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Transcript
Sweet genes: Do we shape the gene pool of our forests ? Thomas Geburek Department of Forest Genetics Trees are extremely long-lived individuals on our globe! bristlecone pine (Pinus aristata) up to 4600 years ... and have often a huge natural distribution area ! Scots pine (Pinus sylvestris) Nystedt et al. 2013 (Nature, 497, 579-584) 28,354 genes identified in Picea abies „maternal“ chromosome allele „paternal“ chromosome allele homozygous gene(locus) „maternal“ chromosome allele „paternal“ chromosome allele heterozygous gene(locus) Diversifying Factors Selection Homogeneizing Factor Gene Pool Gene Flow Six times elevated mutation rate in wheat exposed for one year to Chernobly radiation. Selection Selection Response to selection (selective gain) = intensity of selection x heritability (narrow sense) R = s x h2 Gene Flow Gene Flow Blowing in the wind ..... Gene flow Genetic Drift lime 24 raspberry 60 orange 1 cherry 10 pineapple 5 Gene pool 100 „sweet genes“ 1. Step random mating 2. Step allelic richness and heterozygosity 3. Step run population through a bottleneck (pick blindly 6 individuals) 4. Step allelic richness and heterozygosity Genetic Drift Heterozygosity after the bottleneck of size N Hafter= [1- 1/(2N)] Hbefore H [%] 75 NIND 2 91.7 95 97.5 99 99.5 6 10 20 50 100 allelic richness after the bottleneck probability of loosing alleles N p1 = 0.60 p2 = 0.24 p3 = 0.10 p4 = 0.05 p5= 0.01 1 1.00 2 2.21 6 3.26 10 3.70 50 4.62 unlimited 5.00 E = m - (1-p)2N allelic richness before the bottleneck Hampe & Petit (2005) Ecological Letters How do we affect the gene pool of forest trees? Identify major points and discuss the issue together with your group members, prepare a 5-minute summary! Thomas Geburek Department of Forest Genetics [email protected]
