Kinetics of the intramolecular disulfide exchange between the periplasmic domains of DsbD

DsbD from Escherichia coli catalyzes the transport of electrons from cytoplasmic thioredoxin to the periplasmic substrate proteins DsbC, DsbG and CcmG. DsbD consists of a periplasmic, N-terminal domain (nDsbD), a central transmembrane domain and a periplasmic, C-terminal domain (cDsbD). Each of these domains contains two essential cysteine residues that are required for intermolecular disulfide exchange between DsbD and substrates, and intramolecular disulfide exchange between the three DsbD domains. In order to determine the rate of intramolecular electron transfer from cDsbD to nDsbD, we constructed a redox-sensitive tryptophan variant of cDsbD (cDsbD(W)) that shows an approximately threefold increase in fluorescence upon reduction and has the same redox potential and reactivity as wild-type cDsbD. cDsbD(W) was then used for the construction of fusion proteins with nDsbD and cDsbD(W), connected via flexible linkers of different length. Using the DsbD substrate DsbC, which can only be reduced by nDsbD and does not react with cDsbD, we could directly measure the intramolecular electron transfer from cDsnD(W) to nDsbB in the fusion proteins. We show that the intramolecular disulfide exchange is significantly faster than the reaction between isolated nDsbD and cDsbD. Nevertheless, the effective concentration of 0.2 mM of the domains in the fusions is comaparably low. The rate of 23 s(-1) for the intramolecular disulfide exchange in the fusions was independent of the linker length and may represent the upper limit for the substrate turnover of full-length DsbD.     

Thermodynamic aspects of DsbD-mediated electron transport

DsbD from Escherichia coli transports electrons from cytoplasmic thioredoxin across the inner membrane to the periplasmic substrate proteins DsbC, DsbG and CcmG. DsbD consists of three domains: a periplasmic N-terminal domain, a central transmembrane domain (tmDsbD) and a periplasmic C-terminal domain. Each domain contains two essential cysteine residues that are required for electron transport. In contrast to the quinone reductase DsbB, HPLC analysis of the methanol/hexane extracts of purified DsbD revealed no presence of quinones, suggesting that the tmDsbD interacts with thioredoxin and the periplasmic C-terminal domain exclusively via disulfide exchange. We also demonstrate that a DsbD variant containing only the redox-active cysteine pair C163 and C285 in tmDsbD, reconstituted into liposomes, has a redox potential of − 0.246 V. The results show that all steps in the DsbD-mediated electron flow are thermodynamically favorable.     

Structural basis and kinetics of inter- and intramolecular disulfide exchange in the redox catalyst DsbD

DsbD from Escherichia coli catalyzes the transport of electrons from cytoplasmic thioredoxin to the periplasmic disulfide isomerase DsbC. DsbD contains two periplasmically oriented domains at the N- and C-terminus (nDsbD and cDsbD) that are connected by a central transmembrane (TM) domain. Each domain contains a pair of cysteines that are essential for catalysis. Here, we show that Cys109 and Cys461 form a transient interdomain disulfide bond between nDsbD and cDsbD in the reaction cycle of DsbD. We solved the crystal structure of this catalytic intermediate at 2.85 A resolution, which revealed large relative domain movements in DsbD as a consequence of a strong overlap between the surface areas of nDsbD that interact with DsbC and cDsbD. In addition, we have measured the kinetics of all functional and nonfunctional disulfide exchange reactions between redox-active, periplasmic proteins and protein domains from the oxidative DsbA/B and the reductive DsbC/D pathway. We show that both pathways are separated by large kinetic barriers for nonfunctional disulfide exchange between components from different pathways.     

An Extended Active-site Motif Controls the Reactivity of the Thioredoxin Fold

Proteins belonging to the thioredoxin (Trx) superfamily are abundant in all organisms. They share the same structural features, arranged in a seemingly simple fold, but they perform a multitude of functions in oxidative protein folding and electron transfer pathways. We use the C-terminal domain of the unique transmembrane reductant conductor DsbD as a model for an in-depth analysis of the factors controlling the reactivity of the Trx fold. We employ NMR spectroscopy, x-ray crystallography, mutagenesis, in vivo functional experiments applied to DsbD, and a comparative sequence analysis of Trx-fold proteins to determine the effect of residues in the vicinity of the active site on the ionization of the key nucleophilic cysteine of the -CXXC- motif. We show that the function and reactivity of Trx-fold proteins depend critically on the electrostatic features imposed by an extended active-site motif.     

SoxV,an orthologue of the CcdA disulfide transporter,is involved in thiosulfate oxidation in Rhodovulum sulfidophilum and reduces the periplasmic thioredoxin SoxW

Proteins of the CcdA/DsbD family have previously been found to be involved in the protein disulfide isomerase and cytochrome c maturation pathways of bacteria. SoxV is a CcdA homologue encoded by a genetic locus involved in lithotrophic thiosulfate oxidation in Rhodovulum sulfidophilum. Mutagenesis studies demonstrate an essential and specific role for SoxV in thiosulfate oxidation. Another protein encoded by the same locus, SoxW, is a periplasmic thioredoxin. SoxW was found to be in the reduced state during growth of R. sulfidophilum in the presence of thiosulfate. Maintenance of SoxW in the reduced state was shown to require SoxV. Nevertheless, SoxW was found to be dispensible for thiosulfate oxidation suggesting that SoxV reduces more than one periplasmic partner protein.     

1H, 13C, and 15N resonance assignment of the C103S mutant of the N-terminal domain of DsbD from Neisseria meningitidis

We report the nearly complete ¹H, ¹³C, and ¹⁵N resonance assignments of the C103S mutant of the N-terminal domain of DsbD from Neisseria meningitides. Secondary structure determination using CSI method leads to the prediction of nine β-sheet parts.     

Oxidation state-dependent protein-protein interactions in disulfide cascades

Bacterial growth and pathogenicity depend on the correct formation of disulfide bonds, a process controlled by the Dsb system in the periplasm of Gram-negative bacteria. Proteins with a thioredoxin fold play a central role in this process. A general feature of thiol-disulfide exchange reactions is the need to avoid a long lived product complex between protein partners. We use a multidisciplinary approach, involving NMR, x-ray crystallography, surface plasmon resonance, mutagenesis, and in vivo experiments, to investigate the interaction between the two soluble domains of the transmembrane reductant conductor DsbD. Our results show oxidation state-dependent affinities between these two domains. These observations have implications for the interactions of the ubiquitous thioredoxin-like proteins with their substrates, provide insight into the key role played by a unique redox partner with an immunoglobulin fold, and are of general importance for oxidative protein-folding pathways in all organisms.     

Active-site properties of the oxidized and reduced C-terminal domain of DsbD obtained by NMR spectroscopy

The periplasmic C-terminal domain of the Escherichia coli DsbD protein (cDsbD) has a thioredoxin fold. The two cysteine residues in the CXXC motif serve as the reductant for the disulfide bond of the N-terminal domain which can in turn act as a reductant for various periplasmic partners. The resulting disulfide bond in cDsbD is reduced via an unknown mechanism by the transmembrane helical domain of the protein. We show by NMR analysis of (13)C, (15)N-labelled cDsbD that the protein is rigid, is stable to extremes of pH and undergoes only localized conformational changes in the vicinity of the CXXC motif, and in adjacent regions of secondary structure, upon undergoing the reduced/oxidized transition. pK(a) values have been determined, using 2D NMR, for the N-terminal cysteine of the CXXC motif, Cys461, as well as for other active-site residues. It is demonstrated using site-directed mutagenesis that the negative charges of the side-chains of Asp455 and Glu468 in the active site contribute to the unusually high pK(a) value, 10.5, of Cys461. This value is higher than expected from knowledge of the reduction potential of cDsbD. In a double mutant of cDsbD, D455N/E468Q, the pK(a) value of Cys461 is lowered to 8.6, a value close to that expected for an unperturbed cysteine residue. The pK(a) value of the second cysteine in wild-type cDsbD, Cys464, is significantly higher than the maximum pH value that was studied (pH 12.2).