Transition to density dependence in a reintroduced ecosystem engineer
Manning, Adrian D., Evans, Maldwyn J., Banks, Sam C., Batson, William G., Belton, Emily, Crisp, Helen A., Fletcher, Donald B., Gordon, Iain J., Grarock, Kate, Munro, Nicki, Newport, Jenny, Pierson, Jennifer, Portas, Timothy J., Snape, Melissa A., and Wimpenny, Claire (2019) Transition to density dependence in a reintroduced ecosystem engineer. Biodiversity and Conservation, 28 (14). pp. 3803-3830.
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Abstract
When does a reintroduced population of animals become self-regulating? Quantifying this is critical in determining when interventions can be tapered off, or when they may need to be reinstated. We tracked the growth trajectory of a reintroduced population to establish whether it was irruptive and/or had transitioned to self-regulation. In 2012, we reintroduced 32 eastern bettongs (Bettongia gaimardi), a potoroid marsupial from Tasmania, Australia, to a 485 ha exotic predator-proof fenced reserve in the Australian Capital Territory. We established a 92 cage trap monitoring network to track population growth between the Austral Autumn 2014 and Summer 2018. We used capture-recapture models to track changes in the population through time, and modelled 'bettong weight', 'pouch occupancy' and 'age of pouch young' with population variation, to establish potential associations with changes in population size. The estimated population grew from 32 individuals in 2012 to 100 in 2014, 192 in Autumn 2016, and then declined to 151 in Summer 2018. Estimated survival of adults was high-above 92% between most sessions. Adult female weights ranged between 0.485 and 2.428 kg, and adult males between 0.470 and 2.775 kg. Our study showed density dependence was achieved over the 6 year period. Low adult mortality, and variable pouch occupancy related to female weight, suggested that food availability had influenced lactation in females, with flow-on impacts on juvenile survival. Long-term, broad-scale population dynamics were probably driven by a mix of direct (e.g. disease, harvesting for other reintroductions), and indirect (i.e. climate dependent availability of nutritious food) influences on population size.
Item ID: | 61072 |
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Item Type: | Article (Research - C1) |
ISSN: | 1572-9710 |
Keywords: | Australia, Bettongia gaimardi, Density dependence, Marsupial, Reintroduction, Self-regulation |
Copyright Information: | © Springer Nature B.V. 2019. |
Funders: | Australian Research Council (ARC) |
Projects and Grants: | ARC Linkage Grant (LP110100126), ARC Future Fellowship (FT100100358) |
Date Deposited: | 27 Nov 2019 07:31 |
FoR Codes: | 41 ENVIRONMENTAL SCIENCES > 4104 Environmental management > 410401 Conservation and biodiversity @ 100% |
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