Abstract
Recent advances in the application of molecular genetic approaches have emphasized our potentially huge underestimate of microbial diversity in a range of natural environments1. These approaches, however, give no direct information about the biogeochemical processes in which microorganisms are active2. Here we describe an approach to directly link specific environmental microbial processes with the organisms involved, based on the stable-carbon-isotope labelling of individual lipid biomarkers. We demonstrate this approach in aquatic sediments and provide evidence for the identity of the bacteria involved in two important biogeochemical processes: sulphate reduction coupled to acetate oxidation in estuarine and brackish sediments3,4, and methane oxidation in a freshwater sediment5. Our results suggest that acetate added in a 13C-labelled form was predominantly consumed by sulphate-reducing bacteria similar to the Gram-positive Desulfotomaculum acetoxidans and not by a population of the more widely studied Gram-negative Desulfobacter spp. Furthermore, 13C-methane labelling experiments suggest that type I methanotrophic bacteria dominate methane oxidation at the freshwater site.
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Acknowledgements
We thank H. J. Laanbroek, J. J. Middelburg and K. Perry for comments on earlier versions of the manuscript; L.-A. Meyer-Reil and M. Köster for their help at Rügen, Germany; and S.P.Barnes for the enrichment of acetate-using Desulfotomaculum from Tamar sediments. This work was supported by the European Union Environment Programme and the UK Natural Environmental Research Council.
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Boschker, H., Nold, S., Wellsbury, P. et al. Direct linking of microbial populations to specific biogeochemical processes by 13C-labelling of biomarkers. Nature 392, 801–805 (1998). https://doi.org/10.1038/33900
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DOI: https://doi.org/10.1038/33900
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