Abstract
Sulfate reduction is one of the earliest types of energy metabolism used by ancestral organisms to sustain life. Despite extensive studies, many questions remain about the way respiratory sulfate reduction is associated with energy conservation. A crucial enzyme in this process is the dissimilatory sulfite reductase (dSiR), which contains a unique siroheme-[4Fe4S] coupled cofactor. Here, we report the structure of desulfoviridin from Desulfovibrio vulgaris, in which the dSiR DsrAB (sulfite reductase) subunits are bound to the DsrC protein. The alpha(2)beta(2)gamma(2) assembly contains two siroheme-[4Fe4S] cofactors bound by DsrB, two sirohydrochlorins and two [4Fe4S] centers bound by DsrA, and another four [4Fe4S] centers in the ferredoxin domains. A sulfite molecule, coordinating the siroheme, is found at the active site. The DsrC protein is bound in a cleft between DsrA and DsrB with its conserved C-terminal cysteine reaching the distal side of the siroheme. We propose a novel mechanism for the process of sulfite reduction involving DsrAB, DsrC, and the DsrMKJOP membrane complex (a membrane complex with putative disulfide/thiol reductase activity), in which two of the six electrons for reduction of sulfite derive from the membrane quinone pool. These results show that DsrC is involved in sulfite reduction, which changes the mechanism of sulfate respiration. This has important implications for models used to date ancient sulfur metabolism based on sulfur isotope fractionations.
Highlights
Ago), the advent of oxygenic photosynthesis led to a gradual increase in the levels of atmospheric oxygen, which in turn caused an increasing flux of sulfate to the oceans from weathering of sulfide minerals on land [3]
A key enzyme in sulfur-based energy metabolism is the dissimilatory sulfite reductase,3 which is present in organisms that reduce sulfate, sulfite, and other sulfur compounds
The assimilatory sulfite (aSiR) and aNiR, found in plants, fungi, and bacteria, are monomeric enzymes that display an internal two-fold symmetry of a module that is related to DsrA/DsrB, suggesting that these assimilatory proteins resulted from a gene duplication event [9, 10, 14]
Summary
Protein Crystallization and X-ray Data—Dvir from D. vulgaris Hildenborough (DSM 644) was purified as described previously [32]. A detailed description of the crystallization and structure solution of Dvir by multiple-wavelength anomalous dispersion based on the iron is presented in Ref. 32. Crystals diffract to 2.1 Å and belong to the same space group (P21) as the 2.9 Å data set, but with different cell parameters: a ϭ 65.41, b ϭ 118.91, and c ϭ 132.25 Å,  ϭ 104.1° with one ␣22␥2 assembly in the asymmetric unit and solvent content of ϳ50%. Structure Determination and Refinement—Because the two measured crystals are not isomorphous, the 2.1 Å data set structure was solved by molecular replacement with MOLREP [37] using the 2.9 Å model as a template (two ␣␥ units were found).
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