A unifying framework for the transient parasite dynamics of migratory hosts

A unifying framework for the transient parasite dynamics of migratory hosts

Migrations allow animals to track seasonal changes in resources, find mates, and avoid harsh climates, but these regular, long-distance movements also have implications for parasite dynamics and animal health. Migratory animals have been dubbed “superspreaders” of infection, but migration can also r...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS Vol. 117; no. 20; pp. 10897 - 10903
Main Authors: Peacock, Stephanie J., Krkošek, Martin, Lewis, Mark A., Molnár, Péter K.
Format: Journal Article
Language:English
Published: United States National Academy of Sciences 19-05-2020
Subjects:
Animal health
Animal migration
Animals
Biological Sciences
Climate
Climate effects
Culling
Disease hot spots
Health risks
Mortality
Movements
Parasites
Positive feedback
Seasonal variations
Stalling
Wildlife
Wildlife habitats
migration
host–parasite
wildlife health
population dynamics
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Summary:Migrations allow animals to track seasonal changes in resources, find mates, and avoid harsh climates, but these regular, long-distance movements also have implications for parasite dynamics and animal health. Migratory animals have been dubbed “superspreaders” of infection, but migration can also reduce parasite burdens within host populations via migratory escape from contaminated habitats and transmission hotspots, migratory recovery due to parasite mortality, and migratory culling of infected individuals. Here, we show that a single migratory host–macroparasite model can give rise to these different phenomena under different parametrizations, providing a unifying framework for a mechanistic understanding of the parasite dynamics of migratory animals. Importantly, our model includes the impact of parasite burden on host movement capability during migration, which can lead to “parasite-induced migratory stalling” due to a positive feedback between increasing parasite burdens and reduced movement. Our results provide general insight into the conditions leading to different health outcomes in migratory wildlife. Our approach lays the foundation for tactical models that can help understand, predict, and mitigate future changes of disease risk in migratory wildlife that may arise from shifting migratory patterns, loss of migratory behavior, or climate effects on parasite development, mortality, and transmission.
Bibliography:Edited by Nils Chr. Stenseth, University of Oslo, Oslo, Norway, and approved March 19, 2020 (received for review May 22, 2019)
Author contributions: S.J.P., M.K., M.A.L., and P.K.M. designed research; S.J.P., M.A.L., and P.K.M. performed research; S.J.P., M.A.L., and P.K.M. analyzed data; and S.J.P., M.K., M.A.L., and P.K.M. wrote the paper.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1908777117