Seascape Genetics and the Spatial Ecology of Juvenile Green Turtles

Jensen, Michael P.; Dalleau, Mayeul; Gaspar, Philippe; Lalire, Maxime; Jean, Claire; Ciccione, Stéphane; Mortimer, Jeanne A.; Quillard, Mireille; Taquet, Coralie; Wamukota, Andrew; Leroux, Géraud; Bourjea, Jérôme

doi:10.3390/genes11030278

Cited by 21 publications

(11 citation statements)

References 70 publications

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“…Even for mobile species, able to swim actively while performing migrations or ontogenetic shifts in habitat use (Abecasis et al, 2009;Almpanidou et al, 2019), PD alone can explain more than 50% of the variation in genetic dispersal estimates (Kinlan and Gaines, 2003). Taxa without planktonic dispersal stages might also benefit from some aid in transportation by oceanographic currents, as suggested for some taxa like green turtles (e.g., Jensen et al, 2020), but not others (e.g., Briscoe et al, 2016).…”

Section: Mpa Aggregationsmentioning

confidence: 99%

Potential Biodiversity Connectivity in the Network of Marine Protected Areas in Western Africa

et al. 2021

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Marine Protected Areas (MPAs) must function as networks with sufficient stepping-stone continuity between suitable habitats to ensure the conservation of naturally connected regional pools of biodiversity in the long-term. For most marine biodiversity, population connectivity is mediated by passively dispersed planktonic stages with contrasting dispersal periods, ranging from a few hours to hundreds of days. These processes exert a major influence on whether threatened populations should be conserved as either isolated units or linked metapopulations. However, the distance scales at which individual MPAs are connected are insufficiently understood. Here, we use a biophysical model integrating high-resolution ocean currents and contrasting dispersal periods to predict connectivity across the Network of MPAs in Western Africa. Our results revealed that connectivity differs sharply among distinct ecological groups, from highly connected (e.g., fish and crustacea) to predominantly isolated ecosystem structuring species (e.g., corals, macroalgae and seagrass) that might potentially undermine conservation efforts because they are the feeding or nursery habitats required by many other species. Regardless of their dispersal duration, all ecological groups showed a common connectivity gap in the Bijagós region of Guinea-Bissau, highlighting the important role of MPAs there and the need to further support and increase MPA coverage to ensure connectivity along the whole network. Our findings provide key insights for the future management of the Network of MPAs in Western Africa, highlighting the need to protect and ensure continuity of isolated ecosystem structuring species and identifying key regions that function as stepping-stone connectivity corridors.

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Section: Mpa Aggregationsmentioning

confidence: 99%

Potential Biodiversity Connectivity in the Network of Marine Protected Areas in Western Africa

et al. 2021

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“…Although migratory data of juvenile green turtles are limited (e.g. Sanchez et al 2020), oceanic currents play an important role in the distribution of juvenile green turtles through the WIO (Jensen et al 2020). Four satellite tags deployed on juvenile green turtles in southern Tanzania showed that they stayed close (approximately 10 km) to the capture site (Sea Sense 2017).…”

Section: Green Turtlementioning

confidence: 99%

“…Although research on the genetic structure of coastal populations of green, hawksbill, and loggerhead turtles has been conducted (Bourjea et al 2015b, Fernandes 2015, Anastácio & Pereira 2017, Jensen et al 2020, the experts noted that further work is needed to place the coastal foraging and nesting populations of all 5 species in a regional context (Fig. 4B).…”

Section: Genetic Connectivitymentioning

confidence: 99%

Marine turtles of the African east coast: current knowledge and priorities for conservation and research

Geer

Bourjea

Broderick

et al. 2022

Endang. Species. Res.

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Although published literature regarding the 5 species of marine turtle found along the continental African east coast has grown substantially over the last decades, a comprehensive synthesis of their status and ecology is lacking. Using a mixed methods approach, which combined an exhaustive literature review and expert elicitation, we assessed the distribution and magnitude of nesting, foraging areas, connectivity, and anthropogenic threats for these species in Somalia, Kenya, Tanzania, Mozambique, and South Africa. A complex pattern of nesting sites, foraging areas, and migration pathways emerged that identified areas of high importance in all 5 countries, although significant data gaps remain, especially for Somalia. Illegal take, bycatch, and loss of foraging and nesting habitat were identified as the most serious anthropogenic threats. Although these threats are broadly similar along most of the coast, robust data that enable quantification of the impacts are scarce. Experts identified regional strengths and opportunities, as well as impediments to turtle conservation. Topics such as legislation and enforcement, collaboration, local stakeholders, and funding are discussed, and future directions suggested. Given the projected growth in human population along the continental African east coast and expected accompanying development, anthropogenic pressures on turtle populations are set to increase. Stronger regional collaboration and coordination within conservation and research efforts are needed if current and future challenges are to be tackled effectively.

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“…Recent studies that integrated phylogeographic inference, numerical ocean circulation models, and Lagrangian simulation of individual particle trajectories (van Sebille et al ., 2018) have greatly improved our knowledge of the ecological factors driving evolution in the oceans. These include studies of genetic structure (Bertola et al ., 2020; Sefc et al ., 2020), connectivity and establishment (Jensen et al ., 2020; Nikolic et al ., 2020) of marine organisms. For terrestrial plants, mechanistic dispersal simulations also have been used to predict propagule transoceanic dispersal of mangroves (Van der Stocken et al ., 2019), seagrasses (Smith et al ., 2018) and Urticaceae (Wu et al ., 2018), and to confirm the origin of pre‐Columbian bottle gourds (Kistler et al ., 2014).…”

Section: Introductionmentioning

confidence: 99%

Congruence between ocean‐dispersal modelling and phylogeography explains recent evolutionary history of Cycas species with buoyant seeds

Liu

Lindström²,

Chen

et al. 2021

New Phytologist

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Summary Ocean currents play a significant role in driving the long‐distance dispersal (LDD), spatial distribution and phylogeographic patterns of many organisms. Integrating phylogeographic analyses and mechanistic ocean current modelling can provide novel insights into the evolutionary history of terrestrial littoral species but has been rarely applied in this context. We focused on a group of Cycas that have buoyant seeds and occupy coastal habitats. By integrating evidence from mechanistic simulations and whole plastomic data, we examined the role of ocean circulation in shaping the phylogeography of these Cycas species. Plastomes of the studied Cycas species showed extreme conservatism, following a post‐Pleistocene divergence. Phylogenies revealed three subclades, corresponding to the Pacific Ocean, Sunda Shelf and Indian Ocean. The ocean modelling results indicate that hotspots of seed stranding coincide well with the contemporary distribution of the Cycas species and that drifting trajectories from the three subclades are largely confined to separate regions. These findings suggest that ocean current systems, by driving long‐distance dispersal, have shaped the distribution and phylogeography for Cycas with buoyant seeds. This study highlights how the combination of genomic data and ocean drift modelling can help explain phylogeographic patterns and diversity in terrestrial littoral ecosystems.

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Seascape Genetics and the Spatial Ecology of Juvenile Green Turtles

Cited by 21 publications

References 70 publications

Potential Biodiversity Connectivity in the Network of Marine Protected Areas in Western Africa

Potential Biodiversity Connectivity in the Network of Marine Protected Areas in Western Africa

Marine turtles of the African east coast: current knowledge and priorities for conservation and research

Congruence between ocean‐dispersal modelling and phylogeography explains recent evolutionary history of Cycas species with buoyant seeds

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