Matings between close relatives often reduce the fitness of offspring, probably because homozygosity leads to the expression of recessive deleterious alleles. Studies of several animals have shown that reproductive success is lower when genetic similarity between parents is high, and that survival and other measures of fitness increase with individual levels of genetic diversity. These studies indicate that natural selection may favour the avoidance of matings with genetically similar individuals. But constraints on social mate choice, such as a lack of alternatives, can lead to pairing with genetically similar mates. In such cases, it has been suggested that females may seek extra-pair copulations with less related males, but the evidence is weak or lacking. Here we report a strong positive relationship between the genetic similarity of social pair members and the occurrence of extra-pair paternity and maternity ('quasi-parasitism') in three species of shorebirds. We propose that extra-pair parentage may represent adaptive behavioural strategies to avoid the negative effects of pairing with a genetically similar mate.
Telomeres are dynamic DNA-protein structures that form protective caps at the ends of eukaryotic chromosomes. Although initial telomere length is partly genetically determined, subsequent accelerated telomere shortening has been linked to elevated levels of oxidative stress. Recent studies show that short telomere length alone is insufficient to induce cellular senescence; advanced attrition of these repetitive DNA sequences does, however, reflect ageing processes. Furthermore, telomeres vary widely in length between individuals of the same age, suggesting that individuals differ in their exposure or response to telomere-shortening stress factors. Here, we show that residual telomere length predicts fitness components in two phylogenetically distant bird species: longevity in sand martins, Riparia riparia, and lifetime reproductive success in dunlins, Calidris alpina. Our results therefore imply that individuals with longer than expected telomeres for their age are of higher quality.
BackgroundTo date, the only estimate of the heritability of telomere length in wild
populations comes from humans. Thus, there is a need for analysis of natural
populations with respect to how telomeres evolve.Methodology/Principal FindingsHere, we show that telomere length is heritable in free-ranging sand lizards,
Lacerta agilis. More importantly, heritability
estimates analysed within, and contrasted between, the sexes are markedly
different; son-sire heritability is much higher relative to daughter-dam
heritability. We assess the effect of paternal age on Telomere Length (TL)
and show that in this species, paternal age at conception is the best
predictor of TL in sons. Neither paternal age per se at
blood sampling for telomere screening, nor corresponding age in sons impact
TL in sons. Processes maintaining telomere length are also associated with
negative fitness effects, most notably by increasing the risk of cancer and
show variation across different categories of individuals (e.g. males vs.
females). We therefore tested whether TL influences offspring survival in
their first year of life. Indeed such effects were present and independent
of sex-biased offspring mortality and offspring malformations.Conclusions/SignificanceTL show differences in sex-specific heritability with implications for
differences between the sexes with respect to ongoing telomere selection.
Paternal age influences the length of telomeres in sons and longer telomeres
enhance offspring survival.
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