Testing predator–prey theory using broad‐scale manipulations and independent validation

• Published in: The Journal of animal ecology Vol. 84; no. 6; pp. 1600 - 1609
• Main Authors: Serrouya, Robert, McLellan, Bruce N, Boutin, Stan, Aubry, Lise
• Format: Journal Article
• Language: English
• Published: England Blackwell Scientific Publ 01.11.2015; John Wiley & Sons Ltd; Blackwell Publishing Ltd; John Wiley and Sons Inc
• Subjects: adaptive management; Alces alces; Allee; Animal populations; Animals; British Columbia; Canis lupus; caribou; Community ecology; conservation; Deer - physiology; depensatory; equations; Food Chain; limitation; meta-analysis; Models, Biological; moose; Population Density; population dynamics; Predation; Predatory Behavior; prediction; regulation; Standard Paper; Trophic Interactions; wolves; Wolves - physiology; British Columbia; limitation; conservation; regulation; caribou; depensatory; Allee; adaptive management; predation; moose; wolves
• ISSN: 0021-8790; 1365-2656
• DOI: 10.1111/1365-2656.12413

A robust test of ecological theory is to gauge the predictive accuracy of general relationships parameterized from multiple systems but applied to a new area. To address this goal, we used an ecosystem‐level experiment to test predator–prey theory by manipulating prey abundance to determine whether predation was density dependent, density independent, compensatory or depensatory (inversely density dependent) on prey populations. Understanding the nature of predation is of primary importance in community ecology because it establishes whether predation has little effect on prey abundance (compensatory), whether it promotes coexistence (density dependent) and reduces the equilibrium of prey (density independent) or whether it can be destabilizing (depensatory). We used theoretical predictions consisting of functional and numerical equations parameterized independently from meta‐analyses on wolves (Canis lupus) and moose (Alces alces), but applied to our specific wolf–moose system. Predictions were tested by experimentally reducing moose abundance across 6500 km² as a novel way of evaluating the nature of predation. Depensatory predation of wolves on moose was the best explanation of the population dynamic – a mechanism that has been hypothesized to occur but has rarely been evaluated. Adding locally obtained kill rates and numerical estimates to the independent data provided no benefit to model predictions, suggesting that the theory was robust to local variation. These findings have critical implications for any organism that is preyed upon but that also has, or will be, subject to increased human exploitation or perturbations from environmental change. If depensatory predation is not accounted for in harvest models, predicted yields will be excessive and lead to further population decline.