Breakdown of self-incompatibility due to genetic interaction between a specific S-allele and an unlinked modifier.
Yan LiEkaterina MamonovaNadja KöhlerMark van KleunenMarc StiftPublished in: Nature communications (2023)
Breakdown of self-incompatibility has frequently been attributed to loss-of-function mutations of alleles at the locus responsible for recognition of self-pollen (i.e. the S-locus). However, other potential causes have rarely been tested. Here, we show that self-compatibility of S 1 S 1 -homozygotes in selfing populations of the otherwise self-incompatible Arabidopsis lyrata is not due to S-locus mutation. Between-breeding-system cross-progeny are self-compatible if they combine S 1 from the self-compatible cross-partner with recessive S 1 from the self-incompatible cross-partner, but self-incompatible with dominant S-alleles. Because S 1 S 1 homozygotes in outcrossing populations are self-incompatible, mutation of S 1 cannot explain self-compatibility in S 1 S 1 cross-progeny. This supports the hypothesis that an S 1 -specific modifier unlinked to the S-locus causes self-compatibility by functionally disrupting S 1 . Self-compatibility in S 19 S 19 homozygotes may also be caused by an S 19 -specific modifier, but we cannot rule out a loss-of-function mutation of S 19 . Taken together, our findings indicate that breakdown of self-incompatibility is possible without disruptive mutations at the S-locus.