TY - JOUR T1 - Limits to adaptation in partially selfing species JF - bioRxiv DO - 10.1101/026146 SP - 026146 AU - Matthew Hartfield AU - Sylvain Glémin Y1 - 2016/01/01 UR - http://biorxiv.org/content/early/2016/03/02/026146.abstract N2 - In outcrossing populations, “Haldane’s Sieve” states that recessive beneficial alleles are less likely to fix than dominant ones, because they are less expose to selection when rare. In contrast, selfing organisms are not subject to Haldane’s Sieve and are more likely to fix recessive types than outcrossers, as selfing rapidly creates homozygotes, increasing overall selection acting on mutations. However, longer homozygous tracts in selfers also reduce the ability of recombination to create new genotypes. It is unclear how these two effects influence overall adaptation rates in partially selfing organisms. Here, we calculate the fixation probability of beneficial alleles if there is an existing selective sweep in the population. We consider both the potential loss of the second beneficial mutation if it has a weaker advantage than the first, and the possible replacement of the initial allele if the second mutant is fitter. Overall, loss of weaker adaptive alleles during a first selective sweep has a larger impact on preventing fixation of both mutations in highly selfing organisms. Furthermore, the presence of linked mutations has two opposing effects on Haldane’s Sieve. First, recessive mutants are disproportionally likely to be lost in outcrossers, so it is likelier that dominant mutations will fix. Second, with elevated rates of adaptive mutation, selective interference annuls the advantage in selfing organisms of not suffering from Haldane’s Sieve; outcrossing organisms are more able to fix weak beneficial mutations of any dominance value. Overall, the weakened effect of recombination can greatly limit adaptation in selfing organisms.Website for simulation code: http://github.com/MattHartfield/TwoAdvSelfSims ER -