Rain, recreation and risk: Human activity and ecological disturbance create seasonal risk landscapes for the prey of an ambush predator

Abernathy, Heather N.; Crawford, Derek A.; Chandler, Richard B.; Garrison, Elina P.; Conner, L. Mike; Miller, Karl V.; Cherry, Michael J.

doi:10.1111/1365-2656.13976

Cited by 4 publications

(2 citation statements)

References 103 publications

(203 reference statements)

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“…However, animals may also exhibit weaker or no response to humans if the benefit of increased energy intake from resource subsidies (Matassa et al, 2016) or refugia from predation (Muhly et al, 2011) outweighs the cost of higher anthropogenic risk. Responsiveness to humans may also fluctuate if foraging requirements and behaviours are seasonal due to breeding state or environmental conditions (Abernathy et al, 2023). Finally, humans might serve as an attractant if providing resource subsidies, causing animals to relax antipredator responses to access these resources (Darlington et al, 2022).…”

Section: Conditions Predicted To Produce a Phenotypic Response To Hum...mentioning

confidence: 99%

Population and community consequences of perceived risk from humans in wildlife

Smith,

McDaniels,

Peacor

et al. 2024

Ecology Letters

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Human activities catalyse risk avoidance behaviours in wildlife across taxa and systems. However, the broader ecological significance of human‐induced risk perception remains unclear, with a limited understanding of how phenotypic responses scale up to affect population or community dynamics. We present a framework informed by predator–prey ecology to predict the occurrence of non‐consumptive effects (NCE) and trait‐mediated indirect effects (TMIE) of anthropogenic disturbances. We report evidence from a comprehensive review of the different types of human‐induced behavioural and physiological phenotypic changes and their influence on vital rates and population parameters in wildlife. Evidence for human‐induced NCEs and TMIEs is mixed, with half of published studies finding a relationship between human activities, phenotypic change and population outcomes. The net effects of anthropogenic NCEs and TMIEs depend on the mismatch between the phenotypic response and the lethality of human activity. However, strong research biases in taxa, systems, human disturbance types and demographic measures prevent unified inference about the prevalence of population responses to human activities. Coexistence with and conservation of wildlife requires additional research linking human‐induced phenotypic change to population and community outcomes.

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Section: Conditions Predicted To Produce a Phenotypic Response To Hum...mentioning

confidence: 99%

Population and community consequences of perceived risk from humans in wildlife

Smith,

McDaniels,

Peacor

et al. 2024

Ecology Letters

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“…Variability in predator‐prey interactions is often a function of environmental conditions. For example, ecological disturbance, such as fire and flooding can result in considerable change in environmental conditions and can influence deer behavior during lactation (Lashley et al 2015, Cherry et al 2017, Abernathy et al 2022), interactions between deer and their predators (Doherty et al 2022, Abernathy et al 2023), and survival of neonates (Engebretsen et al 2023) and adult females (Bled et al 2022). Antipredator defenses exhibited by deer change with age, most notably when neonates complete the limited mobility period, abandon their hiding strategy, and begin to follow their mother.…”

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confidence: 99%

Survival, cause‐specific mortality, and population growth of white‐tailed deer in western Virginia

Clevinger,

Ford,

Kelly

et al. 2023

J Wildl Manag

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Understanding the role of recruitment in population dynamics of white‐tailed deer (Odocoileus virginianus) is important for management. In the central Appalachian Mountains, deer are part of a largely forested ecosystem that supports 3 carnivore species thought to be capable of influencing white‐tailed deer recruitment: black bears (Urus americanus), coyotes (Canis latrans), and bobcats (Lynx rufus). Yet little is known about predation, how other environmental factors influence recruitment, or the importance of neonate survival to white‐tailed deer population performance in the region. Our objectives were to identify causes of mortality for neonates, analyze effects of landscape attributes on survival of neonates, estimate survival rates for neonates and adult female white‐tailed deer, and to model population growth trends based on current vital rates and hypothetical harvest and neonate survival scenarios. During 2019–2020, we captured 57 neonate deer in Bath County, Virginia, USA, by monitoring 38 pregnant females equipped with global positioning system collars and vaginal implant transmitters and by conducting transect searches for recently born neonates. We observed 37 neonate mortalities and identified cause of death using field and genetic evidence. Mortalities included 28 predation events and 9 deaths from other causes (e.g., abandonment, malnutrition, disease). Black bears accounted for 48.6% of neonate mortalities, and 64.2% of predation events (n = 18), followed by bobcats (n = 5) and coyotes (n = 3). Annual survival for adult female deer was 0.871 and neonate survival to 12 weeks old was 0.310. Elevation was a significant predictor of neonate survival; mortality risk increased 20% for every 100‐m increase in elevation. Models of annual population growth using observed vital rates predicted an increasing population (λ = 1.10). A 10% increase in female harvest would still result in a potential population increase of 2% (λ = 1.02), but a 20% increase in harvest rate would result in a potential 7% decline (λ = 0.93). Neonate survival was higher near fertile valley bottoms and lower along forested ridges characterized by shallow, infertile soils and limited edge or early successional forests. While predation, largely influenced by black bears, was the leading cause of neonate mortality and contributed to low neonate survival, we observed little evidence of population decline, and suggest there is opportunity for a modest increase in harvest of female deer.

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Measuring the benefit of a defensive trait: Vigilance and survival probability

Ellsworth,

Peacor,

Chandler

et al. 2024

Ecology

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Defensive traits are hypothesized to benefit prey by reducing predation risk from a focal predator but come at a cost to the fitness of the prey. Variation in the expression of defensive traits is seen among individuals within the same population, and in the same individual in response to changes in the environment (i.e., phenotypically plastic responses). It is the relative magnitude of the cost and benefit of the defensive trait that underlies the defensive trait expression and its consequences to the community. However, whereas the cost has received much attention in ecological research, the benefit is seldom examined. Even in a defensive trait as extensively studied as vigilance, there are few studies of the purported benefit of the behavior, namely that vigilance enhances survival. We examined whether prey vigilance increased survival and quantified that benefit in a natural system, with white‐tailed deer (Odocoileus virginianus) experiencing unmanipulated levels of predation risk from Florida panther (Puma concolor coryi). Deer that spent more time vigilant (as measured by head position using camera trap data) had a higher probability of survival. Indeed, an individual deer that was vigilant 75% of the time was more than three times as likely to be killed by panthers over the course of a year than a deer that was vigilant 95% of the time. Our results therefore show that within‐population variation in the expression of a defensive trait has profound consequences for the benefit it confers. Our results provide empirical evidence supporting a long‐held but seldom‐tested hypothesis, that vigilance is a behavior that reduces the probability of predation and quantifies the benefit of this defensive trait. Our work furthers an understanding of the net effects of a trait on prey fitness and predator–prey interactions, within‐population variation in traits, and predation risk effects.

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Rain, recreation and risk: Human activity and ecological disturbance create seasonal risk landscapes for the prey of an ambush predator

Cited by 4 publications

References 103 publications

Population and community consequences of perceived risk from humans in wildlife

Population and community consequences of perceived risk from humans in wildlife

Survival, cause‐specific mortality, and population growth of white‐tailed deer in western Virginia

Measuring the benefit of a defensive trait: Vigilance and survival probability

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