Disparate patterns of genetic divergence in three widespread corals across a pan-Pacific environmental gradient highlights species-specific adaptation trajectories

  1. Benjamin C C Hume
  2. Christian R Voolstra
  3. Eric Armstrong
  4. Guinther Mitushasi
  5. Barbara Porro
  6. Nicolas Oury
  7. Sylvain Agostini
  8. Emilie Boissin
  9. Julie Poulain
  10. Quentin Carradec
  11. David A. Paz-García
  12. Didier Zoccola
  13. Hélène Magalon
  14. Clémentine Moulin
  15. Guillaume Bourdin
  16. Guillaume Iwankow
  17. Sarah Romac
  18. Bernard Banaigs
  19. Emmanuel Boss
  20. Chris Bowler
  21. Colomban de Vargas
  22. Eric Douville
  23. Michel Flores
  24. Paola Furla
  25. Pierre E Galand
  26. Eric Gilson
  27. Fabien Lombard
  28. Stéphane Pesant
  29. Stéphanie Reynaud
  30. Matthew B. Sullivan
  31. Shinichi Sunagawa
  32. Olivier Thomas
  33. Romain Troublé
  34. Rebecca Vega Thurber
  35. Patrick Wincker
  36. Serge Planes
  37. Denis Allemand
  38. Didier Forcioli
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Abstract

Tropical coral reefs are among the worst affected ecosystems by climate change with predictions ranging between a 70-90% loss of reefs in the coming decades. Effective conservation strategies that maximize ecosystem resilience, and potential for recovery, must be informed by the accurate characterization of extant genetic diversity and population structure together with an understanding of the adaptive potential of keystone species. Here, we analyzed samples from theTaraPacific Expedition (2016 to 2018) that completed an 18,000 km longitudinal transect of the Pacific Ocean sampling three widespread corals –Pocillopora meandrina, Porites lobata, andMilleporacf.platyphylla– across 33 sites from 11 islands. Using deep metagenomic sequencing of 269 colonies in conjunction with morphological analyses and climate variability data we can show that the sampled transect encompasses multiple morphologically cryptic species that exhibit disparate biogeographic patterns, and most importantly, distinct evolutionary patterns, despite exposure to identical environmental regimes. Our findings demonstrate on a basin-scale that evolutionary trajectories are species-specific and complex, and can only in part be predicted from the environment. This highlights that conservation strategies must integrate multi-species investigations to consider the distinct genomic footprints shaped by selection as well as the genetic potential for adaptive change.

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