Environmental conditions during breeding modify the strength of mass-dependent carry-over effects in a migratory bird.

In many animals, processes occurring in one season carry over to influence reproductive success and survival in future seasons. The strength of such carry-over effects is unlikely to be uniform across years, yet our understanding of the processes that are capable of modifying their strength remains...

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Bibliographic Details
Published in:PLoS ONE
Main Authors: Xavier A Harrison, David J Hodgson, Richard Inger, Kendrew Colhoun, Gudmundur A Gudmundsson, Graham McElwaine, Tom Tregenza, Stuart Bearhop
Format: Article in Journal/Newspaper
Language:English
Published: Public Library of Science (PLoS) 2013
Subjects:
Medicine
R
Science
Q
brent geese
Online Access:https://doi.org/10.1371/journal.pone.0077783
https://doaj.org/article/854ae0e50d7c4ac499bef252dc451506
Description
Summary:In many animals, processes occurring in one season carry over to influence reproductive success and survival in future seasons. The strength of such carry-over effects is unlikely to be uniform across years, yet our understanding of the processes that are capable of modifying their strength remains limited. Here we show that female light-bellied Brent geese with higher body mass prior to spring migration successfully reared more offspring during breeding, but only in years where environmental conditions during breeding were favourable. In years of bad weather during breeding, all birds suffered reduced reproductive output irrespective of pre-migration mass. Our results suggest that the magnitude of reproductive benefits gained by maximising body stores to fuel breeding fluctuates markedly among years in concert with conditions during the breeding season, as does the degree to which carry-over effects are capable of driving variance in reproductive success among individuals. Therefore while carry-over effects have considerable power to drive fitness asymmetries among individuals, our ability to interpret these effects in terms of their implications for population dynamics is dependent on knowledge of fitness determinants occurring in subsequent seasons.

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