Structural basis for the oxidation of protein-bound sulfur by the sulfur cycle molybdohemo-enzyme sulfane dehydrogenase SoxCD.

The sulfur cycle enzyme sulfane dehydrogenase SoxCD is an essential component of the sulfur oxidation (Sox) enzyme system of Paracoccus pantotrophus. SoxCD catalyzes a six-electron oxidation reaction within the Sox cycle. SoxCD is an α(2)ß(2) heterotetrameric complex of the molybdenum cofactor-containing SoxC protein and the diheme c-type cytochrome SoxD with the heme domains D(1) and D(2). SoxCD(1) misses the heme-2 domain D(2) and is catalytically as active as SoxCD. The crystal structure of SoxCD(1) was solved at 1.33 Å. The substrate of SoxCD is the outer (sulfane) sulfur of Cys-110-persulfide located at the C-terminal peptide swinging arm of SoxY of the SoxYZ carrier complex. The SoxCD(1) substrate funnel toward the molybdopterin is narrow and partially shielded by side-chain residues of SoxD(1). For access of the sulfane-sulfur of SoxY-Cys-110 persulfide we propose that (i) the blockage by SoxD-Arg-98 is opened via interaction with the C terminus of SoxY and (ii) the C-terminal peptide VTIGGCGG of SoxY provides interactions with the entrance path such that the cysteine-bound persulfide is optimally positioned near the molybdenum atom. The subsequent oxidation reactions of the sulfane-sulfur are initiated by the nucleophilic attack of the persulfide anion on the molybdenum atom that is, in turn, reduced. The close proximity of heme-1 to the molybdopterin allows easy acceptance of the electrons. Because SoxYZ, SoxXA, and SoxB are already structurally characterized, with SoxCD(1) the structures of all key enzymes of the Sox cycle are known with atomic resolution.

A combined fluorescence spectroscopic and electrochemical approach for the study of thioredoxins.

A new way to study the electrochemical properties of proteins by coupling front-face fluorescence spectroscopy with an optically transparent thin-layer electrochemical cell is presented. First, the approach was examined on the basis of the redox-dependent conformational changes in tryptophans in cytochrome c, and its redox potential was successfully determined. Second, an electrochemically induced fluorescence analysis of periplasmic thiol-disulfide oxidoreductases SoxS and SoxW was performed. SoxS is essential for maintaining chemotrophic sulfur oxidation of Paracoccus pantotrophus active in vivo, while SoxW is not essential. According to the potentiometric redox titration of tryptophan fluorescence, the midpoint potential of SoxS was -342 ± 8 mV versus the standard hydrogen electrode (SHE') and that of SoxW was -256 ± 10 mV versus the SHE'. The fluorescence properties of the thioredoxins are presented and discussed together with the intrinsic fluorescence contribution of the tyrosines.

The periplasmic thioredoxin SoxS plays a key role in activation in vivo of chemotrophic sulfur oxidation of Paracoccus pantotrophus.

The significance of the soxS gene product on chemotrophic sulfur oxidation of Paracoccus pantotrophus was investigated. The thioredoxin SoxS was purified, and the N-terminal amino acid sequence identified SoxS as the soxS gene product. The wild-type formed thiosulfate-oxidizing activity and Sox proteins during mixotrophic growth with succinate plus thiosulfate, while there was no activity, and only traces of Sox proteins, under heterotrophic conditions. The homogenote mutant strain GBOmegaS is unable to express the soxSR genes, of which soxR encodes a transcriptional regulator. Strain GBOmegaS cultivated mixotrophically showed about 22 % of the specific thiosulfate-dependent O(2) uptake rate of the wild-type, and when cultivated heterotrophically it produced 35 % activity. However, under both mixotrophic and heterotrophic conditions, strain GBOmegaS formed Sox proteins essential for sulfur oxidation in vitro at the same high level as the wild-type produced them during mixotrophic growth. Genetic complementation of strain GBOmegaS with soxS restored the activity upon mixotrophic and heterotrophic growth. Chemical complementation by reductants such as L-cysteine, DTT and tris(2-carboxyethyl)phosphine also restored the activity of strain GBOmegaS in the presence of chloramphenicol, which is an inhibitor of de novo protein synthesis. The data demonstrate that SoxS plays a key role in activation of the Sox enzyme system, and this suggests that SoxS is part of a novel type of redox control in P. pantotrophus.

The flavoprotein SoxF functions in chemotrophic thiosulfate oxidation of Paracoccus pantotrophus in vivo and in vitro.

Paracoccus pantotrophus strain GBsoxFDelta carries a deletion in the soxF gene that inactivates flavoprotein SoxF-sulfide dehydrogenase. This strain grew with thiosulfate slower than the wild type. GBsoxFDelta cells oxidized thiosulfate at a rate of 40% and hydrogen sulfide at a rate of 45% of the wild type. Complementation of GBsoxFDelta with plasmid pRIsoxF carrying the soxF gene increased these rates to 83% and 70%, respectively. However, GBsoxFDelta and GBsoxFDelta (pRIsoxF) oxidized thiosulfate and hydrogen sulfide to sulfate as evident from the yield of electrons. The thiosulfate oxidation rate of cell-free extracts of strain GBsoxFDelta was increased when supplemented with SoxF isolated from the wild type. However, SoxF did not affect the thiosulfate-oxidizing activity of the Sox enzyme system as reconstituted from the 'as-isolated' four Sox proteins. These data demonstrated that SoxF enhanced chemotrophic thiosulfate oxidation in vivo and acted on some component or condition present in whole cells and cell-free extracts but not present in the reconstituted system.

SoxV transfers electrons to the periplasm of Paracoccus pantotrophus - an essential reaction for chemotrophic sulfur oxidation.

The soxVW genes are located upstream of the sox gene cluster encoding the sulfur-oxidizing ability of Paracoccus pantotrophus. SoxV is highly homologous to CcdA, which is involved in cytochrome c maturation of P. pantotrophus. SoxV was shown to function in reduction of the periplasmic SoxW, which shows a CysXaaXaaCys motif characteristic for thioredoxins. From strain GBOmegaV, which carries an Omega-kanamycin-resistance-encoding interposon in soxV, and complementation analysis it was evident that SoxV but not the periplasmic SoxW was essential for lithoautotrophic growth of P. pantotrophus with thiosulfate. However, the thiosulfate-oxidizing activities of cell extracts from the wild-type and from strain GBOmegaV were similar, demonstrating that the low thiosulfate-oxidizing activity of strain GBOmegaV in vivo was not due to a defect in biosynthesis or maturation of proteins of the Sox system and suggesting that SoxV is part of a regulatory or catalytic system of the Sox system. Analysis of DNA sequences available from different organisms harbouring a Sox system revealed that soxVW genes are exclusively present in sox operons harbouring the soxCD genes, encoding sulfur dehydrogenase, suggesting that SoxCD might be a redox partner of SoxV. No complementation of the ccdA mutant P. pantotrophus TP43 defective in cytochrome c maturation was achieved by expression of soxV in trans, demonstrating that the high identity of SoxV and CcdA does not correspond to functional homology.

Prokaryotic sulfur oxidation.

Recent biochemical and genomic data differentiate the sulfur oxidation pathway of Archaea from those of Bacteria. From these data it is evident that members of the Alphaproteobacteria harbor the complete sulfur-oxidizing Sox enzyme system, whereas members of the beta and gamma subclass and the Chlorobiaceae contain sox gene clusters that lack the genes encoding sulfur dehydrogenase. This indicates a different pathway for oxidation of sulfur to sulfate. Acidophilic bacteria oxidize sulfur by a system different from the Sox enzyme system, as do chemotrophic endosymbiotic bacteria.

SoxRS-mediated regulation of chemotrophic sulfur oxidation in Paracoccus pantotrophus.

Paracoccus pantotrophus GB17 requires thiosulfate for induction of the sulfur-oxidizing (Sox) enzyme system. The soxRS genes are divergently oriented to the soxVWXYZA-H genes. soxR predicts a transcriptional regulator of the ArsR family and soxS a periplasmic thioredoxin. The homogenate mutant GBOmegaS carrying a disruption of soxS by the Omega-kanamycin-resistance-encoding interposon expressed a low thiosulfate-oxidizing activity under heterotrophic and mixotrophic growth conditions. This activity was repressed by complementation with soxR, suggesting that SoxR acts as a repressor and SoxS is essential for full expression. Sequence analysis uncovered operator characteristics in the intergenic regions soxS-soxV and soxW-soxX. In each region a transcription start site was identified by primer extension analysis. Both regions were cloned into the vector pRI1 and transferred to P. pantotrophus. Strains harbouring pRI1 with soxS-soxV or soxW-soxX expressed the sox genes under heterotrophic conditions at a low rate, indicating repressor titration. Sequence analysis of SoxR suggested a helix-turn-helix (HTH) motif at position 87-108 and uncovered an invariant Cys-80 and a cysteine residue at the C-terminus. SoxR was overproduced in Escherichia coli with an N-terminal His6-tag and purified to near homogeneity. Electrophoretic gel mobility shift assays with SoxR retarded the soxS-soxV region as a single band while the soxW-soxX region revealed at least two protein-DNA complexes. These data demonstrated binding of SoxR to the relevant DNA. This is believed to be the first report of regulation of chemotrophic sulfur oxidation at the molecular level.

Sulfur dehydrogenase of Paracoccus pantotrophus: the heme-2 domain of the molybdoprotein cytochrome c complex is dispensable for catalytic activity.

Sulfur dehydrogenase, Sox(CD)(2), is an essential part of the sulfur-oxidizing enzyme system of the chemotrophic bacterium Paracoccus pantotrophus. Sox(CD)(2) is a alpha(2)beta(2) complex composed of the molybdoprotein SoxC (43 442 Da) and the hybrid diheme c-type cytochrome SoxD (37 637 Da). Sox(CD)(2) catalyzes the oxidation of protein-bound sulfur to sulfate with a unique six-electron transfer. Amino acid sequence analysis identified the heme-1 domain of SoxD proteins to be specific for sulfur dehydrogenases and to contain a novel ProCysMetXaaAspCys motif, while the heme-2 domain is related to various cytochromes c(2). Purification of sulfur dehydrogenase without protease inhibitor yielded a dimeric SoxCD(1) complex consisting of SoxC and SoxD(1) of 30 kDa, which contained only the heme-1 domain. The heme-2 domain was isolated as a new cytochrome SoxD(2) of about 13 kDa. Both hemes of SoxD in Sox(CD)(2) are redox-active with midpoint potentials at E(m)1 = 218 +/- 10 mV and E(m)2 = 268 +/- 10 mV, while SoxCD(1) and SoxD(2) both exhibit a midpoint potential of E(m) = 278 +/- 10 mV. Electrochemically induced FTIR difference spectra of Sox(CD)(2), SoxCD(1), and SoxD(2) were distinct. A carboxy group is protonated upon reduction of the SoxD(1) heme but not for SoxD(2). The specific activity of SoxCD(1) and Sox(CD)(2) was identical as was the yield of electrons with thiosulfate in the reconstituted Sox enzyme system. To examine the physiological significance of the heme-2 domain, a mutant was constructed that was deleted for the heme-2 domain, which produced SoxCD(1) and transferred electrons from thiosulfate to oxygen. These data demonstrated the crucial role of the heme-1 domain of SoxD for catalytic activity, electron yield, and transfer of the electrons to the cytoplasmic membrane, while the heme-2 domain mediated the alpha(2)beta(2) tetrameric structure of sulfur dehydrogenase.

Sulfide dehydrogenase activity of the monomeric flavoprotein SoxF of Paracoccus pantotrophus.

Flavocytochrome c-sulfide dehydrogenases (FCSDs) are complexes of a flavoprotein with a c-type cytochrome performing hydrogen sulfide-dependent cytochrome c reduction in vitro. The amino acid sequence analysis revealed that the phylogenetic relationship of different flavoproteins reflected the relationship of sulfur-oxidizing bacteria. The flavoprotein SoxF of Paracoccus pantotrophus is 29-67% identical to the flavoprotein subunit of FCSD of phototrophic sulfur-oxidizing bacteria. Purification of SoxF yielded a homogeneous emerald-green monomeric protein of 42 797 Da. SoxF catalyzed sulfide-dependent horse heart cytochrome c reduction at the optimum pH of 6.0 with a k(cat) of 3.9 s(-1), a K(m) of 2.3 microM for sulfide, and a K(m) of 116 microM for cytochrome c, as determined by nonlinear regression analysis. The yield of 1.9 mol of cytochrome c reduced per mole of sulfide suggests sulfur or polysulfide as the product. Sulfide dehydrogenase activity of SoxF was inhibited by sulfur (K(i) = 1.3 microM) and inactivated by sulfite. Cyanide (1 mM) inhibited SoxF activity at pH 6.0 by 25% and at pH 8.0 by 92%. Redox titrations in the infrared spectral range from 1800 to 1200 cm(-1) and in the visible spectral range from 400 to 700 nm both yielded a midpoint potential for SoxF of -555 +/- 10 mV versus Ag/AgCl at pH 7.5 and -440 +/- 20 mV versus Ag/AgCl at pH 6.0 (-232 mV versus SHE') and a transfer of 1.9 electrons. Electrochemically induced FTIR difference spectra of SoxF as compared to those of free flavin in solution suggested a strong cofactor interaction with the apoprotein. Furthermore, an activation/variation of SoxF during the redox cycles is observed. This is the first report of a monomeric flavoprotein with sulfide dehydrogenase activity.

Sulfur oxidation in Paracoccus pantotrophus: interaction of the sulfur-binding protein SoxYZ with the dimanganese SoxB protein.

The central protein of the sulfur-oxidizing enzyme system of Paracoccus pantotrophus, SoxYZ, formed complexes with subunits associated and covalently bound. In denaturing SDS-polyacrylamide gel electrophoresis (PAGE) SoxY migrated at 12 and SoxZ at 16kDa. SDS-PAGE of homogeneous SoxYZ without reductant separated dimeric complexes of 25, 29, and 32kDa identified by the N-terminal amino acid sequences as SoxY-Y, SoxY-Z, and SoxZ-Z, and subunit cleavage by reduction suggested their linkage via protein disulfide bonds. SoxYZ was reversibly redox active between -0.25 and 0.2V, as monitored by a combined electrochemical and FTIR spectroscopic approach. The dimanganese SoxB protein (58.611Da) converted the covalently linked heterodimer SoxY-Z to SoxYZ with associated subunits which in turn aggregated to the heterotetramer Sox(YZ)(2). This reaction depended on time and the SoxB concentration, and demonstrated the interaction of these two Sox proteins.