TY - JOUR
T1 - Assessing global patterns in mammalian carnivore occupancy and richness by integrating local camera trap surveys
AU - Rich, Lindsey N.
AU - Davis, Courtney L.
AU - Farris, Zach J.
AU - Miller, David A.W.
AU - Tucker, Jody M.
AU - Hamel, Sandra
AU - Farhadinia, Mohammad S.
AU - Steenweg, Robin
AU - Di Bitetti, Mario S.
AU - Thapa, Kanchan
AU - Kane, Mamadou D.
AU - Sunarto, S.
AU - Robinson, Nathaniel P.
AU - Paviolo, Agustín
AU - Cruz, Paula
AU - Martins, Quinton
AU - Gholikhani, Navid
AU - Taktehrani, Ateih
AU - Whittington, Jesse
AU - Widodo, Febri A.
AU - Yoccoz, Nigel G.
AU - Wultsch, Claudia
AU - Harmsen, Bart J.
AU - Kelly, Marcella J.
N1 - Publisher Copyright:
© 2017 John Wiley & Sons Ltd
PY - 2017/8
Y1 - 2017/8
N2 - Aim: Biodiversity loss is a major driver of ecosystem change, yet the ecological data required to detect and mitigate losses are often lacking. Recently, camera trap surveys have been suggested as a method for sampling local wildlife communities, because these observations can be collated into a global monitoring network. To demonstrate the potential of camera traps for global monitoring, we assembled data from multiple local camera trap surveys to evaluate the interchange between fine- and broad-scale processes impacting mammalian carnivore communities. Location: Argentina, Belize, Botswana, Canada, Indonesia, Iran, Madagascar, Nepal, Norway, Senegal, South Africa, and the U.S.A. Methods: We gathered camera trap data, totalling > 100,000 trap nights, from across five continents. To analyse local and species-specific responses to anthropogenic and environmental variables, we fitted multispecies occurrence models to each study area. To analyse global-level responses, we then fitted a multispecies, multi-area occurrence model. Results: We recorded 4,805 detections of 96 mammalian carnivore species photographed across 1,714 camera stations located in 12 countries. At the global level, our models revealed that carnivore richness and occupancy within study areas was positively associated with prey availability. Occupancy within study areas also tended to increase with greater protection and greater distances to roads. The strength of these relationships, however, differed among countries. Main conclusions: We developed a research framework for leveraging global camera trap data to evaluate patterns of mammalian carnivore occurrence and richness across multiple spatial scales. Our research highlights the importance of intact prey populations and protected areas in conserving carnivore communities. Our research also highlights the potential of camera traps for monitoring wildlife communities and provides a case study for how this can be achieved on a global scale. We encourage greater integration and standardization among camera trap studies worldwide, which would help inform effective conservation planning for wildlife populations both locally and globally.
AB - Aim: Biodiversity loss is a major driver of ecosystem change, yet the ecological data required to detect and mitigate losses are often lacking. Recently, camera trap surveys have been suggested as a method for sampling local wildlife communities, because these observations can be collated into a global monitoring network. To demonstrate the potential of camera traps for global monitoring, we assembled data from multiple local camera trap surveys to evaluate the interchange between fine- and broad-scale processes impacting mammalian carnivore communities. Location: Argentina, Belize, Botswana, Canada, Indonesia, Iran, Madagascar, Nepal, Norway, Senegal, South Africa, and the U.S.A. Methods: We gathered camera trap data, totalling > 100,000 trap nights, from across five continents. To analyse local and species-specific responses to anthropogenic and environmental variables, we fitted multispecies occurrence models to each study area. To analyse global-level responses, we then fitted a multispecies, multi-area occurrence model. Results: We recorded 4,805 detections of 96 mammalian carnivore species photographed across 1,714 camera stations located in 12 countries. At the global level, our models revealed that carnivore richness and occupancy within study areas was positively associated with prey availability. Occupancy within study areas also tended to increase with greater protection and greater distances to roads. The strength of these relationships, however, differed among countries. Main conclusions: We developed a research framework for leveraging global camera trap data to evaluate patterns of mammalian carnivore occurrence and richness across multiple spatial scales. Our research highlights the importance of intact prey populations and protected areas in conserving carnivore communities. Our research also highlights the potential of camera traps for monitoring wildlife communities and provides a case study for how this can be achieved on a global scale. We encourage greater integration and standardization among camera trap studies worldwide, which would help inform effective conservation planning for wildlife populations both locally and globally.
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U2 - 10.1111/geb.12600
DO - 10.1111/geb.12600
M3 - Article
AN - SCOPUS:85021204783
SN - 1466-822X
VL - 26
SP - 918
EP - 929
JO - Global Ecology and Biogeography
JF - Global Ecology and Biogeography
IS - 8
ER -