Designing connected marine reserves in the face of global warming

Álvarez‐Romero, Jorge G.; Munguía‐Vega, Adrián; Beger, Maria; Mancha‐Cisneros, Maria del Mar; Suárez-Castillo, Alvin Noé; Gurney, Georgina G.; Pressey, Robert L.; Gerber, Leah R.; Morzaria‐Luna, Hem Nalini; Reyes‐Bonilla, Héctor; Adams, Vanessa M.; Kolb, Mélanie; Graham, Erin; VanDerWal, Jeremy; Castillo‐López, Alejandro; Hinojosa‐Arango, Gustavo; Petatán‐Ramírez, David; Moreno-Báez, Marcia; Godínez‐Reyes, Carlos R.; Torre, Jorge

doi:10.1111/gcb.13989

Cited by 62 publications

(49 citation statements)

References 120 publications

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“…This will provide a sound framework for discussing potential tradeoffs and complementarity between both sets of guidelines. For example, fishing zones, which are mainly located downstream relative to the oceanic currents that transport larvae, have a higher economic value than upstream fishing zones (Alvarez-Romero et al 2018). Thus, prioritizing upstream sources of larvae for protection within marine reserves could result in a more connected and resilient network at comparatively lower socio-economic costs (Alvarez-Romero et al 2018).…”

Section: Discussionmentioning

confidence: 99%

“…For example, the current PLD of M. rosacea, the most heavily fished grouper in the GOC, may be reduced from 28 to 21 days with an average increase in temperature of 3°C, significantly decreasing the connectedness of marine reserve networks for rocky reefs in the asymmetric currents of the GOC, while shifting the importance of present day upstream larval sources to sites located more downstream in the direction of the flow (Alvarez-Romero et al 2018). This means that reserves may need to be larger and closer and/or networks may need to include more reserves to maintain larval connectivity in the future (Alvarez-Romero et al 2018).…”

Section: Climate Change Adaptationmentioning

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: Discussionmentioning

confidence: 99%

Section: Climate Change Adaptationmentioning

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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“…This is unlikely to be the case given the complex geography of the region. A more sophisticated extinction risk model could be developed based on historical records of cyclone damage and surveys of fish and their habitats, perhaps even with climate change effects ( Alvarez -Romero et al 2018). The algorithm in this model would tend to favor the protection of sites with lower risk of extinction and hence allocate MPAs to stable regions first.…”

Section: Discussionmentioning

confidence: 99%

Strategies in scheduling marine protected area establishment in a network system

Kininmonth

Abesamis

Bernardo

et al. 2018

Ecological Applications

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Instantaneous implementation of systematic conservation plans at regional scales is rare. More typically, planned actions are applied incrementally over periods of years or decades. During protracted implementation, the character of the connected ecological system will change as a function of external anthropogenic pressures, local metapopulation processes, and environmental fluctuations. For heavily exploited systems, habitat quality will deteriorate as the plan is implemented, potentially influencing the schedule of protected area implementation necessary to achieve conservation objectives. Understanding the best strategy to adopt for applying management within a connected environment is desirable, especially given limited conservation resources. Here, we model the sequential application of no‐take marine protected areas (MPAs) in the central Philippines within a metapopulation framework, using a range of network‐based decision rules. The model was based on selecting 33 sites for protection from 101 possible sites over a 35‐yr period. The graph‐theoretic network criteria to select sites for protection included PageRank, maximum degree, closeness centrality, betweenness centrality, minimum degree, random, and historical events. We also included a dynamic strategy called colonization–extinction rate that was updated every year based on the changing capacity of each site to produce and absorb larvae. Each rule was evaluated in the context of achieving the maximum metapopulation mean lifetime at the conclusion of the implementation phase. MPAs were designated through the alteration of the extinction risk parameter. The highest ranked criteria were PageRank while the actual implementation from historical records ranked lowest. Our results indicate that protecting the sites ranked highest with regard to larval supply is likely to yield the highest benefit for fish abundance and fish metapopulation persistence. Model results highlighted the benefits of including network processes in conservation planning.

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“…For conservation features, we used sea-floor habitat maps as they are found in varying proportions within and outside EEZ (Harris et al, 2014; S1), connectivity metrics as calculated in sections above, and EBSA (Fischer et al, 2019). We used degree and betweenness centrality connectivity metrics to inform selection of important areas for connectivity and reflecting best practice for planning for connected reserves ( Alvarez-Romero et al, 2018;Magris et al, 2018;Magris, Pressey, Weeks, & Ban, 2014). Thus connectivity objectives were to prioritize features that receive input from a larger number of other features or are sinks (measured with in-degree), which have a high number of connections going out to other features or are sources (measured with out-degree), and which may act as important stepping stones among other features (those that have a high betweenness centrality).…”

Section: Designing a Network Of Mpa Across Maritime Jurisdictionmentioning

confidence: 99%

“…Earlier reports on MPA connectivity indicate poor connections among global MPA network (Andrello et al, 2017) and a mismatch between fishing dependency and larval supply from MPAs'. For the full benefits of protected areas to be realized, closures should enhance maintenance of connections within MPA networks and between MPA networks and fished areas across maritime zones ( Alvarez-Romero et al, 2018). The Marxan-with-Zones best solution presents one option for expanding protection within EEZs to 15 and 9% within high seas to meet biodiversity targets aligned with existing priority areas (EBSAs) and maintain connectivity by protecting connected reefs.…”

Section: Aligning Conservation Areas To Regional Connectivity Patternsmentioning

confidence: 99%

Aligning marine spatial conservation priorities with functional connectivity across maritime jurisdictions

Maina

Gamoyo

Adams

et al. 2019

Conservat Sci and Prac

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Globally, maritime boundaries on oceans form the basis of governance and management of natural resources, yet the fish, and other marine resources neither conform nor confine to these artificial boundaries. As goods and services from marine life continue to retrogress under the intense human exploitation and changing global environment, resilience could be supported through establishment of a functionally connected network of marine reserves across maritime jurisdictions. While the establishment of protected areas within the exclusive economic zones (EEZ) is expanding, mechanisms that would allow governments to conserve marine areas beyond national jurisdictions are currently inadequate.Consequently, implementing marine reserves is largely confined within territorial waters, high connectivity among contiguous maritime zones notwithstanding. As the global focus shifts toward achieving sustainable development goals for the oceans, there is a need for region-specific approaches to area-based biodiversity conservation that extends the scope of protection to areas in the high seas beyond the EEZ. Using simulations of functional connectivity and seafloor geomorphology, we present and apply in the Western Indian Ocean (WIO) region a contextual approach to regional marine conservation planning to inform a more effective regional marine conservation across maritime zones. K E Y W O R D Sareas beyond national jurisdiction, fisheries management, functional connectivity, high seas, larval dispersal, marine conservation planning, marine protected areas, ocean governance, regional MPA, seafloor geomorphic habitats, Western Indian Ocean

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Designing connected marine reserves in the face of global warming

Cited by 62 publications

References 120 publications

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

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

Strategies in scheduling marine protected area establishment in a network system

Aligning marine spatial conservation priorities with functional connectivity across maritime jurisdictions

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