Abstract
Both mass (as a measure of body reserves) during breeding and adult survival should reflect variation in food availability. Those species that are adapted to less seasonally variable foraging niches and so where competition dominates during breeding, will tend to have a higher mass increase via an interrupted foraging response, because their foraging demands increase and so become more unpredictable. They will then produce few offspring per breeding attempt, but trade this off with higher adult survival. In contrast, those species that occupy a more seasonal niche will not gain mass because foraging remains predictable, as resources become superabundant during breeding. They can also produce more offspring per breeding attempt, but with a trade-off with reduced adult survival. We tested whether the then predicted positive correlation between levels of mass gained during seasonal breeding and adult survival was present across 40 species of tropical bird measured over a 10-year period in a West African savannah. We showed that species with a greater seasonal mass increase had higher adult survival, controlling for annual mass variation (i.e. annual variation in absolute food availability) and variation in the timing of peak mass (i.e. annual predictability of food availability), clutch size, body size, migratory status and phylogeny. Our results support the hypothesis that the degree of seasonal mass variation in birds is probably an indication of life history adaptation: across tropical bird species it may therefore be possible to use mass gain during breeding as an index of adult survival.
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Acknowledgments
We would like to thank the A. P. Leventis Ornithological Research Institute for logistical support, and the many ringers who have contributed over the years to this long-term dataset. Thank you to the Leventis Conservation Foundation for funding this study. This is publication no. 72 from the A. P. Leventis Ornithological Research Institute.
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Communicated by Ola Olsson.
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Cox, D.T.C., Cresswell, W. Mass gained during breeding positively correlates with adult survival because both reflect life history adaptation to seasonal food availability. Oecologia 174, 1197–1204 (2014). https://doi.org/10.1007/s00442-013-2859-5
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DOI: https://doi.org/10.1007/s00442-013-2859-5