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Small-scale genetic structure of coral populations in Palau based on whole mitochondrial genomes: Implications for future coral resilience.
Palumbi, Stephen R; Walker, Nia S; Hanson, Erik; Armstrong, Katrina; Lippert, Marilla; Cornwell, Brendan; Nestor, Victor; Golbuu, Yimnang.
Afiliação
  • Palumbi SR; Department of Biology and Oceans Department Hopkins Marine Station of Stanford University Pacific Grove California USA.
  • Walker NS; Department of Biology and Oceans Department Hopkins Marine Station of Stanford University Pacific Grove California USA.
  • Hanson E; Hawaii Institute of Marine Biology, University of Hawaii Honolulu Hawaii USA.
  • Armstrong K; Department of Biology and Oceans Department Hopkins Marine Station of Stanford University Pacific Grove California USA.
  • Lippert M; Department of Biology and Oceans Department Hopkins Marine Station of Stanford University Pacific Grove California USA.
  • Cornwell B; Department of Biology and Oceans Department Hopkins Marine Station of Stanford University Pacific Grove California USA.
  • Nestor V; Department of Biology and Oceans Department Hopkins Marine Station of Stanford University Pacific Grove California USA.
  • Golbuu Y; Palau International Coral Reef Center Koror Palau.
Evol Appl ; 16(2): 518-529, 2023 Feb.
Article em En | MEDLINE | ID: mdl-36793699
ABSTRACT
The ability of local populations to adapt to future climate conditions is facilitated by a balance between short range dispersal allowing local buildup of adaptively beneficial alleles, and longer dispersal moving these alleles throughout the species range. Reef building corals have relatively low dispersal larvae, but most population genetic studies show differentiation only over 100s of km. Here, we report full mitochondrial genome sequences from 284 tabletop corals (Acropora hyacinthus) from 39 patch reefs in Palau, and show two signals of genetic structure across reef scales from 1 to 55 km. First, divergent mitochondrial DNA haplotypes exist in different proportions from reef to reef, causing PhiST values of 0.02 (p = 0.02). Second, closely related sequences of mitochondrial Haplogroups are more likely to be co-located on the same reefs than expected by chance alone. We also compared these sequences to prior data on 155 colonies from American Samoa. In these comparisons, many Haplogroups in Palau were disproportionately represented or absent in American Samoa, and inter-regional PhiST = 0.259. However, we saw three instances of identical mitochondrial genomes between locations. Together, these data sets suggest two features of coral dispersal revealed by occurrence patterns in highly similar mitochondrial genomes. First, the Palau-American Samoa data suggest that long distance dispersal in corals is rare, as expected, but that it is common enough to deliver identical mitochondrial genomes across the Pacific. Second, higher than expected co-occurrence of Haplogroups on the same Palau reefs suggests greater retention of coral larvae on local reefs than predicted by many current oceanographic models of larval movement. Increased attention to local scales of coral genetic structure, dispersal, and selection may help increase the accuracy of models of future adaptation of corals and of assisted migration as a reef resilience intervention.
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Texto completo: 1 Base de dados: MEDLINE Tipo de estudo: Prognostic_studies Idioma: En Ano de publicação: 2023 Tipo de documento: Article

Texto completo: 1 Base de dados: MEDLINE Tipo de estudo: Prognostic_studies Idioma: En Ano de publicação: 2023 Tipo de documento: Article