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How the genetic composition of a population changes through stochastic processes, such as genetic drift, in combination with deterministic processes, such as selection, is critical to understanding how phenotypes vary in space and time. Here, we show how evolutionary forces affecting selection, including recombination and effective population size, drive genomic patterns of allele-specific expression (ASE). Integrating tissue-specific genotypic and transcriptomic data from 1500 individuals from two different cohorts, we demonstrate that ASE is less often observed in regions of low recombination, and loci in high or normal recombination regions are more efficient at using ASE to underexpress harmful mutations. By tracking genetic ancestry, we discriminate between ASE variability due to past demographic effects, including subsequent bottlenecks, versus local environment. We observe that ASE is not randomly distributed along the genome and that population parameters influencing the efficacy of natural selection alter ASE levels genome wide.

Original publication

DOI

10.1126/sciadv.abl3819

Type

Journal article

Journal

Science advances

Publication Date

05/2022

Volume

8

Addresses

Ontario Institute for Cancer Research, Toronto, ON, Canada.

Keywords

Humans, Recombination, Genetic, Genetic Drift, Alleles, Genetic Variation, Selection, Genetic