Density-dependent reproduction causes winter crashes in a common vole population

Common voles in western France exhibit three-year population cycles with winter crashes after large outbreaks. During the winter of 2011–2012, we monitored survival, reproduction, recruitment and population growth rate of common voles at different densities (from low to outbreak densities) in natu...

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Bibliographic Details
Published in:Population ecology 2016-07, Vol.58 (3), p.395-405
Main Authors: Pinot, Adrien, Frédéric Barraquand, Edoardo Tedesco, Vincent Lecoustre, Vincent Bretagnolle, Bertrand Gauffre
Format: Article
Language:English
Subjects:
adverse effects
Animal populations
animals
Behavioral Sciences
Biomedical and Life Sciences
CMR
Density
Density dependence
Ecology
Environmental conditions
Environmental Sciences
Evolutionary Biology
Forestry
Hypotheses
Life cycles
Life Sciences
Microtus arvalis
Mortality
Original Article
Outbreaks
Plant Sciences
Population cycles
Population growth
Recruitment
reproduction
Rodents
species recruitment
Survival
Winter
Zoology
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Summary:Common voles in western France exhibit three-year population cycles with winter crashes after large outbreaks. During the winter of 2011–2012, we monitored survival, reproduction, recruitment and population growth rate of common voles at different densities (from low to outbreak densities) in natura to better understand density dependence of demographic parameters. Between October and April, the number of animals decreased irrespective of initial density. However, the decline was more pronounced when October density was higher (loss of ≈54 % of individuals at low density and 95 % at high density). Using capture-mark-recapture models with Pradel’s temporal symmetry approach, we found a negative effect of density on recruitment and reproduction. In contrast, density had a slightly positive effect on survival indicating that mortality did not drive the steeper declines in animal numbers at high density. We discuss these results in a population cycle framework, and suggest that crashes after outbreaks could reflect negative effects of density dependence on reproduction rather than changes in mortality rates.
ISSN:1438-3896
1438-390X
DOI:10.1007/s10144-016-0552-3