Abstract
Many species are shifting their ranges in response to climate-driven environmental changes, particularly in high-latitude regions. However, the patterns of dispersal and colonization during range shifting events are not always clear. Understanding how populations are connected through space and time can reveal how species navigate a changing environment. Here, we present a fine-scale population genomics study of gentoo penguins (Pygoscelis papua), a presumed site-faithful colonial nesting species that has increased in population size and expanded its range south along the Western Antarctic Peninsula. Using whole genome sequencing, we analysed 129 gentoo penguin individuals across 12 colonies located at or near the southern range edge. Through a detailed examination of fine-scale population structure, admixture, and population divergence, we inferred that gentoo penguins historically dispersed rapidly in a stepping-stone pattern from the South Shetland Islands leading to the colonization of Anvers Island, and then the adjacent mainland Western Antarctica Peninsula. Recent southward expansion along the Western Antarctic Peninsula also followed a stepping-stone dispersal pattern coupled with limited post-divergence gene flow from colonies on Anvers Island. Genetic diversity appeared to be maintained across colonies during the historical dispersal process, and range-edge populations are still growing. This suggests large numbers of migrants may provide a buffer against founder effects at the beginning of colonization events to maintain genetic diversity similar to that of the source populations before migration ceases post-divergence. These results coupled with a continued increase in effective population size since approximately 500–800 years ago distinguish gentoo penguins as a robust species that is highly adaptable and resilient to changing climate.
Original language | English |
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Article number | e17282 |
Journal | Molecular Ecology |
Volume | 33 |
Issue number | 6 |
Early online date | 1 Feb 2024 |
DOIs | |
Publication status | Published - 6 Mar 2024 |
Funding
We gratefully acknowledge National Geographic Lindblad Expeditions, Hurtigruten Expeditions, Skip Novak and Pelagic Expeditions, and the crew of the Vinson of Antarctica (Alec Hazel, Kenneth Perigón, and Jose Gritti) for providing logistical support for fieldwork in Antarctica. We thank Kerry Reid for providing wet lab training and guidance, and Irby Lovette and Jacob Cooper for their assistance in the field. We acknowledge Stony Brook University's SeaWulf supercomputing resources ( https://it.stonybrook.edu/services/high‐performance‐computing ) made available for conducting the research reported in this paper. We thank Ron Naveen at Oceanites for providing permitting and funding for sample collection during the 2019/2020 field season (Antarctic Conservation Act Permit No. 2019‐0001). Sampling during the 2021/2022 season was permitted through the UK Foreign and Commonwealth Office (Permit No. 20‐2021‐22). This work was funded by NASA FINESST Grant Award No. 80NSSC20K1605, the Stony Brook University Faculty‐Staff Dissertation Fellowship, the Institute for Advanced Computational Sciences Endowment for Ecology & Evolution, the National Geographic Society, and the Field Museum's Robert A. Pritzker Center of Meteoritics and Polar Studies.
Funders | Funder number |
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Field Museum's Robert A. Pritzker Center of Meteoritics and Polar Studies | |
Imperial College London | |
National Aeronautics and Space Administration | 80NSSC20K1605 |
National Geographic Society | |
Stony Brook University |
Keywords
- colonization
- founder effects
- range expansion
- seabirds
- stepping-stone dispersal
- whole genome sequencing
ASJC Scopus subject areas
- Ecology, Evolution, Behavior and Systematics
- Genetics