Allelic genealogies in sporophytic self-incompatibility systems in plants

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Abstract

Expectations for the time scale and structure of allelic genealogies in finite populations are formed under three models of sporophytic self- incompatibility. The models differ in the dominance interactions among the alleles that determine the self-incompatibility phenotype: In the SSIcod model, alleles act codominantly in both pollen and style, in the SSIdom model, alleles form a dominance hierarchy, and in SSIdomcod, alleles are codominant in the style and show a dominance hierarchy in the pollen. Coalescence times of alleles rarely differ more than threefold from those under gametophytic self-incompatibility, and transspecific polymorphism is therefore expected to be equally common. The previously reported directional turnover process of alleles in the SSIdomcod model results in coalescence times lower and substitution rates higher than those in the other models. The SSIdom model assumes strong asymmetries in allelic action, and the most recessive extant allele is likely to be the most recent common ancestor. Despite these asymmetries, the expected shape of the allele genealogies does not deviate markedly from the shape of a neutral gene genealogy. The application of the results to sequence surveys of alleles, including interspecific comparisons, is discussed.

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Schierup, M. H., Vekemans, X., & Christiansen, F. B. (1998). Allelic genealogies in sporophytic self-incompatibility systems in plants. Genetics, 150(3), 1187–1198. https://doi.org/10.1093/genetics/150.3.1187

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