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Transcript
Genetic Drift, followed by selection can cause linkage disequilibrium Combination of Two Different Gene Pools Admixture Recombination Breaks Down Linkage Disequilibria The rate of decline in LD increases with r LD declines over time (rate depending on r) r= D sqrt(pqst) Concept of Linkage Law of Independent Assortment = 0.25 A Meiosis a B b = 0.25 All allele combinations in gametes equally probable = 0.25 = 0.25 Probability of recombination = 0.5 A B a b = 0.25 Meiosis = 0.25 = 0.25 = 0.25 All allele combinations in gametes equally probable Linked Loci Probability of recombination = 0.3 A a B b = 0.35 Meiosis = 0.15 = 0.15 All allele combinations in gametes NOT equally probable = 0.35 Probability of recombination = 0.1 A B a b = 0.45 Meiosis = 0.05 = 0.05 = 0.45 All allele combinations in gametes NOT equally probable Concept: The closer two loci are on a chromosome, the lower the probability of recombination. Why important? (1) Affects rate that LD is broken down. (2) Allows one to determine the linear order of genes on a chromosome (make a genome map). (3) Maps allow for the localization of genes, mutant phenotypes, and QTL in the genome. Selection at a single locus affects other loci under LD Selection has an effect on frequency of B alleles LD may retard rate of evolution If: new mutations are linked to deleterious sites or arise in the ‘wrong’ chromosomal backgrounds (255 genes examined) A comparison of substitution rates between D. simulans and D. melanogaster for synonomous and non-synonomous sites LD among 1504 marker Loci on Human Chromosome 22. (Dawson et al. 2002) Where did CCR5 D32 come from? There is strong linkage disequilibrium between CCR5 and two neutral marker loci. Probability that D32-197-215 has remained unchanged across generations: Pg = (1 - c - m)g Prob recombination Prob mutation Estimated p = 0.848, m = 0.001, c = 0.005 g = 27.5 ~ 27.5 x 25 = 688 yrs How does LD help identify genes that may be under positive natural selection? For neutral alleles: Genetic drift is the primary evolutionary mechanism. So: If LD is detectable, indicates that an allele is young. Expect magnitude of LD is proportional to the age of an allele. If LD is not detectable, indicates that an allele is old. Expect old and frequent alleles, or old and rare alleles, But do not expect young, high frequency alleles. Indicates alleles at the locus may be under selection. G6PD polymorphism and deficiency Countries with malaria have highest frequency of a reduced-activity allele. LD is higher for the G6PD-202A allele; suggests positive selection Probability that 2 randomly chosen “a” chromosomes have the same snps across a physical distance
