PLoS Genetics (Feb 2024)

High germline mutation rates, but not extreme population outbreaks, influence genetic diversity in a keystone coral predator.

  • Iva Popovic,
  • Lucie A Bergeron,
  • Yves-Marie Bozec,
  • Ann-Marie Waldvogel,
  • Samantha M Howitt,
  • Katarina Damjanovic,
  • Frances Patel,
  • Maria G Cabrera,
  • Gert Wörheide,
  • Sven Uthicke,
  • Cynthia Riginos

DOI
https://doi.org/10.1371/journal.pgen.1011129
Journal volume & issue
Vol. 20, no. 2
p. e1011129

Abstract

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Lewontin's paradox, the observation that levels of genetic diversity (π) do not scale linearly with census population size (Nc) variation, is an evolutionary conundrum. The most extreme mismatches between π and Nc are found for highly abundant marine invertebrates. Yet, the influences of new mutations on π relative to extrinsic processes such as Nc fluctuations are unknown. Here, we provide the first germline mutation rate (μ) estimate for a marine invertebrate in corallivorous crown-of-thorns sea stars (Acanthaster cf. solaris). We use high-coverage whole-genome sequencing of 14 parent-offspring trios alongside empirical estimates of Nc in Australia's Great Barrier Reef to jointly examine the determinants of π in populations undergoing extreme Nc fluctuations. The A. cf. solaris mean μ was 9.13 x 10-09 mutations per-site per-generation (95% CI: 6.51 x 10-09 to 1.18 x 10-08), exceeding estimates for other invertebrates and showing greater concordance with vertebrate mutation rates. Lower-than-expected Ne (~70,000-180,000) and low Ne/Nc values (0.0047-0.048) indicated weak influences of population outbreaks on long-term π. Our findings are consistent with elevated μ evolving in response to reduced Ne and generation time length, with important implications for explaining high mutational loads and the determinants of genetic diversity in marine invertebrate taxa.