A global perspective on microbial diversity in the terrestrial deep subsurface
Autor: | Duane P. Moser, Sara M. E. Rassner, Andre Soares, Karen Budwill, Sean M. Caffrey, Lotta Purkamo, John W. Moreau, Magdalena R. Osburn, Malin Bomberg, Lily Momper, Alexandre Bagnoud, Andre Mu, Vitaly V. Kadnikov, Gerrit Voordouw, Cody S. Sheik, Jeffrey A. Gralnick, Brandy M. Toner, Andrew C. Mitchell, B. Sherwood Lollar, Matthew W. Fields, Katinka Wouters, Dongshan An, Arwyn Edwards |
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Rok vydání: | 2019 |
Předmět: |
0303 health sciences
geography Biomass (ecology) geography.geographical_feature_category biology 030306 microbiology Range (biology) Ecology Marine habitats Aquifer 15. Life on land biology.organism_classification 03 medical and health sciences Habitat 13. Climate action Metagenomics Gammaproteobacteria Environmental science 14. Life underwater Betaproteobacteria 030304 developmental biology |
Popis: | SummaryWhile recent efforts to catalogue Earth’s microbial diversity have focused upon surface and marine habitats, 12% to 20% of Earth’s bacterial and archaeal biomass is suggested to inhabit the terrestrial deep subsurface, compared to ∼1.8% in the deep subseafloor1–3. Metagenomic studies of the terrestrial deep subsurface have yielded a trove of divergent and functionally important microbiomes from a range of localities4–6. However, a wider perspective of microbial diversity and its relationship to environmental conditions within the terrestrial deep subsurface is still required. Here, we show the diversity of bacterial communities in deep subsurface groundwater is controlled by aquifer lithology globally, by using 16S rRNA gene datasets collected across five countries on two continents and from fifteen rock types over the past decade. Furthermore, our meta-analysis reveals that terrestrial deep subsurface microbiota are dominated by Betaproteobacteria, Gammaproteobacteria and Firmicutes, likely as a function of the diverse metabolic strategies of these taxa. Despite this similarity, evidence was found not only for aquifer-specific microbial communities, but also for a common small consortium of prevalent Betaproteobacteria and Gammaproteobacterial OTUs across the localities. This finding implies a core terrestrial deep subsurface community, irrespective of aquifer lithology, that may play an important role in colonising and sustaining microbial habitats in the deep terrestrial subsurface. Anin-silicocontamination-aware approach to analysing this dataset underscores the importance of downstream methods for assuring that robust conclusions can be reached from deep subsurface-derived sequencing data. Understanding the global panorama of microbial diversity and ecological dynamics in the deep terrestrial subsurface provides a first step towards understanding the role of microbes in global subsurface element and nutrient cycling. |
Databáze: | OpenAIRE |
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