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The Evolution of Populations

The Evolution of Populations. Chapter 11. Genetic Variation in Populations. Microevolution - the observable change in the allele frequencies of a population over time. Occurs on a small scale In populations there are a wide range of phenotypes

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The Evolution of Populations

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  1. The Evolution of Populations Chapter 11

  2. Genetic Variation in Populations • Microevolution - the observable change in the allele frequencies of a population over time. • Occurs on a small scale • In populations there are a wide range of phenotypes • Ex: short/fat penguins and taller/slim penguins

  3. Genetic Variation in Populations • In order to have a wide range of phenotypes, there must be genetic variation • The greater the variation in phenotypes, the more likely it is that at least some individuals can survive in a changing environment

  4. Genetic Variation in Populations • For example, a short/fat penguin might be better able to stay warm in an especially cold winter. A tall/slim penguin might be able to dive better, thus catching more fish in a period of food shortage

  5. Genetic Variation in Populations • Gene pool - All of the alleles of every individual in a population

  6. Genetic Variation in Populations • The allele frequency is a measure of how common a certain allele was in the population

  7. Genetic Variation in Populations • To calculate allele frequency for “b”: • 7 b • 7 B • Total alleles = 14 • 7b/14 TOTAL = 50%

  8. Mutations A random change in DNA Can form a new allele Mutations that occur in sex cells can be passed on to offspring Recombination Occurs during meiosis Parents’ alleles can be arranged in new ways during crossing over Genetic Variation - 2 Main Sources

  9. How do we analyze genetic variation in a population? • With graphs!

  10. Natural Selection in Populations • “mean” = average • “distribution” = range of data; a set of data and their frequency of occurrence

  11. Natural Selection in Populations • Normal distribution/bell shaped curve • frequency is highest near the mean and decreases toward each extreme end of the range

  12. Natural Selection in Populations • Phenotypes in the middle of the range are most common • Ex: people of average height (5-6ft) would fall in the shaded region • Anyone shorter or taller (the extremes) would fall outside the shaded region

  13. Directional Selection • Directional selection - Favors a phenotype at one extreme of a trait’s range. • Causes a shift in the population’s phenotypic distribution • Extreme/rare phenotype becomes more common

  14. Directional Selection • Ex: Peppered moth example • After the tree trunks became dark again, the trait for white bodies was selected against because it was no longer beneficial. This caused a shift in the distribution. The mean range now included mostly black moths.

  15. Stabilizing Selection • Stabilizing Selection- The intermediate phenotype is favored and becomes most common in the population. • Distribution becomes stable in the middle range/decreases genetic variation

  16. Stabilizing Selection • Ex: Human birth weight • Babies with either a very low or very high weight at birth are more likely to experience complications than babies of average weight

  17. Disruptive Selection • Disruptive selection- Both extreme phenotypes are favored • Intermediate is selected against

  18. Disruptive Selection • Ex: The African swallowtail butterfly has traits to be either orange, black (the extremes), or tan (the intermediate) • Predators don’t eat the orange or black ones because orange and black butterflies of different species are poisonous. Thus, the extreme trait is favored.

  19. 11.3 Notes • Gene Flow… • Organisms move to new population & reproduce --> its alleles are added to new population’s gene pool and removed from original one. • Increases genetic variation receiving of population • Lack of gene flow can lead to speciation

  20. 11.3 Notes • Genetic Drift • Small populations = more affected by chance • Elimination/sudden increase of alleles in a small population = drift • Drift = loss of genetic diversity

  21. 11.3 Notes • Bottleneck Effect • Drift that occurs after an event reduces population size • Reduced population size = reduced genetic variation

  22. 11.3 Notes • The Founder Effect • Small number of individuals colonize a new area • Gene pool of new colony is usually very different (less diverse) from original population

  23. 11.3 Notes • Effects of Drift • Loss of genetic variation • Less likely to have a large amount of individuals that can survive a changing environment • Higher chance of lethal genes being passed on instead of eliminated

  24. 11.3 Notes • Sexual Selection • Males continually produce sperm, small investment, can have many mates • Females have limited number of eggs, long gestational periods, invest more time/resources • Makes females choosy about mates

  25. 11.3 Notes • Sexual Selection • Certain traits increase mating success • Intra- : competition between males • Inter- : showy males to attract mates • Some showy traits can put animals in danger, but suggest good health/fertility/ability to care/defend to potential mates. GOOD QUALITY.

  26. 1/26/12 Bell Ringer! • What kind of sexual selection is feautured in this video? What traits might the beetle have to make him successful? • Sexual Selection of Darwin Beetles • What kind of sexual selection is featured in this video? Why are females so choosy about mates? • Sexual Selection Birds of Paradise

  27. Hardy-Weinberg Equilibrium • Describes populations that are not evolving • “Equilibrium” - Genotype frequencies in a population stay the SAME over time as long as 5 conditions are met.

  28. 5 Conditions • Very large population - no drift • No emigration/immigration - no gene flow • No mutations - no new alleles can be added to gene pool • Random mating - no sexual selection • No natural selection - all traits aid in survival equally

  29. Hardy-Weinberg Equilibrium • Equilibrium is only met if ALL 5 conditions are met!!!! • Real populations rarely meet all 5

  30. Why study Hardy-Weinberg? • Biologists can compare real data to data predicted by the model. • Can learn more about the ways populations evolve and about how to test factors that can lead to evolution.

  31. Review on what leads to evolution • Genetic drift • Gene flow • Mutation • Sexual selection • Natural selection

  32. Speciation Through Isolation • Speciation - the rise of two or more new species from a previously existing species • Isolated populations - when gene flow stops • Isolated populations adapt to their environments differently, which can lead to differences in the gene pools

  33. Speciation Through Isolation • Reproductive isolation - members of different populations can not mate successfully • Reproductive organs not compatible • Producing barren offspring • Final step of speciation

  34. What causes isolation? • Behavioral isolation - differences in courtship or mating behaviors • Bird dances • Frog songs • Firefly flash patterns

  35. What causes isolation? • Geographic isolation - Physical barriers that can separate populations • Mountain ranges • Rivers • Valleys

  36. What causes isolation? • Geographic • Isthmus of Panama separated a large population of wrasse fish • Gene pools changed over time • Now 2 separate species

  37. What causes isolation? • Temporal isolation - mating seasons do not line up • High competition for mates at one time

  38. Evolution Through Natural Selection is Not Random • “Chance” and “random” relate to how easily an outcome can be predicted • Genetic drift • Mutations

  39. Evolution Through Natural Selection is Not Random • Natural selection is NOT random • Natural selection pushes a population’s traits in an advantageous direction • The response of species to environmental challenges is not random

  40. Patterns In Evolution • Convergent Evolution - evolution toward similar characteristics in unrelated species • Adaptations to similar environments

  41. Patterns In Evolution • Shark and dolphin tails • Separated by 300 million years of evolution

  42. Patterns In Evolution • Divergent Evolution - Closely related species evolve in different directions • Different appearances due to adapting to different environments

  43. Patterns In Evolution • Red fox and Kit fox • Red coat, temperate region vs. Sandy coat/big ears, desert regions

  44. Patterns In Evolution • Species interactions can lead to connected evolutionary pathways • Coevolution - process in which two or more species evolve in response to changes in each other

  45. Patterns In Evolution • Acacia plant and stinging ant • Ant protects plant from predators and plant provides nectar for the ant

  46. Patterns In Evolution • “Evolutionary Arms Race” - coevolution in competitive relationships

  47. Patterns In Evolution • Garter snake and rough skinned newt • Newt produces a neurotoxin that concentrates on their skin • Garter snakes have evolved a resistance to the toxin • Driven newts to have extreme levels of toxins

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