Abstract
Newly formed selfing lineages may express recessive genetic load and suffer inbreeding depression. This can have a genome-wide
genetic basis, or be due to loci linked to genes under balancing selection. Understanding the genetic architecture of inbreeding
depression is important in the context of the maintenance of self-incompatibility and understanding the evolutionary dynamics
of S-alleles. We addressed this using North-American subspecies of Arabidopsis lyrata. This species is normally self-incompatible
and outcrossing, but some populations have undergone a transition to selfing. The goals of this study were to: (1) quantify the
strength of inbreeding depression in North-American populations of A. lyrata; and (2) disentangle the relative contribution of
S-linked genetic load compared with overall inbreeding depression. We enforced selfing in self-incompatible plants with known
S-locus genotype by treatment with CO2, and compared the performance of selfed vs outcrossed progeny. We found significant
inbreeding depression for germination rate (d¼0.33), survival rate to 4 weeks (d¼0.45) and early growth (d¼0.07), but not for
flowering rate. For two out of four S-alleles in our design, we detected significant S-linked load reflected by an under-representation
of S-locus homozygotes in selfed progeny. The presence or absence of S-linked load could not be explained by the dominance
level of S-alleles. Instead, the random nature of the mutation process may explain differences
in the recessive deleterious load among lineages.
Original language | English |
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Pages (from-to) | 19 - 28 |
Number of pages | 10 |
Journal | Heredity |
Volume | 110 |
DOIs | |
Publication status | First published - 15 Aug 2012 |
Keywords
- Balancing selection
- Inbreeding depression
- Mating system evolution
- Mutational load
- Self-incompatibility