replying to A. A. Campos et al. Nature Communications https://doi.org/10.1038/s41467-022-31381-6 (2022)
A Matters Arising article raised concerns about the interpretation of our findings reported in our recent publication on the Steller’s sea cow (Hydrodamalis gigas) nuclear genome1. After careful consideration of the criticism, we maintain our main conclusion that this marine mammal started to become extinct at a period significantly preceding the arrival the first Paleolithic humans in the Bering Sea region. This conclusion is supported not only by genomic analysis but also by the small number of Steller’s sea cow bones that were excavated in prehistorical archeological sites along the North Pacific coast line2,3,4,5.
We suppose that extinct the Steller’s sea cow could migrate significant distances along the coastline and between islands (including Aleutian and Commander Islands) in the same way as the extant sirenian species: the dugong (Dugong dugon)6 and the West Indian manatee (Trichechus manatus)7. Although Steller’s sea cow was likely unable to swim across large distances it could conquer new island habitats due to the westward Alaskan current that flows along the south side of the Alaska Peninsula and the Aleutian Islands8 and enters the Bering Sea through several Aleutian passes, and then forms the Aleutian North Slope current that flows into the East Kamchatka current (Fig. 1)9. Moreover, this sea current configuration has existed since at least the Middle Pleistocene despite glaciations and the Bering Sea level drop9.
Thus, the Alaskan stream could allow in a constant westward gene flow among the H. gigas populations of Alaska and the Aleutian and the Commander Islands, which, at the current time, is the case for northern fur seals’ (Callorhinus ursinus) early migrations. Fur seal pups born on St. Paul Island usually migrate westward without being able to dive deeply, feed or navigate10.
Sea otter hunting (Enhydra lutris) was one of the possible indirect reasons for the extinction of the last H. gigas population on the Commander Islands. Some think that fur traders used Steller’s sea cows as a source of meat and fat2; others propose that overhunting of the sea otter influenced local ecological food chains and led to the loss of kelp forests and to the parallel extinction of the last H. gigas population, which lost its feeding source11. Nevertheless, sea otters (strong swimmers and divers) survived as a species after this “fur trade fever” with the repeated loss of genetic diversity along the North Pacific Ocean. Moreover, the gene flow between the islands and the mainland populations still remains12. It is also suggested that the extinction of Steller’s sea cow in the North Pacific region had a significant impact on kelp forests and ecosystem dynamics in general13.
Modern data on the genetic diversity of another, and genetically closest, sirenian species, the dugong, showed low genetic diversity levels in the Indian and the Pacific Ocean populations and detected geographic structuring among them. Several mitochondrial lineages of this species have been described14. At the same time, these obtained mitochondrial DNA data present the migration possibilities for this species (predominantly by males) along the coastline of Africa, Asia, Australia, and possibly between parts of the Indonesian archipelago14,15.
In our study that described the first nuclear genome of H. gigas1, we did not propose a panmictic character of the population structure for the Steller’s sea cow in its distribution limits. However, it seems that gene flow between the Commander and Aleutian Islands H. gigas was possible until Last Glacial Maximum, which took place from 26.5 ka to 19 to 20 ka16. We suppose that much earlier glaciations and periods in between in this region could limit as well as enhance the gene flow of animal and plant species in the North Pacific Rim. Moreover, kelp forests have grown along the Aleutian–Commander Islands chain and further towards the Kuril Islands and Japan continuously.
In conclusion, we suggest that precise geological data on the Bering Sea level during the Pleistocene and additional H. gigas genomic datasets from individuals representing different periods and geographical localities will be necessary to determine the causes for the extinction of the Steller’s sea cow in the North Pacific region.
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All literature sources used in this article are available in the References list.
References
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Acknowledgements
The authors want to thank Prof. Jorge Galindo-Villegas for his valuable comments. The authors want to thank Anna Tikhonova for her valuable comments and English proofreading of this manuscript. The authors are also grateful to Anna A. Krasivskaya for her artistic talent. This study was completed within the framework of the Federal themes of the Zoological Institute no. АААА-А19-119032590102-7 “Phylogeny, morphology, and systematics of placental mammals”. The funders had no role in the study design, data collection and analysis, decision to publish, or preparation of the manuscript.
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F.S.S., S.M.R., A.N.T., and A.V.N. conceptualized the study; A.N.T. and A.V.N. sequred funding; F.S.S., S.M.R., A.N.T., and A.V.N. carried out investigation; A.N.T. and A.V.N. administrated study and project; A.N.T. and A.V.N. supervised study; A.V.N. was responsinble for visualization; A.V.N. wrote original draft; all authors participated in writing, review and editing.
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Sharko, F.S., Rastorguev, S.M., Tikhonov, A.N. et al. Reply to: “Steller’s sea cow uncertain history illustrates importance of ecological context when interpreting demographic histories from genomes”. Nat Commun 13, 3672 (2022). https://doi.org/10.1038/s41467-022-31382-5
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DOI: https://doi.org/10.1038/s41467-022-31382-5
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