Flyway connectivity and exchange primarily driven by moult migration in geese

A. Kölzsch; G. J. D. M. Müskens; P. Szinai; S. Moonen; P. Glazov; H. Kruckenberg; M. Wikelski; B. A. Nolet

doi:10.1186/s40462-019-0148-6

Movement Ecology (Jan 2019)

Flyway connectivity and exchange primarily driven by moult migration in geese

A. Kölzsch,
G. J. D. M. Müskens,
P. Szinai,
S. Moonen,
P. Glazov,
H. Kruckenberg,
M. Wikelski,
B. A. Nolet

Affiliations

A. Kölzsch: Department of Migration and Immuno-Ecology, Max Planck Institute for Ornithology
G. J. D. M. Müskens: Team Animal Ecology, Wageningen Environmental Research, Wageningen University & Research
P. Szinai: Balaton-felvidéki National Park Directorate
S. Moonen: Institute of Avian Research
P. Glazov: Institute of Geography, Russian Academy of Sciences
H. Kruckenberg: Institute for Wetlands and Waterbird Research e.V
M. Wikelski: Department of Migration and Immuno-Ecology, Max Planck Institute for Ornithology
B. A. Nolet: Department of Animal Ecology, Netherlands Institute of Ecology (NIOO-KNAW)

DOI: https://doi.org/10.1186/s40462-019-0148-6
Journal volume & issue: Vol. 7, no. 1
pp. 1 – 11

Abstract

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Abstract Background For the conservation and management of migratory species that strongly decrease or increase due to anthropological impacts, a clear delineation of populations and quantification of possible mixing (migratory connectivity) is crucial. Usually, population exchange in migratory species is only studied in breeding or wintering sites, but we considered the whole annual cycle in order to determine important stages and sites for population mixing in an Arctic migrant. Methods We used 91 high resolution GPS tracks of Western Palearctic greater white-fronted geese (Anser A. albifrons) from the North Sea and Pannonic populations to extract details of where and when populations overlapped and exchange was possible. Overlap areas were calculated as dynamic Brownian bridges of stopover, nest and moulting sites. Results Utilisation areas of the two populations overlapped only somewhat during spring and autumn migration stopovers, but much during moult. During this stage, non-breeders and failed breeders of the North Sea population intermixed with geese from the Pannonic population in the Pyasina delta on Taimyr peninsula. The timing of use of overlap areas was highly consistent between populations, making exchange possible. Two of our tracked geese switched from the North Sea population flyway to the Pannonic flyway during moult on Taimyr peninsula or early during the subsequent autumn migration. Because we could follow one of them during the next year, where it stayed in the Pannonic flyway, we suggest that the exchange was long-term or permanent. Conclusions We have identified long-distance moult migration of failed or non-breeders as a key phenomenon creating overlap between two flyway populations of geese. This supports the notion of previously suggested population exchange and migratory connectivity, but outside of classically suggested wintering or breeding sites. Our results call for consideration of moult migration and population exchange in conservation and management of our greater white-fronted geese as well as other waterfowl populations.

Published in Movement Ecology

ISSN: 2051-3933 (Online)
Publisher: BMC
Country of publisher: United Kingdom
LCC subjects: Science: Biology (General)
Website: https://movementecologyjournal.biomedcentral.com

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