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.     

Transfer of electrons across the cytoplasmic membrane by DsbD, a membrane protein involved in thiol-disulphide exchange and protein folding in the bacterial periplasm

Reduction of non-native protein disulphides in the periplasm of Escherichia coli is catalysed by three enzymes, DsbC, DsbG and DsbE, each of which harbours a catalytic Cys-X-X-Cys dithiol motif. This dithiol motif requires continuous reduction for activity. Genetic evidence suggests that the source of periplasmic reducing power resides within the cytoplasm, provided by thioredoxin (trxA) and thioredoxin reductase (trxB). Cytoplasmic electrons donated by thioredoxin are thought to be transferred into the periplasm via the DsbD membrane protein. To understand the molecular nature of electron transfer, we have analysed the membrane topology of DsbD. DsbD is exported by an N-terminal signal peptide. The N- and C-terminal domains are positioned in the periplasmic space, connected by eight transmembrane segments. Electron transfer was shown to require five cysteine sulphydryl of DsbD. Trans complementation of mutant DsbD molecules revealed intermolecular electron transfer. We discuss a model whereby the membrane-embedded disulphides of DsbD accept electrons from cytoplasmic thioredoxin and transfer them to the C-terminal periplasmic dithiol motif of DsbD.     

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.     

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.     

High-resolution structures of Escherichia coli cDsbD in different redox states: A combined crystallographic, biochemical and computational study

Escherichia coli DsbD transports electrons from cytoplasmic thioredoxin to periplasmic target proteins. DsbD is composed of an N-terminal (nDsbD) and a C-terminal (cDsbD) periplasmic domain, connected by a central transmembrane domain. Each domain possesses two cysteine residues essential for electron transport. The transport proceeds via disulfide exchange reactions from cytoplasmic thioredoxin to the central transmembrane domain and via cDsbD to nDsbD, which then reduces the periplasmic target proteins. We determined four high-resolution structures of cDsbD: oxidized (1.65 A resolution), chemically reduced (1.3 A), photo-reduced (1.1 A) and chemically reduced at pH increased from 4.6 to 7. The latter structure was refined at 0.99 A resolution, the highest achieved so far for a thioredoxin superfamily member. The data reveal unprecedented structural details of cDsbD, demonstrating that the domain is very rigid and undergoes hardly any conformational change upon disulfide reduction or interaction with nDsbD. In full agreement with the crystallographic results, guanidinium chloride-induced unfolding and refolding experiments indicate that oxidized and reduced cDsbD are equally stable. We confirmed the structural rigidity of cDsbD by molecular dynamics simulations. A remarkable feature of cDsbD is the pKa of 9.3 for the active site Cys461: this value, determined using two different experimental methods, surprisingly was around 2.5 units higher than expected on the basis of the redox potential. Additionally, taking advantage of the very high quality of the cDsbD structures, we carried out pKa calculations, which gave results in agreement with the experimental findings. In conclusion, our wide-scope analysis of cDsbD, encompassing atomic-resolution crystallography, computational chemistry and biophysical measurements, highlighted two so far unrecognized key aspects of this domain: its unusual redox properties and extreme rigidity. Both are likely to be correlated to the role of cDsbD as a covalently linked electron shuttle between the membrane domain and the N-terminal periplasmic domain of DsbD.     

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).     

Mutations of the membrane-bound disulfide reductase DsbD that block electron transfer steps from cytoplasm to periplasm in Escherichia coli

The cytoplasmic membrane protein DsbD keeps the periplasmic disulfide isomerase DsbC reduced, using the cytoplasmic reducing power of thioredoxin. DsbD contains three domains, each containing two reactive cysteines. One membrane-embedded domain, DsbDbeta, transfers electrons from thioredoxin to the carboxy-terminal thioredoxin-like periplasmic domain DsbDgamma. To evaluate the role of conserved amino acid residues in DsbDbeta in the electron transfer process, we substituted alanines for each of 19 conserved amino acid residues and assessed the in vivo redox states of DsbC and DsbD. The mutant DsbDs of 11 mutants which caused defects in DsbC reduction showed relatively oxidized redox states. To analyze the redox state of each DsbD domain, we constructed a thrombin-cleavable DsbD (DsbDTH) from which we could generate all three domains as separate polypeptide chains by thrombin treatment in vitro. We divided the mutants with strong defects into two classes. The first mutant class consists of mutant DsbDbeta proteins that cannot receive electrons from cytoplasmic thioredoxin, resulting in a DsbD that has all six of its cysteines disulfide bonded. The second mutant class represents proteins in which the transfer of electrons from DsbDbeta to DsbDgamma appears to be blocked. This class includes the mutant with the most clear-cut defect, P284A. We relate the properties of the mutants to the positions of the amino acids in the structure of DsbD and discuss mechanisms that would interfere with the electron transfer process.     

Crystal structure of DsbDgamma reveals the mechanism of redox potential shift and substrate specificity(1)

The Escherichia coli transmembrane protein DsbD transfers electrons from the cytoplasm to the periplasm through a cascade of thiol-disulfide exchange reactions. In this process, the C-terminal periplasmic domain of DsbD (DsbDgamma) shuttles the reducing potential from the membrane domain (DsbDbeta) to the N-terminal periplasmic domain (DsbDalpha). The crystal structure of DsbDgamma determined at 1.9 A resolution reveals that the domain has a thioredoxin fold with an extended N-terminal stretch. In comparison to thioredoxin, the DsbDgamma structure exhibits the stabilized active site conformation and the extended active site alpha2 helix that explain the domain's substrate specificity and the redox potential shift, respectively. The hypothetical model of the DsbDgamma:DsbDalpha complex based on the DsbDgamma structure and previous structural studies indicates that the conserved hydrophobic residue in the C-X-X-C motif of DsbDgamma may be important in the specific recognition of DsbDalpha.     

Structural basis and kinetics of DsbD-dependent cytochrome c maturation

DsbD from Escherichia coli transports two electrons from cytoplasmic thioredoxin to the periplasmic substrate proteins DsbC, DsbG and CcmG. DsbD consists of an N-terminal periplasmic domain (nDsbD), a C-terminal periplasmic domain, and a central transmembrane domain. Each domain possesses two cysteines required for electron transport. Herein, we demonstrate fast (3.9 x 10(5) M(-1)s(-1)) and direct disulfide exchange between nDsbD and CcmG, a highly specific disulfide reductase essential for cytochrome c maturation. We determined the crystal structure of the disulfide-linked complex between nDsbD and the soluble part of CcmG at 1.94 A resolution. In contrast to the other two known complexes of nDsbD with target proteins, the N-terminal segment of nDsbD contributes to specific recognition of CcmG. This and other features, like the possibility of using an additional interaction surface, constitute the structural basis for the adaptability of nDsbD to different protein substrates.     

Solution structure and backbone dynamics of the cysteine 103 to serine mutant of the N-terminal domain of DsbD from Neisseria meningitidis

The DsbD protein is essential for electron transfer from the cytoplasm to the periplasm of Gram-negative bacteria. Its N-terminal domain dispatches electrons coming from cytoplasmic thioredoxin (Trx), via its central transmembrane and C-terminal domains, to its periplasmic partners: DsbC, DsbE/CcmG, and DsbG. Previous structural studies described the latter proteins as Trx-like folds possessing a characteristic C-X-X-C motif able to generate a disulfide bond upon oxidation. The Escherichia coli nDsbD displays an immunoglobulin-like fold in which two cysteine residues (Cys103 and Cys109) allow a disulfide bond exchange with its biological partners.We have determined the structure in solution and the backbone dynamics of the C103S mutant of the N-terminal domain of DsbD from Neisseria meningitidis. Our results highlight significant structural changes concerning the beta-sheets and the local topology of the active site compared with the oxidized form of the E. coli nDsbD. The structure reveals a "cap loop" covering the active site, similar to the oxidized E. coli nDsbD X-ray structure. However, regions featuring enhanced mobility were observed both near to and distant from the active site, revealing a capacity of structural adjustments in the active site and in putative interaction areas with nDsbD biological partners. Results are discussed in terms of functional consequences.     

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.     

Transmembrane electron transfer by the membrane protein DsbD occurs via a disulfide bond cascade

The cytoplasmic membrane protein DsbD transfers electrons from the cytoplasm to the periplasm of E. coli, where its reducing power is used to maintain cysteines in certain proteins in the reduced state. We split DsbD into three structural domains, each containing two essential cysteines. Remarkably, when coexpressed, these truncated proteins restore DsbD function. Utilizing this three piece system, we were able to determine a pathway of the electrons through DsbD. Our findings strongly suggest that the pathway is based on a series of multistep redox reactions that include direct interactions between thioredoxin and DsbD, and between DsbD and its periplasmic substrates. A thioredoxin-fold domain in DsbD appears to have the novel role of intramolecular electron shuttle.     

DsbD-catalyzed transport of electrons across the membrane of Escherichia coli

Dsb proteins catalyze folding and oxidation of polypeptides in the periplasm of Escherichia coli. DsbC reduces wrongly paired disulfides by transferring electrons from its catalytic dithiol motif (98)CGYC. Genetic evidence suggests that recycling of this motif requires at least three proteins, the cytoplasmic thioredoxin reductase (TrxB) and thioredoxin (TrxA) as well as the DsbD membrane protein. We demonstrate here that electrons are transferred directly from thioredoxin to DsbD and from DsbD to DsbC. Three cysteine pairs within DsbD undergo reversible disulfide rearrangements. Our results suggest a novel mechanism for electron transport across membranes whereby electrons are transferred sequentially from cysteine pairs arranged in a thioredoxin-like motif (CXXC) to a cognate reactive disulfide.     

Control of Periplasmic Interdomain Thiol:Disulfide Exchange in the Transmembrane Oxidoreductase DsbD

The bacterial protein DsbD transfers reductant from the cytoplasm to the otherwise oxidizing environment of the periplasm. This reducing power is required for several essential pathways, including disulfide bond formation and cytochrome c maturation. DsbD includes a transmembrane domain (tmDsbD) flanked by two globular periplasmic domains (nDsbD/cDsbD); each contains a cysteine pair involved in electron transfer via a disulfide exchange cascade. The final step in the cascade involves reduction of the Cys¹⁰³-Cys¹⁰⁹ disulfide of nDsbD by Cys⁴⁶¹ of cDsbD. Here we show that a complex between the globular periplasmic domains is trapped in vivo only when both are linked by tmDsbD. We have found previously (Mavridou, D. A., Stevens, J. M., Ferguson, S. J., & Redfield, C. (2007) J. Mol. Biol. 370 ,643 -658) that the attacking cysteine (Cys⁴⁶¹) in isolated cDsbD has a high pK_a value (10.5) that makes this thiol relatively unreactive toward the target disulfide in nDsbD. Here we show using NMR that active-site pK_a values change significantly when cDsbD forms a complex with nDsbD. This modulation of pK_a values is critical for the specificity and function of cDsbD. Uncomplexed cDsbD is a poor nucleophile, allowing it to avoid nonspecific reoxidation; however, in complex with nDsbD, the nucleophilicity of cDsbD increases permitting reductant transfer. The observation of significant changes in active-site pK_a values upon complex formation has wider implications for understanding reactivity in thiol:disulfide oxidoreductases.DsbD is a unique protein that transfers reductant across the cytoplasmic membrane to the periplasm in many Gram-negative bacteria (1, 2). Provision of reductant to the periplasm is required because this compartment is otherwise considered to be an oxidizing environment (2). DsbD includes three domains, each containing a pair of cysteine residues that perform a series of disulfide exchange reactions (Fig. 1A). In the first step, the transmembrane domain (tmDsbD) accepts electrons from thioredoxin in the cytoplasm; these are then transferred to the periplasmic C-terminal domain (cDsbD) and finally to the N-terminal domain (nDsbD), which is also located in the periplasm (3-5). nDsbD acts as a junction point for several pathways that require reductant, including the general disulfide isomerase system and the pathway that is thought to reduce the cysteine thiols of apocytochromes in the cytochrome c biogenesis pathway (6). In Gram-positive bacteria, CcdA, an integral membrane protein, and ResA, which has a thioredoxin fold, provide the reductant required for cytochrome c maturation (7).Open in a separate windowFIGURE 1.Schematic representation of DsbD. A, proposed pathway of electron flow from thioredoxin (TrxA) in the cytoplasm, via the three domains of DsbD, to the cytochrome c maturation (Ccm) and disulfide bond isomerization pathways in the periplasm is shown. The crystal structure of nDsbD is from Protein Data Bank code 1L6P (8), cDsbD from Protein Data Bank code 1UC7 (11), and the nDsbD-cDsbD complex from Protein Data Bank code 1VRS (12). The cyan boxes indicate the thrombin cleavage sites introduced into full-length DsbD to allow detection of the nDsbD-cDsbD complex following its formation in vivo. The cysteine residues are shown in yellow. B, schematic representation of the active site of cDsbD in the covalent complex with nDsbD (12). Some active-site residues of cDsbD are indicated in stick representation and the inter-domain disulfide (Cys⁴⁶¹-SS-Cys¹⁰⁹) is shown in yellow.Structural studies have sought to explain how DsbD functions and interacts with its various partners. The structures of the two soluble periplasmic domains have been determined (Fig. 1A, left). nDsbD has an immunoglobulin-like structure (8, 9) and is the only known thiol:disulfide oxidoreductase with this fold. cDsbD has the more typical thioredoxin fold found in many oxidoreductases; this has the characteristic active-site CXXC motif (10, 11). A covalent complex between single-cysteine variants of each of these two domains was produced in vitro and its x-ray structure solved (12), revealing the interface between the two domains (Fig. 1A, right). Although this mixed disulfide is accepted as a physiological intermediate in the function of DsbD, an in vivo complex between the two soluble domains has not been reported previously (3). Further complexes between nDsbD and its other physiological partners have also been trapped and their structures examined (9, 13). Interestingly, all of the interaction partners of nDsbD are thioredoxin-like proteins; similarities in their folds are congruous with common interaction interfaces (14). However, only cDsbD will reduce nDsbD, whereas nDsbD will reduce several partners. This raises questions about how the direction of reductant flow is maintained and controlled within the series of disulfide-exchange reactions.As part of our structural and mechanistic characterization of DsbD and its domains in solution, we have previously measured by NMR the pK_a values of the active-site cysteine pair, Cys⁴⁶¹ and Cys⁴⁶⁴, of cDsbD (numbered according to the full-length Escherichia coli DsbD sequence) (15). An unusually high pK_a value of 10.5 was measured for the N-terminal cysteine of the CXXC motif, Cys⁴⁶¹, and the pK_a value of the second cysteine, Cys⁴⁶⁴, was significantly higher than the maximum pH value that was studied (pH 12.2). The pK_a value of 10.5 is the highest reported for the N-terminal cysteine of the CXXC motif in a thioredoxin fold. The striking consequence of the elevated pK_a value is that the active-site cysteine of cDsbD, Cys⁴⁶¹, is not strongly nucleophilic, raising critical questions about how this cysteine reacts with the disulfide in nDsbD. It was demonstrated using site-directed mutagenesis that the negatively charged side chains of Asp⁴⁵⁵ and Glu⁴⁶⁸, which are located close to the CXXC motif (Fig. 1B), are responsible for the unusually high pK_a value of Cys⁴⁶¹; mutation of one or both of these residues to Asn and Gln, respectively, resulted in decreases in the pK_a value of Cys⁴⁶¹ from 10.5 to 9.9 (E468Q), to 9.3 (D455N), and to 8.6 (D455N/E468Q). The pK_a values for Asp⁴⁵⁵ were found to be 5.9 and 6.6 in oxidized and reduced cDsbD; these values are significantly higher than the value of ∼4 for an unperturbed aspartic acid. We postulated that the properties of the amino acid side chains in the immediate environment of the cysteines in cDsbD would change upon complex formation with nDsbD, changing the reactivity of the cysteines and explaining how the reaction between the two domains is initiated (15). Specifically, we proposed that an increase in the pK_a value of Asp⁴⁵⁵ upon complex formation would lead to a decrease in the pK_a value of Cys⁴⁶¹, thereby making it a better nucleophile. Stirnimann et al. (10) previously presented pK_a calculations suggesting an increase in the Asp⁴⁵⁵ pK_a value upon complex formation.The aim of this work has been to determine the molecular basis of the control of the reactivity of the active-site cysteine residues in cDsbD, using NMR to compare the active-site properties of cDsbD alone and in its physiological complex with nDsbD. We demonstrate that the pK_a value of Asp⁴⁵⁵ is elevated by at least 1.1 pH units when cDsbD forms a complex with nDsbD. This modulation of the pK_a value is critical for the specificity and function of cDsbD. These in vitro studies are complemented by in vivo studies on complex formation, in which we have trapped the nDsbD-cDsbD complex for the first time. The results of our experiments explain how the intramolecular disulfide cascade within the soluble domains of DsbD functions, and demonstrate the importance of the transmembrane domain in controlling and facilitating complex formation between the soluble domains.     

Recognition and binding of apocytochrome c to P. aeruginosa CcmI,a component of cytochrome c maturation machinery

The biogenesis of c-type cytochromes (Cytc) is a process that in Gram-negative bacteria demands the coordinated action of different periplasmic proteins (CcmA-I), whose specific roles are still being investigated. Activities of Ccm proteins span from the chaperoning of heme b in the periplasm to the specific reduction of oxidized apocytochrome (apoCyt) cysteine residues and to chaperoning and recognition of the unfolded apoCyt before covalent attachment of the heme to the cysteine thiols can occur. We present here the functional characterization of the periplasmic domain of CcmI from the pathogen Pseudomonas aeruginosa (Pa-CcmI*). Pa-CcmI* is composed of a TPR domain and a peculiar C-terminal domain. Pa-CcmI* fulfills both the ability to recognize and bind to P. aeruginosa apo-cytochrome c551 (Pa-apoCyt) and a chaperoning activity towards unfolded proteins, as it prevents citrate synthase aggregation in a concentration-dependent manner. Equilibrium and kinetic experiments with Pa-CcmI*, or its isolated domains, with peptides mimicking portions of Pa-apoCyt sequence allow us to quantify the molecular details of the interaction between Pa-apoCyt and Pa-CcmI*. Binding experiments show that the interaction occurs at the level of the TPR domain and that the recognition is mediated mainly by the C-terminal sequence of Pa-apoCyt. The affinity of Pa-CcmI* to full-length Pa-apoCyt or to its C-terminal sequence is in the range expected for a component of a multi-protein complex, whose task is to receive the apoCyt and to deliver it to other components of the apoCyt:heme b ligation protein machinery.     

Thiol-disulfide exchange in an immunoglobulin-like fold: structure of the N-terminal domain of DsbD

Escherichia coli DsbD transports electrons across the plasma membrane, a pathway that leads to the reduction of protein disulfide bonds. Three secreted thioredoxin-like factors, DsbC, DsbE, and DsbG, reduce protein disulfide bonds whereby an active site C-X-X-C motif is oxidized to generate a disulfide bond. DsbD catalyzes the reduction of the disulfide of DsbC, DsbE, and DsbG but not of the thioredoxin-like oxidant DsbA. The reduction of DsbC, DsbE, and DsbG occurs by transport of electrons from cytoplasmic thioredoxin to the C-terminal thioredoxin-like domain of DsbD (DsbD(C)). The N-terminal domain of DsbD, DsbD(N), acts as a versatile adaptor in electron transport and is capable of forming disulfides with oxidized DsbC, DsbE, or DsbG as well as with reduced DsbD(C). Isolated DsbD(N) is functional in electron transport in vitro. Crystallized DsbD(N) assumes an immunoglobulin-like fold that encompasses two active site cysteines, C103 and C109, forming a disulfide bond between beta-strands. The disulfide of DsbD(N) is shielded from the environment and capped by a phenylalanine (F70). A model is discussed whereby the immunoglobulin fold of DsbD(N) may provide for the discriminating interaction with thioredoxin-like factors, thereby triggering movement of the phenylalanine cap followed by disulfide rearrangement.     

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.     

Effects of mutations in genes for proteins involved in disulphide bond formation in the periplasm on the activities of anaerobically induced electron transfer chains in Escherichia coli K12

The assembly of anaerobically induced electron transfer chains in Escherichia coli strains defective in periplasmic disulphide bond formation was investigated. Strains deficient in DsbA, DsbB or DipZ (DsbD) were unable to catalyse formate-dependent nitrite reduction (Nrf activity) or synthesize any of the known c-type cytochromes. The Nrf⁺ activity and cytochrome c content of mutants defective in DsbC, DsbE or DsbF were similar to those of the parental, wild-type strain. Neither DsbC expressed from a multicopy plasmid nor a second mutation in dipZ (dsbD) was able to compensate for a dsbA mutation by restoring nitrite reductase activity and cytochrome c synthesis. In contrast, only the dsbB and dipZ (dsbD) strains were defective in periplasmic nitrate reductase activity, suggesting that DsbB might fulfil an additional role in anaerobic electron transport. Mutants defective in dipZ (dsbD) were only slightly more sensitive to Cu⁺⁺ ions at concentrations above 5?mM than the parental strain, but strains defective in DsbA, DsbB, DsbC, DsbE or DsbF were unaffected. These results are consistent with our earlier proposals that DsbA, DsbB and DipZ (DsbD) are part of the same pathway for ensuring that haem groups are attached to the correct pairs of cysteine residues of apocytochromes c in the E. coli periplasm. However, neither DsbE nor DsbF are essential for the reduction of DipZ (DsbD).     

Reconstitution of a disulfide isomerization system

Isomerization of disulfide bonds is vital for the proper folding of proteins that possess multiple disulfides. In prokaryotes, the catalytic pathway responsible for disulfide isomerization involves thioredoxin, thioredoxin reductase, and the DsbC, DsbG, and DsbD proteins. To be active as isomerases, DsbC and DsbG must be kept reduced. This task is performed by the cytoplasmic membrane protein DsbD. DsbD in turn is reduced by the cytoplasmic thioredoxin and is composed of three domains. The beta domain is membrane-embedded, whereas the alpha and gamma domains are localized to the periplasm. It had been proposed that electrons are transferred within DsbD by a succession of disulfide exchange reactions between the three domains. To test this model using biochemical methods, we purified to homogeneity different polypeptides corresponding to the alpha, beta, gamma, and betagamma domains. Using these domains, we could reconstitute a DsbD activity and, for the first time, reconstitute in vitro the electron transport pathway from NADPH and thioredoxin to DsbC and DsbG. We showed that electrons are transferred from thioredoxin to the beta domain then successively to the gamma domain, the alpha domain, and finally on to DsbC or DsbG. We also determined the redox potential of the gamma domain to be -241 mV, and that of the alpha domain was found to be -229 mV. This shows that the direction of electron flow within DsbD is thermodynamically driven.     

Redox-active cysteines of a membrane electron transporter DsbD show dual compartment accessibility

The membrane-embedded domain of the unusual electron transporter DsbD (DsbDbeta) uses two redox-active cysteines to catalyze electron transfer between thioredoxin-fold polypeptides on opposite sides of the bacterial cytoplasmic membrane. How the electrons are transferred across the membrane is unknown. Here, we show that DsbDbeta displays an inherent functional and structural symmetry: first, the two cysteines of DsbDbeta can be alkylated from both the cytoplasm and the periplasm. Second, when the two cysteines are disulfide-bonded, cysteine scanning shows that the C-terminal halves of the cysteine-containing transmembrane segments 1 and 4 are exposed to the aqueous environment while the N-terminal halves are not. Third, proline residues located pseudo-symmetrically around the two cysteines are required for redox activity and accessibility of the cysteines. Fourth, mixed disulfide complexes, apparent intermediates in the electron transfer process, are detected between DsbDbeta and thioredoxin molecules on each side of the membrane. We propose a model where the two redox-active cysteines are located at the center of the membrane, accessible on both sides of the membrane to the thioredoxin proteins.