The role of sleeping sites in the predator‐prey dynamics of leopards and olive baboons

Predation risk affects prey species' behavior, even in the absence of a direct threat, but human‐induced environmental change may disturb ecologically significant predator–prey interactions. Here, we propose various ways in which knowledge of antipredator tactics, behavioral risk effects, and primate–predator interactions could assist in identifying human‐caused disruption to natural systems. Using behavior to evaluate primate responses to the ongoing environmental change should be a potentially effective way to make species conservation more predictive by identifying issues before a more dramatic population declines. A key challenge here is that studies of predation on primates often use data collected via direct observations of habituated animals and human presence can deter carnivores and influence subjects' perception of risk. Hence, we also review various indirect data collection methods to evaluate their effectiveness in identifying where environmental change threatens wild species, while also minimizing observer bias.

Section: Resultsmentioning

confidence: 99%

Anthropogenic influences on primate antipredator behavior and implications for research and conservation

LaBarge

Hill

Berman

et al. 2020

“…One was killed by a collared leopard (Isbell et al, ) 144 days after her capture (and transient prolapsed rectum), and we were able to retrieve her collar. Her separation from the other collared female for a week before her death and the location of her last sleeping site on a small boulder never used as a sleeping site before suggest she was incapacitated to some degree before she was killed (Bidner et al, ; Isbell et al, ). We were unable to locate the other baboon or the signal from her collar beyond 165 days after she was captured.…”

Section: Resultsmentioning

confidence: 99%

“…GPS collars have been deployed on many animal species (Tucker et al, ) but they are less commonly used with primates, in part because the typical observational approach of following habituated primates on foot allows animal locations to be estimated in other ways, including with handheld GPS units (e.g., Eckhardt, Polansky, & Boesch, ; Noser & Byrne, ; Santhosh, Kumara, Velankar, & Sinha, ; Schreier & Grove, ). Although locational data obtained with handheld GPS units are likely to be comparable with those obtained by GPS collars worn by animals if the observer follows the animal's path or corrects for the spatial displacement between the handheld unit and the animal (e.g., Noser & Byrne, ), GPS collars do not require observers to be present with the study animals and thus are useful for investigating questions that have been largely out of reach to date because of the limitations of observers, such as nocturnal movements of diurnal primates (Isbell, Bidner, Crofoot, Matsumoto‐Oda, & Farine, ), complex spatial relationships within and among groups (Farine et al, ; Farine, Strandburg‐Peshkin, Couzin, Berger‐Wolf, & Crofoot, ; Markham, Alberts, & Altmann, ; Markham, Guttal, Alberts, & Altmann, ), and spatio–temporal interactions between primates and their predators (Bidner, Matsumoto‐Oda, & Isbell, ; Isbell & Bidner, ; Isbell, Bidner, Van Cleave, Matsumoto‐Oda, & Crofoot, ). Given the value of data obtained from GPS collars, more trapping and GPS collaring of primates will likely occur in the future.…”

Section: Introductionmentioning

confidence: 99%

Capture, immobilization, and Global Positioning System collaring of olive baboons (Papio anubis) and vervets (Chlorocebus pygerythrus): Lessons learned and suggested best practices

Isbell

Bidner

Paul

et al. 2019

Self Cite

As the value of Global Positioning System (GPS) technology in addressing primatological questions becomes more obvious, more studies will include capturing and collaring primates, with concomitant increased risk of adverse consequences to primate subjects. Here we detail our experiences in capturing, immobilizing, and placing GPS collars on six olive baboons (Papio anubis) in four groups and 12 vervet monkeys (Chlorocebus pygerythrus) in five groups in Kenya. We captured baboons with cage traps and vervets with box traps, immobilized them, and attached GPS collars that were to be worn for 1 year. Adverse consequences from the trapping effort included incidental death of two nonsubjects (an adult female and her dependent infant), temporary rectal prolapse in one baboon, superficial wounds on the crown of the head in two vervets, and failure to recapture/remove collars from two baboons and two vervets. Obvious negative effects from wearing collars were limited to abrasions around the neck of one vervet. A possible, and if so, serious, adverse effect was greater mortality for collared adult female vervets compared with known uncollared adult female vervets, largely due to leopard (Panthera pardus) predation.Collared animals could be more vulnerable to predation because trapping favors bolder individuals, who may also be more vulnerable to predation, or because collars could slow them down or make them more noticeable to predators. Along with recommendations made by others, we suggest that future studies diversify trapping bait to minimize the risk of rectal prolapse, avoid capturing the first individuals to enter traps, test the movement speeds of collared versus noncollared animals, include a release system on the collars to avoid retrapping failure, and publish both positive and negative effects of capturing, immobilizing, and collaring.

“…Selection of a suitable sleeping site is, therefore, of the utmost importance in terms of energy preservation, but also may influence individual survival rates (Zhang, Li, Watanabe, & Qi, ). Although antipredator behaviors have been documented as the main factor affecting sleeping site choice in many primate species (Anderson, ; Bidner, Matsumoto‐Oda, & Isbell, ; Fan & Jiang, ; Fei, Zhang, Yuan, Zhang, & Fan, ; Reichard, ; Savagian & Fernandez‐Duque, ), thermoregulation has also been proven to influence sleeping behaviors, which is especially true for those species found in cold, seasonal habitats (Li et al, ; Savagian & Fernandez‐Duque, ; Xiang et al, ). First, primates in temperate habitats often enter sleeping sites earlier in the day (e.g., Trachypithecus francoisi ; Zhou, Huang, Li, & Wei, ) or leave the sleeping site much later when temperatures are low (e.g., Rhinopithecus brelichi , Xiang et al, ), thus prolonging the amount of time spent sleeping.…”

Section: Introductionmentioning

confidence: 99%

Effects of cold weather on the sleeping behavior of Skywalker hoolock gibbons (Hoolock tianxing) in seasonal montane forest

Fei

Thompson

Fan

2019

Considering the high energetic costs of maintaining constant body temperature, mammals must adjust their thermoregulatory behaviors in response to cold temperatures. Although primate daytime thermoregulation is relatively well studied, there is limited research in relation to nighttime strategies. To investigate how Skywalker hoolock gibbons (Hoolock tianxing) cope with the low temperatures found in montane forests, we collected sleep-related behavior data from one group (NA) and a single female (NB) at Nankang (characterized by extensive tsaoko plantations) with temperatures dropping below −2.0°C at both sites, making them the coldest known gibbon habitats. The lowest temperatures at both sites remained below 5.0°C from November to March, which we, therefore, defined as the "cold season". The hoolock gibbons remained in their sleeping trees for longer periods during the cold season compared to the warm season. Sleeping trees found at lower elevations and closer to potential feeding trees were favored during cold seasons at both sites. In addition, the gibbons were more likely to huddle together during cold seasons. Our results suggest that cold temperatures have a significant effect on the sleeping behavior of the Skywalker hoolock gibbon, highlighting the adaptability of this threatened species in response to cold climates. K E Y W O R D Shoolock tianxing, huddle, microclimate, montane forest, thermoregulation