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Microevolution

This chapter delves into microevolution, focusing on how allele frequencies change within a population over generations. Nonrandom mating, mutations, genetic drift, gene flow, and natural selection are examined as key drivers of microevolution. The impacts of nonrandom mating such as inbreeding and assortative mating are discussed, along with the effects of mutations on genetic variation. Genetic drift, bottleneck events, founder effects, gene flow, and various types of natural selection are explained, showcasing how genetic variation arises and persists in populations. The concept of genetic polymorphism is also explored, highlighting the presence of multiple alleles in populations and their role in evolutionary processes.

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Microevolution

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  1. Microevolution Chapter 18 contined

  2. Microevolution • Generation to generation • Changes in allele frequencies within a population • Causes: • Nonrandom mating • Mutations • Genetic drift • Gene flow • Natural selection

  3. Nonrandom mating • Inbreeding • Impacts the entire genome, not just certain alleles • Individuals are more likely to mate with neighbors than distant members of the population  increases chances of genetically similar individuals mating • Common in plants (self-fertilization an extreme example) • In animals it often causes inbreeding depression, where offspring are less fit

  4. Nonrandom mating con’t… • Assortative mating • Mates are chosen based on a particular phenotype • Only impacts the genes involved in the selected phenotype • Positive  select mate with the same phenotype • Negative  select mate with the opposite phenotype

  5. Mutations • Changes in: • Nucleotide base pairs • Arrangement of genes on a chromosome • Chromosome structure • Only mutations in gametes are inherited • Most mutations are silent: • Only a small % of the DNA is expressed • Mutations that are expressed are usually harmful • Mutations do NOT cause evolution, but natural selection needs the variations mutations create

  6. Genetic Drift • It is ‘easier’ to lose a rare allele in a small population due to chance • This may produce random evolutionary changes • It can decrease genetic variation within a population • It can also increase genetic variation between different populations

  7. Genetic Drift con’t… • Bottleneck • Can occur if the population decreases suddenly – causes a dramatic change in allele frequencies • Founder effect • Decreased variation in a small population that has broken off from the parent population

  8. Gene Flow • Due to migration of breeding individuals from one population to another • Isolated populations tend to be different from surrounding populations – increased gene flow changes this: • Makes the population internally more varied • Makes the population less varied from other populations

  9. Natural Selection • Occurs over time • Increases the frequency of favorable, adaptive traits • ‘weeds out’ less adapted traits • Only operates on the phenotype, not the genotype • Phenotypes are usually due to interactions of genotypes and the environment • Most polygenic phenotypes show a normal distribution – most of the population is in the middle, with fewer at either extreme • Natural selection can only ‘work’ if there is pre-existing variation within the population

  10. Types of Natural Selection: • Stabilizing Selection • Population is well-adapted to its environment • Selection is against phenotypic extremes

  11. Types of Natural Selection… • Directional Selection • Changes in the environment cause selection of a particular extreme phenotype so that one phenotype gradually replaces another

  12. Types of Natural Selection… • Disruptive Selection • Extreme changes in the environment may favor more than one phenotype

  13. Genetic Variation in Populations • Sources: • Mutation • Sexual reproduction • crossing-over • independent assortment of chromosomes • random union of gametes

  14. Genetic Polymorphism: • The presence of 2 or more alleles in a population • May not be evident if it does not produce distinct phenotypes • Balanced polymorphism • 2 or more alleles persist due to natural selection • May be due to heterozygous advantage • Sickle cell anemia is actually selected for in area where malaria exists

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