Mechanism of the electron transfer catalyst DsbB from Escherichia coli

The membrane protein DsbB from Escherichia coli is essential for disulfide bond formation and catalyses the oxidation of the periplasmic dithiol oxidase DsbA by ubiquinone. DsbB contains two catalytic disulfide bonds, Cys41-Cys44 and Cys104-Cys130. We show that DsbB directly oxidizes one molar equivalent of DsbA in the absence of ubiquinone via disulfide exchange with the 104-130 disulfide bond, with a rate constant of 2.7 x 10 M(-1) x s(-1). This reaction occurs although the 104-130 disulfide is less oxidizing than the catalytic disulfide bond of DsbA (E(o)' = -186 and -122 mV, respectively). This is because the 41-44 disulfide, which is only accessible to ubiquinone but not to DsbA, is the most oxidizing disulfide bond in a protein described so far, with a redox potential of -69 mV. Rapid intramolecular disulfide exchange in partially reduced DsbB converts the enzyme into a state in which Cys41 and Cys44 are reduced and thus accessible for reoxidation by ubiquinone. This demonstrates that the high catalytic efficiency of DsbB results from the extreme intrinsic oxidative force of the enzyme.     

Respiratory chain strongly oxidizes the CXXC motif of DsbB in the Escherichia coli disulfide bond formation pathway

Escherichia coli DsbB has four essential cysteine residues, among which Cys41 and Cys44 form a CXXC redox active site motif and the Cys104-Cys130 disulfide bond oxidizes the active site cysteines of DsbA, the disulfide bond formation factor in the periplasm. Functional respiratory chain is required for the cell to keep DsbA oxidized. In this study, we characterized the roles of essential cysteines of DsbB in the coupling with the respiratory chain. Cys104 was found to form the inactive complex with DsbA under respiration-defective conditions. While DsbB, under normal aerobic conditions, is in the oxidized state, having two intramolecular disulfide bonds, oxidation of Cys104 and Cys130 requires the presence of Cys41-Cys44. Remarkably, the Cys41-Cys44 disulfide bond is refractory to reduction by a high concentration of dithiothreitol, unless the membrane is solubilized with a detergent. This reductant resistance requires both the respiratory function and oxygen, since Cys41-Cys44 became sensitive to the reducing agent when membrane was prepared from quinone- or heme-depleted cells or when a membrane sample was deaerated. Thus, the Cys41-Val-Leu-Cys44 motif of DsbB is kept both strongly oxidized and strongly oxidizing when DsbB is integrated into the membrane with the normal set of respiratory components.     

Preparation and structure of the charge-transfer intermediate of the transmembrane redox catalyst DsbB

Disulfide bond formation is a critical step in the folding of many secretory proteins. In bacteria, disulfide bonds are introduced by the periplasmic dithiol oxidase DsbA, which transfers its catalytic disulfide bond to folding polypeptides. Reduced DsbA is reoxidized by ubiquinone Q8, catalyzed by inner membrane quinone reductase DsbB. Here, we report the preparation of a kinetically stable ternary complex between wild-type DsbB, containing all essential cysteines, Q8 and DsbA covalently bound to DsbB. The crystal structure of this trapped DsbB reaction intermediate exhibits a charge-transfer interaction between Q8 and the Cys44 in the DsbB reaction center providing experimental evidence for the mechanism of de novo disulfide bond generation in DsbB.     

DsbB catalyzes disulfide bond formation de novo

DsbA and DsbB are responsible for disulfide bond formation. DsbA is the direct donor of disulfides, and DsbB oxidizes DsbA. DsbB has the unique ability to generate disulfides by quinone reduction. It is thought that DsbB oxidizes DsbA via thiol disulfide exchange. In this mechanism, a disulfide is formed across the N-terminal pair of cysteines (Cys-41/Cys-44) in DsbB by quinone reduction. This disulfide is then transferred on to the second pair of cysteine residues in DsbB (Cys-104/Cys-130) and then finally transferred to DsbA. We have shown here the redox potential of the two disulfides in DsbB are -271 and -284 mV, respectively, and considerably less oxidizing than the disulfide of DsbA at -120 mV. In addition, we have found the Cys-104/Cys-130 disulfide of DsbB to actually be a substrate for DsbA in vitro. These findings indicate that the disulfides in DsbB are unsuitable to function as the oxidant of DsbA. Furthermore, we have shown that mutants in DsbB that lack either pair or all of its cysteines are also capable of oxidizing DsbA. These unexpected findings raise the possibility that the oxidation of DsbA by DsbB does not occur via thiol disulfide exchange as is widely assumed but rather, directly via quinone reduction.     

Paradoxical redox properties of DsbB and DsbA in the protein disulfide-introducing reaction cascade

Protein disulfide bond formation in the bacterial periplasm is catalyzed by the Dsb enzymes in conjunction with the respiratory quinone components. Here we characterized redox properties of the redox active sites in DsbB to gain further insights into the catalytic mechanisms of DsbA oxidation. The standard redox potential of DsbB was determined to be -0.21 V for Cys41/Cys44 in the N-terminal periplasmic region (P1) and -0.25 V for Cys104/Cys130 in the C-terminal periplasmic region (P2), while that of Cys30/Cys33 in DsbA was -0.12 V. To our surprise, DsbB, an oxidant for DsbA, is intrinsically more reducing than DsbA. Ubiquinone anomalously affected the apparent redox property of the P1 domain, and mutational alterations of the P1 region significantly lowered the catalytic turnover. It is inferred that ubiquinone, a high redox potential compound, drives the electron flow by interacting with the P1 region with the Cys41/Cys44 active site. Thus, DsbB can mediate electron flow from DsbA to ubiquinone irrespective of the intrinsic redox potential of the Cys residues involved.     

Reactivities of quinone-free DsbB from Escherichia coli

DsbB is a disulfide oxidoreductase present in the Escherichia coli plasma membrane. Its cysteine pairs, Cys41-Cys44 and Cys104-Cys130, facing the periplasm, as well as the bound quinone molecules play crucial roles in oxidizing DsbA, the protein dithiol oxidant in the periplasm. In this study, we characterized quinone-free forms of DsbB prepared from mutant cells unable to synthesize ubiquinone and menaquinone. While such preparations lacked detectable quinones, previously reported lauroylsarcosine treatment was ineffective in removing DsbB-associated quinones. Moreover, DsbB-bound quinone was shown to contribute to the redox-dependent fluorescence changes observed with DsbB. Now we reconfirmed that redox potentials of cysteine pairs of quinone-free DsbB are lower than that of DsbA, as far as determined in dithiothreitol redox buffer. Nevertheless, the quinone-free DsbB was able to oxidize approximately 40% of DsbA in a 1:1 stoichiometric reaction, in which hemi-oxidized forms of DsbB having either disulfide are generated. It was suggested that the DsbB-DsbA system is designed in such a way that specific interaction of the two components enables the thiol-disulfide exchanges in the "forward" direction. In addition, a minor fraction of quinone-free DsbB formed the DsbA-DsbB disulfide complex stably. Our results show that the rapid and the slow pathways of DsbA oxidation can proceed up to significant points, after which these reactions must be completed and recycled by quinones under physiological conditions. We discuss the significance of having such multiple reaction pathways for the DsbB-dependent DsbA oxidation.     

Dynamic nature of disulphide bond formation catalysts revealed by crystal structures of DsbB

In the Escherichia coli system catalysing oxidative protein folding, disulphide bonds are generated by the cooperation of DsbB and ubiquinone and transferred to substrate proteins through DsbA. The structures solved so far for different forms of DsbB lack the Cys104–Cys130 initial‐state disulphide that is directly donated to DsbA. Here, we report the 3.4 Å crystal structure of a DsbB–Fab complex, in which DsbB has this principal disulphide. Its comparison with the updated structure of the DsbB–DsbA complex as well as with the recently reported NMR structure of a DsbB variant having the rearranged Cys41–Cys130 disulphide illuminated conformational transitions of DsbB induced by the binding and release of DsbA. Mutational studies revealed that the membrane‐parallel short α‐helix of DsbB has a key function in physiological electron flow, presumably by controlling the positioning of the Cys130‐containing loop. These findings demonstrate that DsbB has developed the elaborate conformational dynamism to oxidize DsbA for continuous protein disulphide bond formation in the cell.     

NMR solution structure of the integral membrane enzyme DsbB: functional insights into DsbB-catalyzed disulfide bond formation

We describe the NMR structure of DsbB, a polytopic helical membrane protein. DsbB, a bacterial cytoplasmic membrane protein, plays a key role in disulfide bond formation. It reoxidizes DsbA, the periplasmic protein disulfide oxidant, using the oxidizing power of membrane-embedded quinones. We determined the structure of an interloop disulfide bond form of DsbB, an intermediate in catalysis. Analysis of the structure and interactions with substrates DsbA and quinone reveals functionally relevant changes induced by these substrates. Analysis of the structure, dynamics measurements, and NMR chemical shifts around the interloop disulfide bond suggest how electron movement from DsbA to quinone through DsbB is regulated and facilitated. Our results demonstrate the extraordinary utility of NMR for functional characterization of polytopic integral membrane proteins and provide insights into the mechanism of DsbB catalysis.     

Structure and mechanisms of the DsbB-DsbA disulfide bond generation machine

All organisms possess specific cellular machinery that introduces disulfide bonds into proteins newly synthesized and transported out of the cytosol. In E. coli, the membrane-integrated DsbB protein cooperates with ubiquinone to generate a disulfide bond, which is transferred to DsbA, a periplasmic dithiol oxido-reductase that serves as the direct disulfide bond donor to proteins folding oxidatively in this compartment. Despite the extensive accumulation of knowledge on this oxidation system, molecular details of the DsbB reaction mechanisms had been controversial due partly to the lack of structural information until our recent determination of the crystal structure of a DsbA-DsbB-ubiquinone complex. In this review we discuss the structural and chemical nature of reaction intermediates in the DsbB catalysis and the illuminated molecular mechanisms that account for the de novo formation of a disulfide bond and its donation to DsbA. It is suggested that DsbB gains the ability to oxidize its specific substrate, DsbA, having very high redox potential, by undergoing a DsbA-induced rearrangement of cysteine residues. One of the DsbB cysteines that are now reduced then interacts with ubiquinone to form a charge transfer complex, leading to the regeneration of a disulfide at the DsbB active site, and the cycle can begin anew.     

Four cysteines of the membrane protein DsbB act in concert to oxidize its substrate DsbA

Protein disulfide bond formation in Escherichia coli is catalyzed by the periplasmic protein DsbA. A cytoplasmic membrane protein DsbB maintains DsbA in the oxidized state by transferring electrons from DsbA to quinones in the respiratory chain. Here we show that DsbB activity can be reconstituted by co-expression of N- and C-terminal fragments of the protein, each containing one of its redox-active disulfide bonds. This system has allowed us (i) to demonstrate that the two DsbB redox centers interact directly through a disulfide bond formed between the two DsbB domains and (ii) to identify the specific cysteine residues involved in this covalent interaction. Moreover, we are able to capture an intermediate in the process of electron transfer from one redox center to the other. These results lead us to propose a model that describes how the cysteines cooperate in the early stages of oxidation of DsbA. DsbB appears to adopt a novel mechanism to oxidize DsbA, using its two pairs of cysteines in a coordinated reaction to accept electrons from the active cysteines in DsbA.     

Crystal Structure of the Dithiol Oxidase DsbA Enzyme from Proteus Mirabilis Bound Non-covalently to an Active Site Peptide Ligand

The disulfide bond forming DsbA enzymes and their DsbB interaction partners are attractive targets for development of antivirulence drugs because both are essential for virulence factor assembly in Gram-negative pathogens. Here we characterize PmDsbA from Proteus mirabilis, a bacterial pathogen increasingly associated with multidrug resistance. PmDsbA exhibits the characteristic properties of a DsbA, including an oxidizing potential, destabilizing disulfide, acidic active site cysteine, and dithiol oxidase catalytic activity. We evaluated a peptide, PWATCDS, derived from the partner protein DsbB and showed by thermal shift and isothermal titration calorimetry that it binds to PmDsbA. The crystal structures of PmDsbA, and the active site variant PmDsbAC30S were determined to high resolution. Analysis of these structures allows categorization of PmDsbA into the DsbA class exemplified by the archetypal Escherichia coli DsbA enzyme. We also present a crystal structure of PmDsbAC30S in complex with the peptide PWATCDS. The structure shows that the peptide binds non-covalently to the active site CXXC motif, the cis-Pro loop, and the hydrophobic groove adjacent to the active site of the enzyme. This high-resolution structural data provides a critical advance for future structure-based design of non-covalent peptidomimetic inhibitors. Such inhibitors would represent an entirely new antibacterial class that work by switching off the DSB virulence assembly machinery.     

Mutants in DsbB that appear to redirect oxidation through the disulfide isomerization pathway

Disulfide bond formation occurs in secreted proteins in Escherichia coli when the disulfide oxidoreductase DsbA, a soluble periplasmic protein, nonspecifically transfers a disulfide to a substrate protein. The catalytic disulfide of DsbA is regenerated by the inner-membrane protein DsbB. To help identify the specificity determinants in DsbB and to understand the nature of the kinetic barrier preventing direct oxidation of newly secreted proteins by DsbB, we imposed selective pressure to find novel mutations in DsbB that would function to bypass the need for the disulfide carrier DsbA. We found a series of mutations localized to a short horizontal α-helix anchored near the outer surface of the inner membrane of DsbB that eliminated the need for DsbA. These mutations changed hydrophobic residues into nonhydrophobic residues. We hypothesize that these mutations may act by decreasing the affinity of this α-helix to the membrane. The DsbB mutants were dependent on the disulfide oxidoreductase DsbC, a soluble periplasmic thiol-disulfide isomerase, for complementation. DsbB is not normally able to oxidize DsbC, possibly due to a steric clash that occurs between DsbC and the membrane adjacent to DsbB. DsbC must be in the reduced form to function as an isomerase. In contrast, DsbA must remain oxidized to function as an oxidizing thiol-disulfide oxidoreductase. The lack of interaction that normally exists between DsbB and DsbC appears to provide a means to separate the DsbA-DsbB oxidation pathway and the DsbC-DsbD isomerization pathway. Our mutants in DsbB may act by redirecting oxidant flow to take place through the isomerization pathway.     

Two cysteines in each periplasmic domain of the membrane protein DsbB are required for its function in protein disulfide bond formation.

DsbB is a protein component of the pathway that leads to disulfide bond formation in periplasmic proteins of Escherichia coli. Previous studies have led to the hypothesis that DsbB oxidizes the periplasmic protein DsbA, which in turn oxidizes the cysteines in other periplasmic proteins to make disulfide bonds. Gene fusion approaches were used to show that (i) DsbB is a membrane protein which spans the membrane four times and (ii) both the N- and C-termini of the protein are in the cytoplasm. Mutational analysis shows that of the six cysteines in DsbB, four are necessary for proper DsbB function in vivo. Each of the periplasmic domains of the protein has two essential cysteines. The two cysteines in the first periplasmic domain are in a Cys-X-Y-Cys configuration that is characteristic of the active site of other proteins involved in disulfide bond formation, including DsbA and protein disulfide isomerase.     

Characterization of the menaquinone-dependent disulfide bond formation pathway of Escherichia coli

In the protein disulfide-introducing system of Escherichia coli, plasma membrane-integrated DsbB oxidizes periplasmic DsbA, the primary disulfide donor. Whereas the DsbA-DsbB system utilizes the oxidizing power of ubiquinone (UQ) under aerobic conditions, menaquinone (MK) is believed to function as an immediate electron acceptor under anaerobic conditions. Here, we characterized MK reactivities with DsbB. In the absence of UQ, DsbB was complexed with MK8 in the cell. In vitro studies showed that, by binding to DsbB in a manner competitive with UQ, MK specifically oxidized Cys41 and Cys44 of DsbB and activated its catalytic function to oxidize reduced DsbA. In contrast, menadione used in earlier studies proved to be a more nonspecific oxidant of DsbB. During catalysis, MK8 underwent a spectroscopic transition to develop a visible violet color (lambdamax = 550 nm), which required a reduced state of Cys44 as shown previously for UQ color development (lambdamax = 500 nm) on DsbB. In an in vitro reaction system of MK8-dependent oxidation of DsbA at 30 degrees C, two reaction components were observed, one completing within minutes and the other taking >1 h. Both of these reaction modes were accompanied by the transition state of MK, for which the slower reaction proceeded through the disulfide-linked DsbA-DsbB(MK) intermediate. The MK-dependent pathway provides opportunities to further dissect the quinone-dependent DsbA-DsbB redox reactions.     

Investigation of the DsbA mechanism through the synthesis and analysis of an irreversible enzyme-ligand complex

Approaching the molecular mechanism of some enzymes is hindered by the difficulty of obtaining suitable protein-ligand complexes for structural characterization. DsbA, the major disulfide oxidase in the bacterial periplasm, is such an enzyme. Its structure has been well characterized in both its oxidized and its reduced states, but structural data about DsbA-peptide complexes are still missing. We report herein an original, straightforward, and versatile strategy for making a stable covalent complex with a cysteine-homoalanine thioether bond instead of the labile cystine disulfide bond which normally forms between the enzyme and polypeptides during the catalytic cycle of DsbA. We substituted a bromohomoalanine for the cysteine in a model 14-mer peptide derived from DsbB (PID-Br), the membrane partner of DsbA. When incubated in the presence of the enzyme, a selective nucleophilic substitution of the bromine by the thiolate of the DsbA Cys(30) occurred. The major advantage of this strategy is that it enables the direct use of the wild-type form of the enzyme, which is the most relevant to obtain unbiased information on the enzymatic mechanism. Numerous intermolecular NOEs between DsbA and PID could be observed by NMR, indicating the presence of preferential noncovalent interactions between the two partners. The thermodynamic properties of the DsbA-PID complex were measured by differential scanning calorimetry. In the complex, the values for both denaturation temperature and variation in enthalpy associated with thermal unfolding were between those of oxidized and reduced forms of DsbA. This progressive increase in stability along the DsbA catalytic pathway strongly supports the model of a thermodynamically driven mechanism.     

Catalysis of disulfide bond formation and isomerization in the Escherichia coli periplasm

Disulfide bond formation is a catalyzed process in vivo. In prokaryotes, the oxidation of cysteine pairs is achieved by the transfer of disulfides from the highly oxidizing DsbA/DsbB catalytic machinery to substrate proteins. The oxidizing power utilized by this system comes from the membrane-embedded electron transport system, which utilizes molecular oxygen as a final oxidant. Proofreading of disulfide bond formation is performed by the DsbC/DsbD system, which has the ability to rearrange non-native disulfides to their native configuration. These disulfide isomerization reactions are sustained by a constant supply of reducing power provided by the cytoplasmic thioredoxin system, utilizing NADPH as the ultimate electron source.     

Randomization of the entire active-site helix alpha 1 of the thiol-disulfide oxidoreductase DsbA from Escherichia coli

DsbA from Escherichia coli is the most oxidizing member of the thiol-disulfide oxidoreductase family (E(o)' = -122 mV) and is required for efficient disulfide bond formation in the periplasm. The reactivity of the catalytic disulfide bond (Cys(30)-Pro(31)-His(32)-Cys(33)) is primarily due to an extremely low pK(a) value (3.4) of Cys(30), which is stabilized by the partial positive dipole charge of the active-site helix alpha1 (residues 30-37). We have randomized all non-cysteine residues of helix alpha1 (residues 31, 32, and 34-37) and found that two-thirds of the resulting variants complement DsbA deficiency in a dsbA deletion strain. Sequencing of 98 variants revealed a large number of non-conservative replacements in active variants, even at well conserved positions. This indicates that tertiary structure context strongly determines alpha-helical secondary structure formation of the randomized sequence. A subset of active and inactive variants was further characterized. All these variants were more reducing than wild type DsbA, but the redox potentials of active variants did not drop below -210 mV. All inactive variants had redox potentials lower than -210 mV, although some of the inactive proteins were still re-oxidized by DsbB. This demonstrates that efficient oxidation of substrate polypeptides is the crucial property of DsbA in vivo.     

A mutation in either dsbA or dsbB, a gene encoding a component of a periplasmic disulfide bond-catalyzing system, is required for high-level expression of the Bacteroides fragilis metallo-beta-lactamase, CcrA, in Escherichia coli.

The metallo-beta-lactamase gene, ccrA, from Bacteroides fragilis is functionally expressed in Escherichia coli only in the presence of a genomic mutation in iarA or iarB (increased ampicillin resistance), identified in this study as dsbA or dsbB, respectively. DsbA and DsbB are components of a periplasmic protein disulfide bond-catalyzing system. Data indicated that DsbA interacted with CcrA, creating aberrant disulfide bond linkages that render CcrA proteolytically unstable. Mutations in dsbA or dsbB permissive for CcrA expression eliminated or greatly reduced DsbA activity, allowing CcrA to assume a disulfide bond-free and proteolytically stable conformation.     

大肠杆菌二硫键形成相关蛋白的结构、功能及其在基因工程表达外源蛋白上的应用

大肠杆菌分泌蛋白二硫键的形成是一系列蛋白协同作用的结果,主要是Dsb家族蛋白,迄今为止共发现了DsbA、DsbB、DsbC、DsbD、DsbE和DsbG。在体内,DsbA负责氧化两个巯基形成二硫键,DsbB则负责DsbA的再氧化。DsbC和DsbG负责校正DsbA导入的异常二硫键,DsbD则负责对DsbC和DsbG进行再还原,DsbE的功能与DsbD类似。除了直接和二硫键的形成相关外,DsbA、DsbC和DsbG都有分子伴侣功能。它们的分子伴侣功能独立于二硫键形成酶的活性并且对二硫键形成酶活性具有明显的促进作用。基于Dsb蛋白的功能特性,利用它们以大肠杆菌为宿主表达外源蛋白,特别是含有二硫键的蛋白,取得了很多成功的例子。本文简要介绍了这方面的进展,显示Dsb蛋白在促进外源蛋白在大肠杆菌中以可溶形式表达方面具有广阔的应用前景。     

Structural analysis of three His32 mutants of DsbA: support for an electrostatic role of His32 in DsbA stability.

DsbA, a 21-kDa protein from Escherichia coli, is a potent oxidizing disulfide catalyst required for disulfide bond formation in secreted proteins. The active site of DsbA is similar to that of mammalian protein disulfide isomerases, and includes a reversible disulfide bond formed from cysteines separated by two residues (Cys30-Pro31-His32-Cys33). Unlike most protein disulfides, the active-site disulfide of DsbA is highly reactive and the oxidized form of DsbA is much less stable than the reduced form at physiological pH. His32, one of the two residues between the active-site cysteines, is critical to the oxidizing power of DsbA and to the relative instability of the protein in the oxidized form. Mutation of this single residue to tyrosine, serine, or leucine results in a significant increase in stability (of approximately 5-7 kcal/mol) of the oxidized His32 variants relative to the oxidized wild-type protein. Despite the dramatic changes in stability, the structures of all three oxidized DsbA His32 variants are very similar to the wild-type oxidized structure, including conservation of solvent atoms near the active-site residue, Cys30. These results show that the His32 residue does not exert a conformational effect on the structure of DsbA. The destabilizing effect of His32 on oxidized DsbA is therefore most likely electrostatic in nature.