Flight feather moult drives minimum daily heart rate in wild geese

Portugal, Steven J, White, Craig R, Green, Jonathan A ORCID: 0000-0001-8692-0163 and Butler, Patrick J
(2018) Flight feather moult drives minimum daily heart rate in wild geese. BIOLOGY LETTERS, 14 (11). 20180650-.

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Waterfowl undergo an annual simultaneous flight-feather moult that renders them flightless for the duration of the regrowth of the flight feathers. In the wild, this period of flightlessness could restrict the capacity of moulting birds to forage and escape predation. Selection might therefore favour a short moult, but feather growth is constrained and presumably energetically demanding. We therefore tested the hypothesis that for birds that undergo a simultaneous flight-feather moult, this would be the period in the annual cycle with the highest minimum daily heart rates, reflecting these increased energetic demands. Implantable heart rate data loggers were used to record year-round heart rate in six wild barnacle geese (<i>Branta leucopsis</i>), a species that undergoes a simultaneous flight-feather moult. The mean minimum daily heart rate was calculated for each individual bird over an 11-month period, and the annual cycle was divided into seasons based on the life-history of the birds. Mean minimum daily heart rate varied significantly between seasons and was significantly elevated during wing moult, to 200 ± 32 beats min<sup>-1</sup>, compared to all other seasons of the annual cycle, including both the spring and autumn migrations. The increase in minimum daily heart rate during moult is likely due to feather synthesis, thermoregulation and the reallocation of minerals and protein.

Item Type: Article
Uncontrolled Keywords: avian, energetics, metabolic rate
Depositing User: Symplectic Admin
Date Deposited: 13 Feb 2019 11:38
Last Modified: 24 Jan 2024 16:56
DOI: 10.1098/rsbl.2018.0650
Related URLs:
URI: https://livrepository.liverpool.ac.uk/id/eprint/3032775