Abstract
Understanding species interactions and their effects on distributions is crucial for assessing the impacts of global change, particularly for invasive species. Co-occurrence models can help investigate these effects when interactions are likely given shared traits. For such an assemblage of invasive and native carnivorans, we examined how patterns of co-occurrence change across space and environmental gradients using a static multispecies occupancy model that accounts for imperfect detectability and models co-occurrence as a function of environmental variables, and also extended it to be temporally dynamic. We focused on invasive raccoons, which pose threats to humans and wildlife globally. In Japan, raccoons prey on many native taxa, but little is known about interactions with sympatric carnivorans. We searched for signals of competitive exclusion of native raccoon dogs (tanuki) and invasive masked palm civets by applying the model to detection data from a broad-scale trapping effort over 6 years. Forest cover was the strongest predictor of occupancy for individual species and raccoon co-occurrences, and raccoon occupancy probability increased with forest cover conditionally depending on the co-occurring carnivoran: only tanuki absence or civet presence had positive responses. However, tanuki occupancy probability increased with forest cover despite any co-occurrence. Thus, we found no evidence of competitive exclusion by raccoons, contrary to our expectations. As parts of the world with invasive raccoons can also have invasive tanuki, our findings may have broad management implications. The model we present should be useful for inferring signals of biotic interactions between species with low detectability over multi-year time frames.
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Data accessibility
The detection data used in this study are archived in the Knowledge Network for Biocomplexity repository (https://doi.org/10.5063/F1X34VS1).
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Acknowledgements
JMK and FK conceived the idea, TT supplied the data and helped with its interpretation and formatting, JMK and MWT conducted the analysis, and JMK drafted the manuscript which MWT and FK helped critically revise. All authors approved the final version for publication. This material is based upon work jointly supported by the National Science Foundation under Grant No. OISE-1614083 and the Japan Society for the Promotion of Science through an International Research Fellowship at the Graduate School of Environment and Information Sciences, Yokohama National University (2016). The authors have no conflict of interest to declare. We would like to thank the Kanagawa-ken Department of Environmental and Agricultural Administration for their assistance in acquiring the raccoon trapping dataset. We would also like to especially thank members of the Koike lab and Mieko Kawamichi for field experience and help with framing the initial ideas, Christopher Rota for methodological assistance, and Robert P. Anderson, Gonzalo Pinilla-Buitrago, Sarah Meenan, and Andrea Paz for valuable suggestions that helped considerably improve the manuscript.
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Kass, J.M., Tingley, M.W., Tetsuya, T. et al. Co-occurrence of invasive and native carnivorans affects occupancy patterns across environmental gradients. Biol Invasions 22, 2251–2266 (2020). https://doi.org/10.1007/s10530-020-02254-0
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DOI: https://doi.org/10.1007/s10530-020-02254-0