Abstract
Dissimilatory sulfate reduction is a microbial energy metabolism that can produce sulfur isotopic fractionations over a large range in magnitude. Calibrating sulfur isotopic fractionation in laboratory experiments allows for better interpretations of sulfur isotopes in modern sediments and ancient sedimentary rocks. The proteins involved in sulfate reduction are expressed in response to environmental conditions, and are collectively responsible for the net isotopic fractionation between sulfate and sulfide. We examined the role of DsrC, a key component of the sulfate reduction pathway, by comparing wildtype Desulfovibrio vulgaris DSM 644T to strain IPFG07, a mutant deficient in DsrC production. Both strains were cultivated in parallel chemostat reactors at identical turnover times and cell specific sulfate reduction rates. Under these conditions, sulfur isotopic fractionations between sulfate and sulfide of 17.3 ± 0.5‰ or 12.6 ± 0.5‰ were recorded for the wildtype or mutant, respectively. The enzymatic machinery that produced these different fractionations was revealed by quantitative proteomics. Results are consistent with a cellular-level response that throttled the supply of electrons and sulfur supply through the sulfate reduction pathway more in the mutant relative to the wildtype, independent of rate. We conclude that the smaller fractionation observed in the mutant strain is a consequence of sulfate reduction that proceeded at a rate that consumed a greater proportion of the strains overall capacity for sulfate reduction. These observations have consequences for models of sulfate reducer metabolism and how it yields different isotopic fractionations, notably, the role of DsrC in central energy metabolism.
Highlights
Sulfate (SO42−) reduction coupled to organic matter oxidation is a common microbial energy metabolism
DsrC Shifts Proteome and Sulfur Isotopes three billion years (Holland, 1973; Garrels and Lerman, 1981; Fike et al, 2015) and today the burial of sulfides derived from Microbial sulfate reduction (MSR) balances at least one-fifth of the oxygen that has accumulated in the atmosphere (Hayes and Waldbauer, 2006)
We examined the role of DsrC in setting the observed S isotope fractionation between sulfate and sulfide during MSR
Summary
Sulfate (SO42−) reduction coupled to organic matter oxidation is a common microbial energy metabolism. DsrC Shifts Proteome and Sulfur Isotopes three billion years (Holland, 1973; Garrels and Lerman, 1981; Fike et al, 2015) and today the burial of sulfides derived from MSR balances at least one-fifth of the oxygen that has accumulated in the atmosphere (Hayes and Waldbauer, 2006). Microbial sulfate reducers can leave a record of their past activity in the form of geologically robust compounds. Sulfurbearing minerals, such as sulfides, sulfates and geostable organic matter can accumulate in sedimentary rocks, some of which are stable for up to billions of years (Holland, 1973; Claypool et al, 1980; Bontognali et al, 2012). The ultimate goal of such works is to understand how the MSR pathway and environmental conditions interacted in the past to generate the S isotopic signatures preserved for millions of years
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