Evaluation of rockfish conservation area networks in the United States and Canada relative to the dispersal distance for black rockfish (Sebastes melanops)

Katie E Lotterhos,Dana R Haggarty,Stefan J Dick

doi:10.1111/eva.12115

Katie E Lotterhos, Dana R Haggarty + Show 1 more

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https://doi.org/10.1111/eva.12115

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Journal: Evolutionary applications	Publication Date: Nov 4, 2013
Citations: 17	License type: CC BY 3.0

Affiliation: University of British Columbia

Abstract

Marine reserves networks are implemented as a way to mitigate the impact of fishing on marine ecosystems. Theory suggests that a reserve network will function synergistically when connected by dispersal, but the scale of dispersal is often unknown. On the Pacific coast of the United States and Canada, both countries have recently implemented a number of rockfish conservation areas (RCAs) to protect exploited rockfish species, but no study has evaluated the connectivity within networks in each country or between the two countries. We used isolation-by-distance theory to estimate the scale of dispersal from microsatellite data in the black rockfish, Sebastes melanops, and compared this estimate with the distance between RCAs that would protect this species. Within each country, we found that the distance between RCAs was generally within the confidence intervals of mean dispersal per generation. The distance between these two RCA networks, however, was greater than the average dispersal per generation. The data were also consistent with a genetic break between southern Oregon and central Oregon. We discuss whether additional nearshore RCAs in southern Oregon and Washington would help promote connectivity between RCA's for shallow-water rockfishes.

Highlights

Marine reserve or marine protected area networks are intended to protect a species or a suite of species from overexploitation
Many factors are important in the efficacy of a reserve network to produce a synergistic effect on population growth, but generally the distance and direction of larval dispersal is a primary issue because it determines the rates of self-recruitment, plays a role in maintaining a persistent network of reserves, and maximizes benefits to the fishery through recruitment subsidy (Sale et al 2005; Gaines et al 2010)
We evaluated the population genetic structure of the black rockfish, Sebastes melanops from southern Oregon to northern British Columbia (BC) and used isolation-by-distance theory to estimate the scale of dispersal

Summary

Introduction

Marine reserve or marine protected area networks are intended to protect a species or a suite of species from overexploitation. Many factors are important in the efficacy of a reserve network to produce a synergistic effect on population growth, but generally the distance and direction of larval dispersal is a primary issue because it determines the rates of self-recruitment, plays a role in maintaining a persistent network of reserves, and maximizes benefits to the fishery through recruitment subsidy (Sale et al 2005; Gaines et al 2010). Assuming no contributions from fished areas, the efficacy of a reserve network is predicted to increase asymptotically as the size of individual reserves increases relative to the mean dispersal distance, regardless of the shape of the tail of the dispersal distribution (Botsford et al 2001; Lockwood et al 2002)

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