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Evolution by genetic drift random fluctuation in allele frequencies allele loss or fixation allele frequency differences between populations.

Published byNeal Butler Modified over 9 years ago

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Presentation on theme: "Evolution by genetic drift random fluctuation in allele frequencies allele loss or fixation allele frequency differences between populations."— Presentation transcript:

1 Evolution by genetic drift random fluctuation in allele frequencies allele loss or fixation allele frequency differences between populations

2 Buri’s (1956) experimental demonstration of genetic drift Initially identical subpopulations evolve by chance to become genetically different

3 Genetic drift is more powerful in small populations

4 Drift leads to an inevitable decline in heterozygosity in finite populations over time. Again, this happens faster in small populations.

5 The northern elephant seal bottleneck large US California and Baja California populations were hunted for oil and skins by end 1800’s, ~ 20 individuals remained on Guadalupe Island off Baja California population rebounded to ~120,000 by 1980 Microunga angustirostris

6 Northern elephant seals show no allozyme variation Bonnell and Selander (1974): no variation at 24 allozyme loci Hoelzel et al. (1993): no variation at > 50 loci Severe homozygosity, despite rapid recovery

7 Did the bottleneck cause reduced genetic variation? pinnepeds show low allozyme variation, but: southern elephant seals: not hunted, no bottleneck, much greater allozyme variation northern species: unusually low variation in highly variable DNA (microsatellites and mitochondrial DNA control region) –2 different control region sequences in 40 northern seals –southern species ~ 10X more variation

8 Photograph by Max McRae The history of colonization of Tasmania and New Zealand by the silvereye, Zosterops lateralis

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