RRC ID 59465
Author Chelo IM, Afonso B, Carvalho S, Theologidis I, Goy C, Pino-Querido A, Proulx SR, Teotónio H.
Title Partial Selfing Can Reduce Genetic Loads While Maintaining Diversity During Experimental Evolution.
Journal G3 (Bethesda)
Abstract Partial selfing, whereby self- and cross- fertilization occur in populations at intermediate frequencies, is generally thought to be evolutionarily unstable. Yet, it is found in natural populations. This could be explained if populations with partial selfing are able to reduce genetic loads and the possibility for inbreeding depression while keeping genetic diversity that may be important for future adaptation. To address this hypothesis, we compare the experimental evolution of Caenorhabditis elegans populations under partial selfing, exclusive selfing or predominant outcrossing, while they adapt to osmotically challenging conditions. We find that the ancestral genetic load, as measured by the risk of extinction upon inbreeding by selfing, is maintained as long as outcrossing is the main reproductive mode, but becomes reduced otherwise. Analysis of genome-wide single-nucleotide polymorphisms (SNPs) during experimental evolution and among the inbred lines that survived enforced inbreeding indicates that populations with predominant outcrossing or partial selfing maintained more genetic diversity than expected with neutrality or purifying selection. We discuss the conditions under which this could be explained by the presence of recessive deleterious alleles and/or overdominant loci. Taken together, our observations suggest that populations evolving under partial selfing can gain some of the benefits of eliminating unlinked deleterious recessive alleles and also the benefits of maintaining genetic diversity at partially dominant or overdominant loci that become associated due to variance of inbreeding levels.
Volume 9(9)
Pages 2811-2821
Published 2019-9-4
DOI 10.1534/g3.119.400239
PII g3.119.400239
PMID 31278175
PMC PMC6723137
MeSH Animals Caenorhabditis elegans / genetics* Evolution, Molecular Female Genetic Load* Genetic Variation* Inbreeding* Inbreeding Depression Linkage Disequilibrium Male Polymorphism, Single Nucleotide Self-Fertilization
IF 2.63
Times Cited 1
C.elegans tm3055