N. gilberti.
Maintenance of Genetic Variation via Neutral Variation
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Maintenance of Genetic Variation through Geographic Variation in Environmental Conditions
•Geographic variation in environmental conditions drives variation among populations•Clines: gradual geographic shifts in frequency of genotypes and phenotypes are called clines
– Recurring clinal variation in body size with temperature– Recurring clinal variation in external color with humidity
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Clinal Variation in the Song Sparrow (Melospiza melodia) •The song sparrow is found throughout North America. 31 subspecies, or “races” have been described.
•Along the west coast, the subspecies form well known cline in body size, plumage coloration and song characteristics, from small pale M.m. saltonis of desert southwest, to large dark M.m. maxima of aleution islands.
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• Pic of song sparrow variation from proctor and lynch
Peale’s Peregrine Falcon of the Pacific Northwest and Aleutian Islands
Anatum Peregrine Falcon of the contintental United States
Tundra Peregrine Falcon of the arctic tundra
Peregrine falcons show clinal variation in
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Maintainence of Genetic Variation through Balanced Polymorphism
• Balanced Polymorphism: Special case of genetic polymorphism in which two or more alleles persist in a population over many generations as a result of natural selection
• Example: Black-bellied seed crackers. In this case, an obvious phenotypic polymorphism is associated with the underlying genetic polymorphism
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Maintainence of Genetic Variation throughHeterozygote Advantage
Fig 18-8 in solomon •Distribution of Sickle Cell Anemia (red bars) and distribution of Falciparum malaria
•Homozygous dominants are at disadvantage due to anemia, homozygous recessives due to malaria.
Heterozygote Advantage. Natural selection favors individuals heterozygous at a particular gene locus over individuals homozyous at that locus
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Maintaining Genetic Variation:Frequency Dependent Selection
Fig 18-9 in solomon
•Frequency-dependent selection. Fitness of particular phenotype depends on how frequently it appears in the population
•Often maintains genetic variation in populations of species that are preyed on by a particular predator species
•Demonstrated in water boatmen, which have three color phenotypes
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101 150AGCAGTAGAA GCCGCCACCA AATACTTCTT AGCCCAAGCC GCAG?CCGCACGCAGTAGAA GCCGCC?CCA AATACTTCTT AGCCCAAGCT GCAGCCCGCA
151 200GCAACCATCT TATTTGCCAG TACTATTAAC GCTTGAACTA TAGGAGAGTGGCAACTATCT TATTCGCCAG TACTATTAAT GCTTGAACCA TAGGAGAATG
201 250AAACATCTCT TGTTTAACCC ACCCCGCCGC AACCATTTTA ATTACTATAGAAACATCTCT TGGTTAACCC ACCCCGCCGC AACCATTCTA ATTATAATAG
251 ___ 300CACTGGCTCT TAAAGTGGGA CT??GCCCCA TGCACTTCTG AATGCCCCCCCACTGGCTCT TAAAGTTGGA CTCGCCCCCA TACACTTCTG AATGCCCCCC301 350GTTATGCAAG GCCTAGATCT AATCACCGGA CTAATTATAG CCACCTGACAGTTATACAAG GCCTAGATCT AGTCACCGGA CTAATTATAG CTACCTGACA
3' End of NADH2 gene; N. insignis (variable sites in blue)Compared to N. gilberti.
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Natural Selection Can Cause Evolution
• Inclusive Fitness
Pic of scrub jays from purves
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Natural Selection Can Cause Evolution
• Inclusive Fitness
– Fitness accrues to an individual when close relatives pass on copies of that individual’s alleles
Individual fitness + Fitness accrued from relative’s
reproductive success
Inclusive Fitness
– Not responsible for this concept until unit on behavioral ecology
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Evolution
•Evolution, at its smallest scale, can be defined as “intergenerational change in the genetic structure of a population”:
•Genotype frequencies
•Allele frequencies
•Population-level, small-scale evolutionary change is called “microevolution”
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0
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0 100 200 300 400 500 600 700 800 900 1000 1100
Distance (m)
Fru
it S
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VA
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Pollination and Gene Flow
Dr. Laura Galloway’s grad student, Linda Johnson is studying whether or not the origin of the plants affected the distances that birds carried the pollen and fertilized “target” flowers.
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Founder Effect Thought experiment: If 10 finches (all same species) from Isabella founded a population on Marchena, would you expect allele and genotype frequencies to be the same on Isabella as on Marchena?
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How Populations Evolve
Chapter Headings
Genetic variation within populations
The Hardy-Weinberg Equilibrium
Microevolution: changes in the genetic structure of populations
Natural selection produces variable results
Studying microevolution
Maintaining genetic variation
How do genotypes determine phenotypes
Constraints on Evolutlion
Short-term versus long-term evolution
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outline
•Important concepts and terms
adaptation, evolution, gene flow, population, deme, genotypes, phenotypes
•Virtually all populations show genetic variation
how to measure (quantify) genetic variation
The genetic composition (allele frequencies) of a population may remain relatively constant over time, ie, allele frequencies are in equilibrium;
This can be modeled mathematically and is referred to as Hardy-Weinberg equilibirim
Hardy-Weinberg model is useful…
The genetic composition of a population may change over time (intergenerationally); this is evolution, more specifically, microevolution
The agents of evolutionary change are natural selection, mutation, drift, migration, non-random mating
The effect of natural selection on frequency distribution of phenotypes (and genotypes) varies depending on the nature of the selection in operation
selection operating against individuals at both ends of the frequency distribution may operate to stabilize frequency distributions and reduce variation
selection may operate to shift the frequency distribution