Changing Seascapes, Stochastic Connectivity, and Marine Metapopulation Dynamics

Watson, James R.; Kendall, Bruce E.; Siegel, David A.; Mitarai, Satoshi

doi:10.1086/665992

Cited by 95 publications

(142 citation statements)

References 53 publications

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“…In reality, connectivity and LEP all likely vary over time. Stochasticity in connectivity can decrease (Watson et al 2012) or increase (Williams and Hastings 2013) metapopulation growth rates.…”

Section: Persistence In a Network Of Connected Populationsmentioning

confidence: 99%

Beyond connectivity: how empirical methods can quantify population persistence to improve marine protected‐area design

Burgess

Nickols

Griesemer

et al. 2014

Ecological Applications

203

297

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Abstract. Demographic connectivity is a fundamental process influencing the dynamics and persistence of spatially structured populations. Consequently, quantifying connectivity is essential for properly designing networks of protected areas so that they achieve their core ecological objective of maintaining population persistence. Recently, many empirical studies in marine systems have provided essential, and historically challenging to obtain, data on patterns of larval dispersal and export from marine protected areas (MPAs). Here, we review the empirical studies that have directly quantified the origins and destinations of individual larvae and assess those studies' relevance to the theory of population persistence and MPA design objectives. We found that empirical studies often do not measure or present quantities that are relevant to assessing population persistence, even though most studies were motivated or contextualized by MPA applications. Persistence of spatial populations, like nonspatial populations, depends on replacement, whether individuals reproduce enough in their lifetime to replace themselves. In spatial populations, one needs to account for the effect of larval dispersal on future recruitment back to the local population through local retention and other connectivity pathways. The most commonly reported descriptor of larval dispersal was the fraction of recruitment from local origin (self-recruitment). Self-recruitment does not inform persistence-based MPA design because it is a fraction of those arriving, not a fraction of those leaving (local retention), so contains no information on replacement. Some studies presented connectivity matrices, which can inform assessments of persistence with additional knowledge of survival and fecundity after recruitment. Some studies collected data in addition to larval dispersal that could inform assessments of population persistence but which were not presented in that way. We describe how three pieces of empirical information are needed to fully describe population persistence in a network of MPAs: (1) lifetime fecundity, (2) the proportion of larvae that are locally retained (or the full connectivity matrix), and (3) survival rate after recruitment. We conclude by linking theory and data to provide detailed guidance to empiricists and practitioners on field sampling design and data presentation that better informs the MPA objective of population persistence.

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Section: Persistence In a Network Of Connected Populationsmentioning

confidence: 99%

Beyond connectivity: how empirical methods can quantify population persistence to improve marine protected‐area design

Burgess

Nickols

Griesemer

et al. 2014

Ecological Applications

203

297

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“…Huret et al, 2007;Tian et al, 2009a) to tens of millions (e.g. Watson et al, 2012;Jones et al, 2015). Field research that relies on parentage, tagging, or drifter data may be limited to only a few hundred sample points (Almany et al, 2007;Planes et al, 2009).…”

Section: Discussionmentioning

confidence: 99%

“…IBM studies may simulate tens of millions of particles and consume vast computational resources (e.g. Watson et al, 2012;Jones et al, 2015), and so we seek an alternative method that reduces the required number of particles.…”

Section: Introductionmentioning

confidence: 99%

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Trait-based modeling of larval dispersal in the Gulf of Maine

Jones¹

2017

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“…Elucidating the mechanisms that control patterns of diversity is a central objective of community ecology (Hubbell 2001, Leibold et al 2004, and has been the focus of considerable research across terrestrial (Tuomisto et al 2003, De Cáceres et al 2012, freshwater (Maloney & Munguia 2011, Angeler 2013) and marine systems (Watson et al 2012, Moritz et al 2013. A better understanding of these mechanisms is critically important for conservation planning, which has historically focussed on prioritizing protection of areas containing high species richness and threatened or endemic species, but often failed to incorporate underlying variation in regional species assembly driven by ecological connectivity, spatial processes and environmental heterogeneity (McKnight et al 2007).…”

Section: Introductionmentioning

confidence: 99%

Geographic distance, water circulation and environmental conditions shape the biodiversity of Mediterranean rocky coasts

Rattray¹,

Andrello²,

Asnaghi³

et al. 2016

Mar. Ecol. Prog. Ser.

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Ecological connectivity is important for effective marine planning and biodiversity conservation. Our aim was to identify factors important in influencing variation in benthic community structure on shallow rocky reefs in 2 regions of the Mediterranean Sea with contrasting oceanographic regimes. We assessed beta (β) diversity at 146 sites in the littoral and shallow sublittoral from the Adriatic/Ionian Seas (eastern region) and Ligurian/Tyrrhenian Seas (western region) using a null modelling approach to account for variation in species richness. The distance decay relationship between species turnover within each region and geographic distance by sea was determined using generalised linear models. Mantel tests were used to examine correlations between β diversity and connectivity by ocean currents, estimated from Lagrangian dispersal simulations. Variation in β diversity between sites was partitioned according to environmental and spatial components using a distance-based redundancy approach. Species turnover along a gradient of geographic distance was greater by a factor of 3 to 5 in the western region than the eastern region, suggesting lower connectivity between sites. β diversity was correlated with connectivity by ocean currents at both depths in the eastern region but not in the western region. The influ-

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Changing Seascapes, Stochastic Connectivity, and Marine Metapopulation Dynamics

Cited by 95 publications

References 53 publications

Beyond connectivity: how empirical methods can quantify population persistence to improve marine protected‐area design

Beyond connectivity: how empirical methods can quantify population persistence to improve marine protected‐area design

Trait-based modeling of larval dispersal in the Gulf of Maine

Geographic distance, water circulation and environmental conditions shape the biodiversity of Mediterranean rocky coasts

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