-Is change in the allele frequencies of a population over generations -This is evolution on its smallest scale

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1 Remember: -Evolution is a change in species over time -Heritable variations exist within a population -These variations can result in differential reproductive success -Over generations this can result in changes in the genetic composition of a population -Individuals do not evolve, populations do! Mutation and Sexual Reproduction Produce the Genetic Variation that makes Evolution Possible Microevolution Genetic Variation Sources: -Point Mutations are changes in the base gene. They can have significant impact on phenotype as in sickle cell disease -Chromosomal Mutations delete, disrupt, or rearrange many genes at once. They are almost certain to be harmful -Most of the genetic variations within a population are due to the sexual recombination of alleles that already exist in a population -Is change in the allele frequencies of a population over generations -This is evolution on its smallest scale Population Genetics -Is the study of how populations change over time -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 genes in all the members of a population

2 Fixed Alleles The Hardy-Weinberg Equation can be used to Test whether a Population is Evolving -In diploid species, each individual has two alleles for a particular gene and the individual may be either heterozygous or homozygous -If all members of a population are homozygous for the same allele, the allele is said to be fixed. Only one allele exists that at a particular locus in the population -The greater the number of fixed alleles, the lower the species diversity, the less likely it will survive environmental change -The Hardy-Weinberg theorem is used to describe a population that is not evolving -It states that the frequencies of alleles and genes in a population s gene pool will remain constant over the course of generations unless they acted upon by forces other than Mendelian segregation and the recombination of alleles -If the population is not evolving, the population is at Hardy-Weinberg equilibrium Five Conditions for Hardy-Weinberg Equilibrium Basic Hardy-Weinberg Equation -If all these conditions are met, then a population is NOT evolving 1.No mutations 2.Random Mating 3.No Natural Selection 4.The population size must be extremely large (no genetic drift) 5.No genetic flow (emigration, immigration, transfer of pollen) -However, it is unlikely that all the conditions will be met because allele frequencies change and populations evolve p+q=1 p= frequency (%) dominant allele q= frequency (%) recessive allele

3 Expanded Hardy-Weinberg Equation p + q =1 (p + q) 2 = (1) 2 P 2 +2pq +q 2 = 1 Genotypes p 2 = frequency (%) of Homozygous Dominant 2pq = frequency (%) of Heterozygous q 2 = frequency (%) of Homozygous Recessive Importance of Hardy-Weinberg -Yardstick to measure rates of evolution -Predicts that gene frequencies should NOT change over time as long as the HW assumptions hold (no evolution should occur) -Way to calculate gene frequencies through time Microevolution -Caused by violations of the 5 HW assumptions. Mainly due to natural selection, but also caused by chance events that more dramatically affect smaller populations -Mutations can alter gene frequency but are rare -The three major factors that alter allelic frequencies and bring about most evolutionary change are natural selection, genetic drift, and gene flow Natural Selection -Results in alleles being passed to the next generation in proportions different from their relative frequencies in the present generation -Individuals with variations that are better suited to their environment tend to produce more offspring then those with variations that are less suited

4 Genetic Drift -Is the unpredicted fluctuation in allele frequencies from one generation to the next -The smaller the population, the greater the chance is for genetic drift. This is random, nonadaptive change in allele frequencies. Ex.: Founder Effect and Bottleneck Effect Founder Effect -A few individuals become isolated from a large population whose gene pool is not reflective of the population Result: -Genetic variation reduce -Some alleles increase in frequency while others are lost (as compared to the parent population) Ex.: Very common in island and other groups that don t interbreed Bottleneck Effect -A sudden change in the environment (for ex. An earthquake) drastically reduces the size of a population -The few survivors that pass through the restricted bottleneck may have a gene pool that no longer reflects the original population s gene pool Ex.: The population of California condors was reduced to nine individuals. Importance of the Bottleneck Effect Result: -Some alleles lost -Other alleles are over represented -Genetic variation usually lost Importance: -Reduction of population size may reduce gene pool for evolution to work with Ex.Cheetahs

5 Gene Flow -Occurs when a population gains or losses alleles by genetic additions to and/or subtractions from the populations Ex.: Immigration and Emigration -This results from the movement of fertile individuals or gametes between populations -Gene flow tends to reduce the genetic differences between populations, thus making populations more similar Natural Selection is the only Mechanism that Consistently causes Adaptive Evolution Directional Selection -Relative fitness refers to the contribution an organism makes to the gene pool of the next generation relative to the contributions of other members -Fitness does not indicate strength or size. It is only measured by reproductive success -Natural selection acts more directly on the phenotype and indirectly on the genotype and can alter the frequency and distribution of heritable traits in three ways: Directional Selection, Disruptive Selection, & Stabilizing Selection -Individuals with one extreme of a phenotypic range are favored, shifting the curve toward this extreme Ex.: Large black bears survived periods of extreme cold better than smaller ones, and so became more common during the glacial periods Disruptive Selection -Occurs when conditions favor both extremes of a phenotypic range rather than individuals with intermediate phenotypes Ex.: A population has individuals with either small beaks or large becks, but few with the intermediate beak size. Apparently the intermediated beak size is not efficient in cracking either the large or small seeds that are common

6 Stabilizing Selection -Acts against both phenotypes and favors intermediated variations Ex.: Birth weights of most humans lie in a narrow range, as those babies who are very large or very small have higher mortality How is Genetic Variation Preserved in a Population? Diploidy: Because most eukaryotes are diploid, they are capable of hiding genetic variation (recessive alleles) Heterozygous Advantage: Individuals who are heterozygous at a certain locus have an advantage for survival Heterozygous Advantage Example -In sickle-cell disease, individuals homozygous for normal hemoglobin (HH) are susceptible to malaria, whereas homozygous recessive individuals (hh) suffer from the complications of sickle-cell disease -Heterzygous (Hh) benfit from protection from malaria and do not have sickle-cell disease, so the mutant allele remains relatively common Why Natural Selection Cannot Produce Perfect Organisms: -Selection can only edit existing variations -Evolution is limited by historical constraints -Adaptations are often compromises -Chance, natural selection, and the environment interact