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Fractionation of sulfur and hydrogen isotopes inDesulfovibrio vulgariswith perturbed DsrC expression
Author(s) -
William D. Leavitt,
Sofia S. Venceslau,
Inês A. C. Pereira,
David T. Johnston,
Alexander S. Bradley
Publication year - 2016
Publication title -
fems microbiology letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.899
H-Index - 151
eISSN - 1574-6968
pISSN - 0378-1097
DOI - 10.1093/femsle/fnw226
Subject(s) - sulfur , sulfate , desulfovibrio vulgaris , chemistry , biogeochemical cycle , isotope fractionation , fractionation , desulfovibrio , sulfur metabolism , hydrogen sulfide , isotope , sulfide , biochemistry , environmental chemistry , biology , chromatography , bacteria , organic chemistry , genetics , physics , quantum mechanics
Dissimilatory sulfate reduction is the central microbial metabolism in global sulfur cycling. Understanding the importance of sulfate reduction to Earth's biogeochemical S cycle requires aggregating single-cell processes with geochemical signals. For sulfate reduction, these signals include the ratio of stable sulfur isotopes preserved in minerals, as well as the hydrogen isotope ratios and structures of microbial membrane lipids preserved in organic matter. In this study, we cultivated the model sulfate reducer, Desulfovibrio vulgaris DSM 644 T , to investigate how these parameters were perturbed by changes in expression of the protein DsrC. DsrC is critical to the final metabolic step in sulfate reduction to sulfide. S and H isotopic fractionation imposed by the wild type was compared to three mutants. Discrimination agains 34 S in sulfate, as calculated from the residual reactant, did not discernibly differ among all strains. However, a closed-system sulfur isotope distillation model, based on accumulated sulfide, produced inconsistent results in one mutant strain IPFG09. Lipids produced by IPFG09 were also slightly enriched in 2 H. These results suggest that DsrC alone does not have a major impact on sulfate-S, though may influence sulfide-S and lipid-H isotopic compositions. While intriguing, a mechanistic explanation requires further study under continuous culture conditions.

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