Covariation of hot spring geochemistry with microbial genomic diversity, function, and evolution

Colman, Daniel R.; Keller, Lisa M.; Arteaga-Pozo, Emilia; Andrade-Barahona, Eva; Clair, Brian; Shoemaker, Anna; Cox, Alysia; Boyd, Eric S.

Covariation of hot spring geochemistry with microbial genomic diversity, function, and evolution

Daniel R. Colman (), Lisa M. Keller, Emilia Arteaga-Pozo, Eva Andrade-Barahona, Brian Clair, Anna Shoemaker, Alysia Cox and Eric S. Boyd ()
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Daniel R. Colman: Montana State University
Lisa M. Keller: Montana State University
Emilia Arteaga-Pozo: Montana Technological University
Eva Andrade-Barahona: Montana Technological University
Brian Clair: Montana Technological University
Anna Shoemaker: Montana State University
Alysia Cox: Montana Technological University
Eric S. Boyd: Montana State University

Nature Communications, 2024, vol. 15, issue 1, 1-22

Abstract: Abstract The geosphere and the microbial biosphere have co-evolved for ~3.8 Ga, with many lines of evidence suggesting a hydrothermal habitat for life’s origin. However, the extent that contemporary thermophiles and their hydrothermal habitats reflect those that likely existed on early Earth remains unknown. To address this knowledge gap, 64 geochemical analytes were measured and 1022 metagenome-assembled-genomes (MAGs) were generated from 34 chemosynthetic high-temperature springs in Yellowstone National Park and analysed alongside 444 MAGs from 35 published metagenomes. We used these data to evaluate co-variation in MAG taxonomy, metabolism, and phylogeny as a function of hot spring geochemistry. We found that cohorts of MAGs and their functions are discretely distributed across pH gradients that reflect different geochemical provinces. Acidic or circumneutral/alkaline springs harbor MAGs that branched later and are enriched in sulfur- and arsenic-based O2-dependent metabolic pathways that are inconsistent with early Earth conditions. In contrast, moderately acidic springs sourced by volcanic gas harbor earlier-branching MAGs that are enriched in anaerobic, gas-dependent metabolisms (e.g. H2, CO2, CH4 metabolism) that have been hypothesized to support early microbial life. Our results provide insight into the influence of redox state in the eco-evolutionary feedbacks between thermophiles and their habitats and suggest moderately acidic springs as early Earth analogs.

Date: 2024
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DOI: 10.1038/s41467-024-51841-5

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