White-tailed deer detection rates increase when coyotes are present

Hannah L Clipp; Sarah M Pesi; Madison L Miller; Laura C Gigliotti; Brett P Skelly; Christopher T Rota

doi:10.1002/ece3.11149

White-tailed deer detection rates increase when coyotes are present

Ecol Evol. 2024 Mar 17;14(3):e11149. doi: 10.1002/ece3.11149. eCollection 2024 Mar.

Authors

Hannah L Clipp^{1

2}, Sarah M Pesi¹, Madison L Miller¹, Laura C Gigliotti³, Brett P Skelly^{1

4}, Christopher T Rota¹

Affiliations

¹ Division of Forestry and Natural Resources West Virginia University Morgantown West Virginia USA.
² West Virginia Cooperative Fish and Wildlife Research Unit West Virginia University Morgantown West Virginia USA.
³ U.S. Geological Survey West Virginia Cooperative Fish and Wildlife Research Unit Morgantown West Virginia USA.
⁴ West Virginia Division of Natural Resources Elkins West Virginia USA.

Abstract

Predator species can indirectly affect prey species through the cost of anti-predator behavior responses, which may involve shifts in occupancy, space use, or movement. Quantifying the various strategies implemented by prey species to avoid adverse interactions with predators can lead to a better understanding of potential population-level repercussions. Therefore, the purpose of this study was to examine predator-prey interactions by quantifying the effect of predator species presence on detection rates of prey species, using coyotes (Canis latrans) and white-tailed deer (Odocoileus virginianus) in Central Appalachian forests of the eastern United States as a model predator-prey system. To test two competing hypotheses related to interspecific interactions, we modeled species detections from 319 camera traps with a two-species occupancy model that incorporated a continuous-time detection process. We found that white-tailed deer occupancy was independent of coyote occupancy, but white-tailed deer were more frequently detectable and had greater detection intensity at sites where coyotes were present, regardless of vegetation-related covariates. In addition, white-tailed deer detection rates at sites with coyotes were highest when presumed forage availability was relatively low. These findings suggest that white-tailed deer may be exhibiting an active avoidance behavioral response to predators by increasing movement rates when coyotes are present in an area, perhaps due to reactive evasive maneuvers and/or proactive attempts to reduce adverse encounters with them. Concurrently, coyotes could be occupying sites with higher white-tailed deer densities. Because white-tailed deer did not exhibit significant shifts in daily activity patterns based on coyote occupancy, we further suggest that white-tailed deer in our study system generally do not use temporal partitioning as their primary strategy for avoiding encounters with coyotes. Overall, our study implements a recently developed analytical approach for modeling multi-species occupancy from camera traps and provides novel ecological insight into the complex relationships between predator and prey species.

Keywords: camera trap; coyote; detection rate; multi‐species occupancy model; predator–prey dynamics; white‐tailed deer.