2023 AMSS Abstract Book

Bering Sea | Fishes and Fish Habitats DOCTORATE ORAL PRESENTATION Shifting fish distributions drive changes in predation in the Eastern Bering Sea Presenter: Maurice Goodman , goodman3@stanford.edu, Stanford University Gemma Carroll , gcarroll@edf.org, Environmental Defense Fund Stephanie Brodie , stephanie.brodie@noaa.gov Arnaud Grüss , gruss.arnaud@gmail.com James Thorson , james.thorson@noaa.gov, NOAA Fisheries Alaska Fisheries Science Center

Stan Kotwicki , stan.kotwicki@noaa.gov, NOAA Kirstin Holsman , kirstin.holsman@noaa.gov Rebecca Selden , bselden@wellesley.edu Elliott Hazen , elliott.hazen@noaa.gov Giulio De Leo , deleo@stanford.edu

An abundance of studies in marine systems have documented species range shifts in response to climate change, and many more have used species distribution models to project species ranges under future conditions. However, there is increasing interest in moving beyond a single-species focus to understand how species redistribution alters ecosystem dynamics via changes in trophic interactions. We employed spatiotemporal models to characterize decadal-scale changes in spatial overlap between the distribution of juvenile walleye pollock ( Gadus chalcogrammus ) and the distributions of four of its groundfish predators: arrowtooth flounder (Atheresthes stomias), Pacific cod ( Gadus macrocephalus ), Pacific halibut ( Hippoglossus stenolepis ), and adult walleye pollock. These fishes represent ecologically and commercially important species in a rapidly changing sub-Arctic ecosystem, the Eastern Bering Sea, Alaska, U.S.A. We then examined whether changes in spatial overlap corresponded to changes in predation, using spatiotemporal models of predator stomach contents. We found marked shifts in spatial overlap between juvenile pollock and two predators (arrowtooth flounder and Pacific halibut) over 34 years, with changes in overlap corresponding to increases in population-scale predation pressure. By contrast, we did not find clear relationships between spatial overlap and predation for Pacific cod and adult pollock, the two predators for which juvenile pollock constitute a much smaller diet proportion. Our findings highlight the complexity of predicting predation dynamics for generalist marine species and suggest a need for better process-based methods for understanding the potential future ecological impacts of coupled species range shifts. However, simple metrics of spatial overlap between relatively specialized predators and their prey offer promise as a means to integrate predictions from species distribution models into ecosystem-based fisheries management.

Alaska Marine Science Symposium 2023 47

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