Bolstering fitness via CO2 fixation and organic carbon uptake: mixotrophs in modern groundwater

Taubert M, Overholt WA, Heinze BM, Matanfack GA, Houhou R, Jehmlich N, Von Bergen M, Roesch P, Popp J, Kuesel K (2022)

Publication Type: Journal article

Publication year: 2022

Journal

Isme Journal Nature Publishing Group: Open Access Hybrid Model Option B

Book Volume: 16

Pages Range: 1153-1162

Journal Issue: 4

DOI: 10.1038/s41396-021-01163-x

Abstract

Current understanding of organic carbon inputs into ecosystems lacking photosynthetic primary production is predicated on data and inferences derived almost entirely from metagenomic analyses. The elevated abundances of putative chemolithoautotrophs in groundwaters suggest that dark CO2 fixation is an integral component of subsurface trophic webs. To understand the impact of autotrophically fixed carbon, the flux of CO2-derived carbon through various populations of subsurface microbiota must first be resolved, both quantitatively and temporally. Here we implement novel Stable Isotope Cluster Analysis to render a time-resolved and quantitative evaluation of 13CO2-derived carbon flow through a groundwater community in microcosms stimulated with reduced sulfur compounds. We demonstrate that mixotrophs, not strict autotrophs, were the most abundant active organisms in groundwater microcosms. Species of Hydrogenophaga, Polaromonas, Dechloromonas, and other metabolically versatile mixotrophs drove the production and remineralization of organic carbon. Their activity facilitated the replacement of 43% and 80% of total microbial carbon stores in the groundwater microcosms with 13C in just 21 and 70 days, respectively. The mixotrophs employed different strategies for satisfying their carbon requirements by balancing CO2 fixation and uptake of available organic compounds. These different strategies might provide fitness under nutrient-limited conditions, explaining the great abundances of mixotrophs in other oligotrophic habitats, such as the upper ocean and boreal lakes.

Involved external institutions

Friedrich-Schiller-Universität Jena DE Germany (DE) Helmholtz-Zentrum für Umweltforschung (UFZ) / Helmholtz Center for Environmental Research DE Germany (DE)

How to cite

APA:

Taubert, M., Overholt, W.A., Heinze, B.M., Matanfack, G.A., Houhou, R., Jehmlich, N.,... Kuesel, K. (2022). Bolstering fitness via CO2 fixation and organic carbon uptake: mixotrophs in modern groundwater. Isme Journal, 16(4), 1153-1162. https://dx.doi.org/10.1038/s41396-021-01163-x

MLA:

Taubert, Martin, et al. "Bolstering fitness via CO2 fixation and organic carbon uptake: mixotrophs in modern groundwater." Isme Journal 16.4 (2022): 1153-1162.

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