Modeling coupled dynamics of an empirical predator-prey system to predict top predator recovery

Samantha N. M. Hamilton; M. T. Tinker; Joseph Jackson; Joseph A. Tomoleoni; Michael C. Kenner; Julie L. Yee; Tomoko Bell; Max C. N. Castorani; Benjamin H. Becker; Brent B. Hughes

doi:10.1016/j.biocon.2024.110623

Modeling coupled dynamics of an empirical predator-prey system to predict top predator recovery

Biological Conservation

By: Samantha N. M. Hamilton, M. T. Tinker, Joseph Jackson, Joseph A. Tomoleoni, Michael C. Kenner, Julie L. Yee, Tomoko Bell, Max C. N. Castorani, Benjamin H. Becker, and Brent B. Hughes

https://doi.org/10.1016/j.biocon.2024.110623

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Abstract

Limited data, time, and funding lead conservation managers to make difficult choices in managing species recovery. Coupled dynamical models are relied upon for decision support, but their application to empirical predator-prey systems has generally been restricted to small, tractable species. To broaden their use in conservation decision-making, we developed a model suitable for predicting the population dynamics of a larger apex carnivore and its prey. We selected southern sea otters (Enhydra lutris nereis) and their primary estuarine prey as our case study and parameterized the dynamical model with data on sea otter, clam, and crab abundances; predator-prey interactions; and sea otter bioenergetics collected from Elkhorn Slough, CA. Our model, having integrated all these salient factors, was able to successfully reproduce trends in taxa abundance as well as shifts in sea otter diet composition and energy intake rates. Rich data inputs allow the model to predict population dynamics over realistic temporal scales not only for the site of data collection, but also for similar estuaries uncolonized by sea otters. Based on model projections parameterized with prey survey data from two such estuaries, Tomales Bay and Drakes Estero, we predict the sites could support over 160 sea otters and may hold potential to further species recovery. In systems with good data availability, the model has high predictive power and can provide multi-taxa projections useful for making informed management decisions.

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Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Modeling coupled dynamics of an empirical predator-prey system to predict top predator recovery
Series title	Biological Conservation
DOI	10.1016/j.biocon.2024.110623
Volume	294
Year Published	2024
Language	English
Publisher	Elsevier
Contributing office(s)	Western Ecological Research Center
Description	110623, 10 p.
First page	110623
Country	United States
State	California
Other Geospatial	Drakes Estero, Tomales Bay
Google Analytic Metrics	Metrics page