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Using bio-physical modelling and population genetics for conservation and management of an exploited species, Pecten maximus L. / Hold, Natalie; Robins, Peter; Szostek, Claire et al.
In: Fisheries Oceanography, Vol. 30, No. 6, 11.2021, p. 740-756.

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Hold N, Robins P, Szostek C, Lambert G, Lincoln H, Le Vay L et al. Using bio-physical modelling and population genetics for conservation and management of an exploited species, Pecten maximus L. Fisheries Oceanography. 2021 Nov;30(6):740-756. Epub 2021 Jul 2. doi: 10.1111/fog.12556

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TY - JOUR

T1 - Using bio-physical modelling and population genetics for conservation and management of an exploited species, Pecten maximus L.

AU - Hold, Natalie

AU - Robins, Peter

AU - Szostek, Claire

AU - Lambert, Gwladys

AU - Lincoln, Harriet

AU - Le Vay, Lewis

AU - Bell, Ewen

AU - Kaiser, Michael

PY - 2021/11

Y1 - 2021/11

N2 - Connectivity between populations is important when considering conservation or the management of exploitation of vulnerable species. We investigated how populations of a broadcast-spawning marine species (scallop, Pecten maximus) that occur in discrete geographic locations were connected to each other. Population genetic insights were related to the outputs from a three-dimensional hydrodynamic model implemented with scallop larval behaviour to understand the extent to which these areas were linked by oceanographic processes and how this was altered by season and two contrasting years that had strongly different average temperature records (warm vs cold) to provide contrasting oceanographic conditions. Our results span from regional to shelf scale. Connectivity was high at a regional level (e.g. northern Irish Sea), but lower at scales > 100 km between sites. Some localities were possibly isolated thus dependent on self-recruitment to sustain local populations. Seasonal timing of spawning and inter-annual fluctuations in seawater temperature influenced connectivity patterns, and hence will affect spatial recruitment. Summer rather than spring spawning increased connectivity among some populations, due to the seasonal strengthening of temperature-driven currents. Furthermore, the warm year resulted in higher levels of modelled connectivity than the cold year. The combination of genetic and oceanographic approaches provided valuable insights into the structure and connectivity at a continental shelf scale. This insight provides a powerful basis for defining conservation management units and the appropriate scale for spatial management. Temporal fluctuations in temperature impact upon variability in connectivity, suggesting that future work should account for ocean warming when investigating population resilience.

AB - Connectivity between populations is important when considering conservation or the management of exploitation of vulnerable species. We investigated how populations of a broadcast-spawning marine species (scallop, Pecten maximus) that occur in discrete geographic locations were connected to each other. Population genetic insights were related to the outputs from a three-dimensional hydrodynamic model implemented with scallop larval behaviour to understand the extent to which these areas were linked by oceanographic processes and how this was altered by season and two contrasting years that had strongly different average temperature records (warm vs cold) to provide contrasting oceanographic conditions. Our results span from regional to shelf scale. Connectivity was high at a regional level (e.g. northern Irish Sea), but lower at scales > 100 km between sites. Some localities were possibly isolated thus dependent on self-recruitment to sustain local populations. Seasonal timing of spawning and inter-annual fluctuations in seawater temperature influenced connectivity patterns, and hence will affect spatial recruitment. Summer rather than spring spawning increased connectivity among some populations, due to the seasonal strengthening of temperature-driven currents. Furthermore, the warm year resulted in higher levels of modelled connectivity than the cold year. The combination of genetic and oceanographic approaches provided valuable insights into the structure and connectivity at a continental shelf scale. This insight provides a powerful basis for defining conservation management units and the appropriate scale for spatial management. Temporal fluctuations in temperature impact upon variability in connectivity, suggesting that future work should account for ocean warming when investigating population resilience.

KW - biophysical modelling

KW - connectivity

KW - fisheries management

KW - genetics

KW - marine protected areas

KW - scallop

KW - spatial management

U2 - 10.1111/fog.12556

DO - 10.1111/fog.12556

M3 - Article

VL - 30

SP - 740

EP - 756

JO - Fisheries Oceanography

JF - Fisheries Oceanography

SN - 1365-2419

IS - 6

ER -