TY - JOUR
T1 - Evolution of sociality in spiders leads to depleted genomic diversity at both population and species levels
AU - Settepani, V.
AU - Schou, M. F.
AU - Greve, M.
AU - Grinsted, L.
AU - Bechsgaard, J.
AU - Bilde, T.
PY - 2017/8/1
Y1 - 2017/8/1
N2 - Across several animal taxa, the evolution of sociality involves a suite of characteristics, a “social syndrome,” that includes cooperative breeding, reproductive skew, primary female-biased sex ratio, and the transition from outcrossing to inbreeding mating system, factors that are expected to reduce effective population size (Ne). This social syndrome may be favoured by short-term benefits but come with long-term costs, because the reduction in Ne amplifies loss of genetic diversity by genetic drift, ultimately restricting the potential of populations to respond to environmental change. To investigate the consequences of this social life form on genetic diversity, we used a comparative RAD-sequencing approach to estimate genomewide diversity in spider species that differ in level of sociality, reproductive skew and mating system. We analysed multiple populations of three independent sister-species pairs of social inbreeding and subsocial outcrossing Stegodyphus spiders, and a subsocial outgroup. Heterozygosity and within-population diversity were sixfold to 10-fold lower in social compared to subsocial species, and demographic modelling revealed a tenfold reduction in Ne of social populations. Species-wide genetic diversity depends on population divergence and the viability of genetic lineages. Population genomic patterns were consistent with high lineage turnover, which homogenizes the genetic structure that builds up between inbreeding populations, ultimately depleting genetic diversity at the species level. Indeed, species-wide genetic diversity of social species was 5–8 times lower than that of subsocial species. The repeated evolution of species with this social syndrome is associated with severe loss of genomewide diversity, likely to limit their evolutionary potential.
AB - Across several animal taxa, the evolution of sociality involves a suite of characteristics, a “social syndrome,” that includes cooperative breeding, reproductive skew, primary female-biased sex ratio, and the transition from outcrossing to inbreeding mating system, factors that are expected to reduce effective population size (Ne). This social syndrome may be favoured by short-term benefits but come with long-term costs, because the reduction in Ne amplifies loss of genetic diversity by genetic drift, ultimately restricting the potential of populations to respond to environmental change. To investigate the consequences of this social life form on genetic diversity, we used a comparative RAD-sequencing approach to estimate genomewide diversity in spider species that differ in level of sociality, reproductive skew and mating system. We analysed multiple populations of three independent sister-species pairs of social inbreeding and subsocial outcrossing Stegodyphus spiders, and a subsocial outgroup. Heterozygosity and within-population diversity were sixfold to 10-fold lower in social compared to subsocial species, and demographic modelling revealed a tenfold reduction in Ne of social populations. Species-wide genetic diversity depends on population divergence and the viability of genetic lineages. Population genomic patterns were consistent with high lineage turnover, which homogenizes the genetic structure that builds up between inbreeding populations, ultimately depleting genetic diversity at the species level. Indeed, species-wide genetic diversity of social species was 5–8 times lower than that of subsocial species. The repeated evolution of species with this social syndrome is associated with severe loss of genomewide diversity, likely to limit their evolutionary potential.
KW - demographic modelling
KW - evolutionary dead end
KW - genetic diversity
KW - inbreeding
KW - RAD sequencing
KW - Stegodyphus
UR - http://www.scopus.com/inward/record.url?scp=85021338126&partnerID=8YFLogxK
UR - https://pure.royalholloway.ac.uk/portal/en/publications/evolution-of-sociality-in-spiders-leads-to-depleted-genomic-diversity-at-both-population-and-species-level(fe1afbd0-4118-46d2-b03f-3054f9ecb13d).html
U2 - 10.1111/mec.14196
DO - 10.1111/mec.14196
M3 - Article
C2 - 28570031
AN - SCOPUS:85021338126
SN - 0962-1083
VL - 26
SP - 4197
EP - 4210
JO - Molecular Ecology
JF - Molecular Ecology
IS - 16
ER -