Asymmetric dispersal is a critical element of concordance between biophysical dispersal models and spatial genetic structure in Great Barrier Reef corals

Riginos, Cynthia; Hock, Karlo; Matias, Ambrocio Melvin A.; Mumby, Peter J.; Oppen, Madeleine J. H. van; Lukoschek, Vimoksalehi

doi:10.1111/ddi.12969

Cited by 32 publications

(30 citation statements)

References 77 publications

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“…Across all of these models migration coefficients were larger for the southward direction. Although this is against the predominant direction of inshore current flow 48 and predicted movement from biophysical models 49 it is in accordance with studies that have shown southward migration to be the predominant direction of gene flow for A. tenuis and A. millepora on the GBR 9,49 including for inshore populations. This disconnect between biophysical modelling (which reflects northward inshore currents) and southward gene flow could reflect differences in effective population size.…”

Section: Demographic Historysupporting

confidence: 89%

Signatures of selection in the coral holobiont reveal complex adaptations to inshore environments driven by Holocene climate change

Cooke

Ying

Fôret

et al. 2020

Preprint

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The inshore region of the Great Barrier Reef (GBR) became inundated at the start of the Holocene when sea levels rose. Like many inshore reefs worldwide it harbours extensive coral assemblages despite being subject to relatively high turbidity, freshwater input and thermal fluctuations. To investigate how the coral holobiont has adapted to these conditions we used shallow whole genome resequencing of 148 Acropora tenuis colonies from five inshore locations to model demographic history, identify signatures of selection and profile symbiont communities. We also assembled the genome of Acropora tenuis from long-read sequencing, providing one of the most contiguous and complete coral genomes to date. We show that corals from Magnetic Island are genetically distinct from reefs further north reflecting a Pleistocene (250-600Kya) split, whereas photosymbiont genotypes differed between reefs in a pattern more likely to reflect contemporary (Holocene) conditions. We also identified loci in the coral host genome with signatures of positive selection in the northern population and demonstrate using coalescent simulations that these are unlikely to be accounted for by demographic history. Associated with these we find genes with roles in a complex range of processes including heterotrophy, osmotic regulation, skeletal development and establishment and maintenance of symbiosis. Our results show that A. tenuis holobionts from the inshore GBR have been significantly shaped by their environment and provide an example of complex adaptations in response to past climate change.

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Section: Demographic Historysupporting

confidence: 89%

Signatures of selection in the coral holobiont reveal complex adaptations to inshore environments driven by Holocene climate change

Cooke

Ying

Fôret

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

“…Across all of these models, migration coefficients were larger for the southward direction. Although this is against the predominant direction of inshore current flow (35) and predictions based on biophysical modeling (36), it is consistent with studies that have shown southward migration to be the predominant direction of gene flow for A. tenuis and A. millepora on the GBR (6,36) including for inshore populations. This disconnect between biophysical modeling (which reflects prevailing, but variable, northward inshore currents) and apparent gene flow could reflect differences in effective population size.…”

Section: And Table S2supporting

confidence: 89%

Genomic signatures in the coral holobiont reveal host adaptations driven by Holocene climate change and reef specific symbionts

et al. 2020

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Genetic signatures caused by demographic and adaptive processes during past climatic shifts can inform predictions of species’ responses to anthropogenic climate change. To identify these signatures in Acropora tenuis, a reef-building coral threatened by global warming, we first assembled the genome from long reads and then used shallow whole-genome resequencing of 150 colonies from the central inshore Great Barrier Reef to inform population genomic analyses. We identify population structure in the host that reflects a Pleistocene split, whereas photosymbiont differences between reefs most likely reflect contemporary (Holocene) conditions. Signatures of selection in the host were associated with genes linked to diverse processes including osmotic regulation, skeletal development, and the establishment and maintenance of symbiosis. Our results suggest that adaptation to post-glacial climate change in A. tenuis has involved selection on many genes, while differences in symbiont specificity between reefs appear to be unrelated to host population structure.

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“…Over the last four decades, we have assembled extensive knowledge on the genetic characterization of marine organisms, mainly concerning the spatial distribution and structuring of populations (e.g., Knutsen et al, 2007;Plank et al, 2010;Robalo et al, 2013;Riginos et al, 2019;Verry et al, 2020). With this information, it is now possible and relevant to understand how these patterns behave through time.…”

Section: Introductionmentioning

confidence: 99%

Time matters: genetic composition and evaluation of effective population size in temperate coastal fish species

Francisco

Robalo

2020

PeerJ

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Background Extensive knowledge on the genetic characterization of marine organisms has been assembled, mainly concerning the spatial distribution and structuring of populations. Temporal monitoring assesses not only the stability in genetic composition but also its trajectory over time, providing critical information for the accurate forecast of changes in genetic diversity of marine populations, particularly important for both fisheries and endangered species management. We assessed fluctuations in genetic composition among different sampling periods in the western Portuguese shore in three fish species. Methods White seabream Diplodus sargus, sand smelt Atherina presbyter and shanny Lipophrys pholis were chosen, because of their genetic patterns in distinct ecological environments, insight into historical and contemporary factors influencing population effective size (Ne), and degree of commercial exploitation. Samples were obtained near Lisbon between 2003 and 2014 and screened for genetic variation with mitochondrial and nuclear markers. Analyses included genealogies, genetic diversities, temporal structures and contemporary Ne. Results For mtDNA no temporal structure was detected, while for nDNA significant differences were recorded between some sampling periods for the shanny and the sand smelt. Haplotype networks revealed deep genealogies, with various levels of diversification. The shanny revealed a smaller Ne/generation when compared to the other species, which, in turn, revealed no evidence of genetic drift for most study periods. These results highlight the fact that temporal variations in genetic pool composition should be considered when evaluating the population structure of fish species with long distance dispersal, which are more vulnerable to recruitment fluctuations.

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Asymmetric dispersal is a critical element of concordance between biophysical dispersal models and spatial genetic structure in Great Barrier Reef corals

Cited by 32 publications

References 77 publications

Signatures of selection in the coral holobiont reveal complex adaptations to inshore environments driven by Holocene climate change

Signatures of selection in the coral holobiont reveal complex adaptations to inshore environments driven by Holocene climate change

Genomic signatures in the coral holobiont reveal host adaptations driven by Holocene climate change and reef specific symbionts

Time matters: genetic composition and evaluation of effective population size in temperate coastal fish species

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