Biophysical modelling and graph theory identify key connectivity hubs in the Mediterranean marine reserve network

Abecasis, David; Fragkopoulou, Eliza; Claro, Bruno; Assis, Jorge

doi:10.3389/fmars.2022.1000687

Cited by 8 publications

(13 citation statements)

References 85 publications

(124 reference statements)

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“…Overall, the example shows that oceanographic connectivity influences population differentiation of the kelp species, explaining ~65 % of genetic data variability. The second example 19 maps oceanographic connectivity of fish populations along a network of Mediterranean MPAs. The code estimates fish connectivity (using a typical pelagic larvae duration of 32 days 7,15 ) between spatial polygon data representing the shape and distribution of MPAs (Figure 2b; Supplement 2).…”

Section: Usage Notesmentioning

confidence: 99%

“…Such an approach considers biological populations as graph vertices with their edges represented by oceanographic connectivity estimates (e.g., probability of connectivity). Specific graph algorithms can compute multigenerational stepping-stone connectivity 12 or identify critical connectivity components with higher centrality that can bridge populations across large water masses 19 . Despite the significant advancements made through biophysical modeling in understanding the role of coastal oceanographic connectivity on marine biodiversity patterns 2,3,14,20 , and its implications for marine conservation and management 7,15,19 , research is hindered by the lack of a globally ready-to-use connectivity database.…”

Section: Introductionmentioning

confidence: 99%

“…Specific graph algorithms can compute multigenerational stepping-stone connectivity 12 or identify critical connectivity components with higher centrality that can bridge populations across large water masses 19 . Despite the significant advancements made through biophysical modeling in understanding the role of coastal oceanographic connectivity on marine biodiversity patterns 2,3,14,20 , and its implications for marine conservation and management 7,15,19 , research is hindered by the lack of a globally ready-to-use connectivity database. This limitation is impaired by the technical and computational requirements associated with the development of such complex modeling tools.…”

Section: Introductionmentioning

confidence: 99%

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Coastal oceanographic connectivity estimates at the global scale

Assis,

Legrand,

Fragkopoulou

et al. 2024

Preprint

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Oceanographic connectivity driven by ocean currents is critical in determining the distribution of marine biodiversity. It mediates the genetic and individual exchange between populations, from structuring dispersal barriers that promote long-term isolation to enabling long-distance dispersal that underpins species expansion and resilience against climate change. Despite its significance, comprehensive estimates of oceanographic connectivity on a global scale remain unavailable, while traditional approaches, often simplistic, fail to capture the complexity of oceanographic factors contributing to population connectivity. This gap hinders a deeper understating of species dispersal ecology, survival, and evolution, ultimately precluding the development of effective conservation strategies aimed at preserving marine biodiversity. To address this challenge, we present a comprehensive dataset of connectivity estimates along the world's coastlines, known for their rich marine biodiversity. These estimates are derived from a biophysical modelling framework that combines high-resolution ocean current data with graph theory to predict multi-generational stepping-stone connectivity. Alongside, we provide coastalNet, an R package designed to streamline access, analysis, and visualization of connectivity estimates. This tool enhances the utility and application of the data, adhering to the FAIR principles of Findability, Accessibility, Interoperability, and Reusability. The dataset and package set a new benchmark for research in oceanographic connectivity, allowing a better exploration of the complex dynamics of coastal marine ecosystems.

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Section: Usage Notesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Coastal oceanographic connectivity estimates at the global scale

Assis,

Legrand,

Fragkopoulou

et al. 2024

Preprint

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“…Some of those approaches have been applied to marine ecosystems (e.g., Abecasis et al., 2023; David et al., 2022; Ospina‐Alvarez et al., 2020; Thomas et al., 2014; Treml et al., 2008), but their application to the deep‐sea benthos over spatial scales of hundreds of kilometres remains challenging, requiring trade‐offs between the information content of available metrics and their data requirements (Calabrese & Fagan, 2004). Habitat patches of VMEs in the deep sea can neither be precisely localized nor well characterized.…”

Section: Introductionmentioning

confidence: 99%

“…Indices that are responsive to the extent of the areas of patches, within viable dispersal distances of others, best capture patch connectivity (Bender et al, 2003;Fahrig, 2013;Fortin & Dale, 2005;Rutledge, 2003;Taylor et al, 1993). Some of those approaches have been applied to marine ecosystems (e.g., Abecasis et al, 2023;David et al, 2022; Ospina-Alvarez TA B L E 1 Extent of suitable habitat and network characteristics for each of seven groups of deep-sea benthic invertebrate taxa forming vulnerable marine ecosystems. , 2020;Thomas et al, 2014;Treml et al, 2008), but their application to the deep-sea benthos over spatial scales of hundreds of kilometres remains challenging, requiring trade-offs between the information content of available metrics and their data requirements (Calabrese & Fagan, 2004).…”

Section: Introductionmentioning

confidence: 99%

Quantifying the effects of fragmentation of connectivity networks of deep‐sea vulnerable marine ecosystems

Wang,

Kenchington,

Murillo

et al. 2024

Diversity and Distributions

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AimProtection of vulnerable marine ecosystems (VMEs) in the high seas has focussed on identifying concentrations of indicator species and prohibiting the operation of bottom‐contact fishing gears where those occur in significant concentrations. Most such species have planktonic larvae and depend on dispersal networks for inter‐generational persistence. Yet, connectivity amongst patches of VME has seldom been considered when spatial management measures are introduced. Here, the relative importance of individual patches for the maintenance of their connectivity networks is evaluated, and a prioritization scheme for management action is proposed. Effective conservation measures should maintain approximately natural network configurations whenever possible.LocationGrand Bank and Flemish Cap, Northwest Atlantic Ocean.Methods3‐D Lagrangian particle tracking was used to model larval dispersal connections between known patches of each of seven groups of benthic invertebrate taxa, previously recognized as indicators of VME. Connectivity networks were constructed and the effects of habitat loss simulated by systematic removal of whole patches, to determine the importance of each patch to connectivity within its respective network.ResultsThe various patches differed widely in their contributions to network connectivity. Each taxon group had both some patches that, if removed from the network, would result in a major decline in connectedness but also several which could be lost with negligible consequences for the remainder.Main ConclusionsWhile protecting each patch of VME has conservation value, the wide variation in connectedness shows that some patches are much more critical than others to the long‐term persistence of the taxa, providing a foundation for prioritization of conservation actions.

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