Genetic isolation and metabolic complexity of an Antarctic subglacial microbiome

Kim, Kyung Mo; Hwang, Kyuin; Lee, Hanbyul; Cho, Ahnna; Davis, Christina L.; Christner, Brent C.; Priscu, John C.; Kim, Ok-Sun

Genetic isolation and metabolic complexity of an Antarctic subglacial microbiome

Kyung Mo Kim (), Kyuin Hwang, Hanbyul Lee, Ahnna Cho, Christina L. Davis, Brent C. Christner, John C. Priscu () and Ok-Sun Kim ()
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Kyung Mo Kim: Yeonsu-gu
Kyuin Hwang: Yeonsu-gu
Hanbyul Lee: Yeonsu-gu
Ahnna Cho: Yeonsu-gu
Christina L. Davis: University of Florida
Brent C. Christner: University of Florida
John C. Priscu: Montana State University
Ok-Sun Kim: Yeonsu-gu

Nature Communications, 2025, vol. 16, issue 1, 1-16

Abstract: Abstract Microbes inhabiting and evolving in aquatic ecosystems beneath polar ice sheets subsist under energy-limited conditions while in relative isolation from surface gene pools and their common ancestral populations of origin. Samples obtained from beneath West Antarctic Ice Sheet (WAIS) allowed us to examine evolutionary relationships of and identify metabolic pathways in microbial genomes recovered from the Mercer Subglacial Lake (SLM) ecosystem. We obtained 1,374 single-cell amplified genomes (SAGs) from individual bacterial and archaeal cells that were isolated from samples of SLM’s water column and sediments. These genomes reveal that a diversity of microorganisms including Patescibacteria exists in SLM. Comparative analyses show that most genomes correspond to new species and taxonomic groups, with phylogenomic and functional evidence supporting their genetic isolation from marine and surface biomes. Genomic data reveal diverse metabolisms in SLM that are capable of oxidizing organic and inorganic compounds via aerobic or anaerobic respiration. Distinct metabolic guild structures are observed for the subglacial populations, where trophic shifts from organotrophy to chemolithotrophy may depend on oxygen availability. Our SAG data suggest versatile metabolic capabilities in the characterized microbial assemblage, reveal key energy-generating strategies in the subglacial aquatic ecosystem, and provide a framework to assess microbial evolution beneath WAIS.

Date: 2025
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DOI: 10.1038/s41467-025-62753-3

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