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Evolutionary Change in Populations. A population’s gene pool Includes all the alleles for all the loci present in the population Diploid organisms have a maximum of two different alleles at each genetic locus
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A population’s gene pool • Includes all the alleles for all the loci present in the population • Diploid organisms have a maximum of two different alleles at each genetic locus • Typically, a single individual therefore has only a small fraction of the alleles present
Evolution of populations is best understood in terms of frequencies: • Genotype • Phenotype • Allele
Genotype frequencies for all 1000 individuals of a hypothetical population
Phenotype frequencies for all 1000 individuals of a hypothetical population
Allele frequencies for all 1000 individuals of a hypothetical population
Hardy-Weinberg Principle • Explains stability of successive generations in populations at genetic equilibrium • Essential to understanding mechanisms of evolutionary change
Genetic equilibrium requires • Random mating • No net mutations • Large population size • No migration • No natural selection
Hardy-Weinberg principle • Shows that if population is large, process of inheritance alone does not cause changes in allele frequencies • Explains why dominant alleles are not necessarily more common than recessive alleles
Hardy-Weinberg equation • p = frequency of dominant allele • q = frequency of the recessive allele:p + q = 1
The genotype frequencies of a population are described by the relationship p2 + 2pq+ q2 = 1 • p2 is frequency of homozygous dominant genotype • 2pq is frequency of heterozygous genotype • q2 is frequency of homozygous recessive genotype
Microevolution • Intergenerational changes in allele or genotype frequencies within a population • Often involves relatively small or minor changes, usually over a few generations
Changes in allele frequencies of a population caused by microevolutionary processes: • Nonrandom mating • Mutation • Genetic drift • Gene flow • Natural selection
Nonrandom mating • Inbreeding • Inbreeding depression • Assortative mating • Both of these increase frequency of homozygous genotypes
Mutation • Source of new alleles • Increases genetic variability acted on by natural selection
Genetic drift • Random change in allele frequencies of a small population • Decreases genetic variation within a population • Changes it causes are usually not adaptive
Genetic drift • Bottleneck is a sudden decrease in population size caused by adverse environmental factors • Founder effect is genetic drift occurring when a small population colonizes a new area
Gene flow • Movement of alleles caused by migration of individuals between populations • Causes changes in allele frequencies
Natural selection • Causes changes in allele frequencies leading to adaptation • Operates on an organism’s phenotype • Changes genetic composition of a population favorably for a particular environment
Modes of selection • Stabilizing • Favors the mean • Directional • Favors one phenotypic extreme • Disruptive • Favors two or more phenotypic extremes
Modes of selection (a) No selection (b) Stabilizing selection
Modes of selection (c) Directional selection (d) Disruptive selection
Genetic variation in populations caused by • Mutation • Sexual reproduction • Allows new phenotypes
Methods of evaluating genetic variation • Genetic polymorphism • Balanced polymorphism • Neutral variation • Geographic variation
Balanced polymorphism: two or more alleles persist in a population over many generations • Heterozygote advantage • Frequency-dependent selection