Linking bio-oceanography and population genetics to assess larval connectivity

Soria, Gaspar; Munguía‐Vega, Adrián; Marinone, S.G.; Moreno-Báez, Marcia; Martínez-Tovar, Iván; Cudney-Bueno, Richard

doi:10.3354/meps09866

Cited by 38 publications

(34 citation statements)

References 65 publications

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“…Later versions emphasized the need to design networks of multiple interconnected reserves to scale up their benefits and allow for multiplicative properties that are not present in individual reserves (e.g. the demographic coupling of populations in different reserves: Gaines et al 2010;Sale et al 2010;Jessen et al 2011), or to more carefully consider constraints imposed by local human activities (Fraschetti et al 2009). …”

Section: Marine Reserves and The Gulf Of Californiamentioning

confidence: 99%

“…Biophysical models and genetic studies indicate that larval dispersal kernels in the GOC are not spatially symmetrical but are highly constrained in particular routes by the direction of the currents driven by the narrow shape of the Gulf, particularly for species that spawn during a single season (Soria et al 2012;Munguia-Vega et al 2014, 2015a, 2018TurkBoyer et al 2014;Lodeiros et al 2016;AlvarezRomero et al 2018) (Fig. 5).…”

Section: Larval Dispersalmentioning

confidence: 99%

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Ecological guidelines for designing networks of marine reserves in the unique biophysical environment of the Gulf of California

Munguía‐Vega

Green

Suárez-Castillo³

et al. 2018

Rev Fish Biol Fisheries

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No-take marine reserves can be powerful management tools, but only if they are well designed and effectively managed. We review how ecological guidelines for improving marine reserve design can be adapted based on an area's unique evolutionary, oceanic, and ecological characteristics in the Gulf of California, Mexico. We provide ecological guidelines to maximize benefits for fisheries management, biodiversity conservation and climate change adaptation. These guidelines include: representing 30% of each major habitat (and multiple examples of each) in marine reserves within each of three biogeographic subregions; protecting critical areas in the life cycle of focal species (spawning and nursery areas) and sites with unique biodiversity; and establishing reserves in areas where local threats can be managed effectively. Given that strong, asymmetric oceanic currents reverse direction twice a year, to maximize 123Rev Fish Biol Fisheries (2018) 28:749-776 https://doi.org/10.1007/s11160-018-9529-y( 0123456789().,-volV) (0123456789().,-volV)

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Section: Marine Reserves and The Gulf Of Californiamentioning

confidence: 99%

Section: Larval Dispersalmentioning

confidence: 99%

Ecological guidelines for designing networks of marine reserves in the unique biophysical environment of the Gulf of California

Munguía‐Vega

Green

Suárez-Castillo³

et al. 2018

Rev Fish Biol Fisheries

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“…We used the ecosystems inhabited by each focal species (Table S6) to represent their spawning and/or recruitment habitats, and assumed they all have, potentially, equal per unit area contributions of larvae. We did not distinguish between spawning and recruitment habitats because for our targeted species both are mainly areas within rocky reef systems (Aburto-Oropeza et al, 2007, Soria et al, 2012.…”

Section: Setting Conservation Goals and Objectivesmentioning

confidence: 99%

“…Given the lack of reliable downscaled projections of physical variables that force the model, our dispersal model did not explicitly include potential changes in currents due to ocean warming (e.g., Andrello et al, 2015), which is an area of active research. Further details of the oceanographic modeling can be found in previous studies , Munguía-Vega et al, 2015, Soria et al, 2012 and are summarized in the Supplementary Material.…”

Section: Setting Conservation Goals and Objectivesmentioning

confidence: 99%

“…Our measure of the value of planning units as stepping stones was distance-weighted fragmentation , which calculates the effect of removing a node on the overall connectivity of the network (Table S7). Given our aim was to maximize whole-of-network connectivity, and that only very few previously identified locations within our planning region showed modeled and empirical evidence of high self-recruitment , Soria et al, 2012, we did not target areas for self-recruitment. In fact, the location of sites showing high local larval retention in the region are unique, and our larval dispersal model shows they are few (Table S8) and associated to small eddies that form near the northern pointy ends of large islands or coastlines.…”

Section: Setting Conservation Goals and Objectivesmentioning

confidence: 99%

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Designing connected marine reserves in the face of global warming

Álvarez‐Romero¹,

Munguía‐Vega²,

Beger³

et al. 2018

Preprint

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. 2018. Designing connected marine reserves in the face of global warming. Global Change Biology 24: e671-e691. https://doi.org/10. 1111/gcb.13989 Designing connected marine reserves in the face of global warming Jorge G. Álvarez-Romero AbstractMarine reserves are widely used to protect species important for conservation and fisheries and to help maintain ecological processes that sustain their populations, including recruitment and dispersal. Achieving these goals requires well-connected networks of marine reserves that maximize larval connectivity, thus allowing exchanges between populations and recolonization after local disturbances. However, global warming can disrupt connectivity by shortening potential dispersal pathways through changes in larval physiology. These changes can compromise the performance of marine reserve networks, thus requiring adjusting their design to account for ocean warming. To date, empirical approaches to marine prioritization have not considered larval connectivity as affected by global warming. Here, we propose a framework for designing marine reserve networks that integrates graph theory and changes in larval connectivity due to potential reductions in planktonic larval duration (PLD) associated with ocean warming, given current socioeconomic constraints. Using the Gulf of California as case study, we assess the benefits and costs of adjusting networks to account for connectivity, with and without ocean warming. We compare reserve networks designed to achieve representation of species and ecosystems with networks designed to also maximize connectivity under current and future ocean-warming scenarios. Our results indicate that current larval connectivity could be reduced significantly under ocean warming because of shortened PLDs. Given the potential changes in connectivity, we show that our graph-theoretical approach based on centrality (eigenvector and distance-weighted fragmentation) of habitat patches can help design better-connected marine reserve networks for the future with equivalent costs. We found that maintaining dispersal connectivity incidentally through representation-only reserve design is unlikely, particularly in regions with strong asymmetric patterns of dispersal connectivity. Our results support previous studies suggesting that, given potential reductions in PLD due to ocean warming, future marine reserve networks would require more and/or larger reserves in closer proximity to maintain larval connectivity.

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