Protein hydroxylation: prolyl 4-hydroxylase, an enzyme with four cosubstrates and a multifunctional subunit

Prolyl 4-hydroxylase (EC 1.14.11.2) catalyzes the formation of 4-hydroxyproline in collagens by the hydroxylation of proline residues in X-Pro-Gly sequences. The reaction requires Fe2+, 2-oxoglutarate, O2, and ascorbate and involves an oxidative decarboxylation of 2-oxoglutarate. Ascorbate is not consumed during most catalytic cycles, but the enzyme also catalyzes decarboxylation of 2-oxoglutarate without subsequent hydroxylation, and ascorbate is required as a specific alternative oxygen acceptor in such uncoupled reaction cycles. A number of compounds inhibit prolyl 4-hydroxylase competitively with respect to some of its cosubstrates or the peptide substrate, and recently many suicide inactivators have also been described. Such inhibitors and inactivators are of considerable interest, because the prolyl 4-hydroxylase reaction would seem a particularly suitable target for chemical regulation of the excessive collagen formation found in patients with various fibrotic diseases. The active prolyl 4-hydroxylase is an alpha 2 beta 2 tetramer, consisting of two different types of inactive monomer and probably containing two catalytic sites per tetramer. The large catalytic site may be cooperatively built up of both the alpha and beta subunits, but the alpha subunit appears to contribute the major part. The beta subunit has been found to be identical to the enzyme protein disulfide isomerase and a major cellular thyroid hormone-binding protein and shows partial homology with a phosphoinositide-specific phospholipase C, thioredoxins, and the estrogen-binding domain of the estrogen receptor. The COOH-terminus of this beta subunit has the amino acid sequence Lys-Asp-Glu-Leu, which was recently suggested to be necessary for the retention of a polypeptide within the lumen of the endoplasmic reticulum. The alpha subunit does not have this COOH-terminal sequence, and thus one function of the beta subunit in the prolyl 4-hydroxylase tetramer appears to be to retain the enzyme within this cell organelle.     

Role of ascorbate in oxidative protein folding

Both in prokaryotic and eukaryotic cells, disulfide bond formation (oxidation and isomerization steps) are catalyzed exclusively in extracytoplasmic compartments. In eukaryotes, protein folding and disulfide bond formation are coupled processes that occur both co- and posttranslationally in the endoplasmic reticulum (ER), which is the main site of the synthesis and posttranslational modification of secretory and membrane proteins. The formation of a disulfide bond from the thiol groups of two cysteine residues requires the removal of two electrons, consequently, these bonds cannot form spontaneously; an oxidant is needed to accept the electrons. In aerobic conditions the ultimate electron acceptor is usually oxygen; however, oxygen itself is not effective in protein thiol oxidation. Therefore, a small molecular weight membrane permeable compound should be supposed for the transfer of electrons from the ER lumen. The aim of the present study was the investigation of the role of ascorbate/dehydroascorbate redox couple in oxidative folding of proteins. We demonstrated that ascorbate addition or its in situ synthesis from gulonolactone results in protein thiol (and/or glutathione; GSH) oxidation in rat liver microsomes. Since microsomal membrane is hardly permeable to ascorbate, the existence of a transport metabolon was hypothesized. Three components of the system have been described and partially characterized: (i) A microsomal metalloenzyme is responsible for ascorbate oxidation on the outer surface of the ER. Ascorbate oxidation results in ascorbate free radical and dehydroascorbate production. (ii) Facilitated diffusion of dehydroascorbate is present in microsomal vesicles. The transport is presumably mediated by a GLUT-type transporter. On the contrary, the previously hypothesized glutathione disulfide (GSSG) transport is practically absent, while GSH is transported with a moderate velocity. (iii) Protein disulfide isomerase catalyzes the reduction of dehydroascorbate in the ER lumen. Both GSH and protein thiols can be electron donors in the process. Intraluminal dehydroascorbate reduction and the consequent ascorbate accumulation strictly correlate with protein disulfide isomerase activity and protein thiol concentration. The concerted action of the three components of the system results in the intraluminal accumulation of ascorbate, protein disulfide and GSSG. In fact, intraluminal ascorbate and GSSG accumulation could be observed upon dehydroascorbate and GSH uptake. In conclusion, ascorbate is able to promote protein disulfide formation in an in vitro system. Further work is needed to justify its role in intact cellular and in vivo systems, as well as to explore the participation of other antioxidants (e.g. tocopherol, ubiquinone, and vitamin K) in the electron transfer chain responsible for oxidative protein folding in the ER.     

Protein-disulfide isomerase- and protein thiol-dependent dehydroascorbate reduction and ascorbate accumulation in the lumen of the endoplasmic reticulum

The transport and intraluminal reduction of dehydroascorbate was investigated in microsomal vesicles from various tissues. The highest rates of transport and intraluminal isotope accumulation (using radiolabeled compound and a rapid filtration technique) were found in hepatic microsomes. These microsomes contain the highest amount of protein-disulfide isomerase, which is known to have a dehydroascorbate reductase activity. The steady-state level of intraluminal isotope accumulation was more than 2-fold higher in hepatic microsomes prepared from spontaneously diabetic BioBreeding/Worcester rats and was very low in fetal hepatic microsomes although the initial rate of transport was not changed. In these microsomes, the amount of protein-disulfide isomerase was similar, but the availability of protein thiols was different and correlated with dehydroascorbate uptake. The increased isotope accumulation was accompanied by a higher rate of dehydroascorbate reduction and increased protein thiol oxidation in microsomes from diabetic animals. The results suggest that both the activity of protein-disulfide isomerase and the availability of protein thiols as reducing equivalents can play a crucial role in the accumulation of ascorbate in the lumen of the endoplasmic reticulum. These findings also support the fact that dehydroascorbate can act as an oxidant in the protein-disulfide isomerase-catalyzed protein disulfide formation.     

Prolyl 3-hydroxylase 1, enzyme characterization and identification of a novel family of enzymes

The collagen prolyl hydroxylases are enzymes that are required for proper collagen biosynthesis, folding, and assembly. They reside within the endoplasmic reticulum and belong to the group of 2-oxoglutarate and iron-dependent dioxygenases. Although prolyl 4-hydroxylase has been characterized as an alpha2beta2 tetramer in which protein disulfide isomerase is the beta subunit with two different alpha subunit isoforms, little is known about the enzyme prolyl 3-hydroxylase (P3H). It was initially characterized and shown to have an enzymatic activity distinct from that of prolyl 4-hydroxylase, but no amino acid sequences or genes were ever reported for the mammalian enzyme. Here we report the characterization of a novel prolyl 3-hydroxylase enzyme isolated from embryonic chicks. The primary structure of the enzyme, which we now call P3H1, demonstrates that P3H1 is a member of a family of prolyl 3-hydroxylases, which share the conserved residues present in the active site of prolyl 4-hydroxylase and lysyl hydroxylase. P3H1 is the chick homologue of mammalian leprecan or growth suppressor 1. Two other P3H family members are the genes previously called MLAT4 and GRCB. In this study we demonstrate prolyl 3-hydroxylase activity of the purified enzyme P3H1 on a full-length procollagen substrate. We also show it to specifically interact with denatured collagen and to exist in a tight complex with other endoplasmic reticulum-resident proteins. Immunohistochemistry with a monoclonal antibody specific for chick P3H1 localizes P3H1 specifically to tissues that express fibrillar collagens, suggesting that other P3H family members may be responsible for modifying basement membrane collagens.     

Iron-dependent uptake of ascorbate into isolated microsomes

A preliminary study (J.M. Mata, R. Assad, and B. Peterkofsky (1981) Arch. Biochem. Biophys. 206, 93-104) suggested that chick embryo limb bone microsomes took up and concentrated [14C]ascorbate in the presence of cofactors for prolyl hydroxylase. In the present study, we found that the apparent Km for ascorbate in the hydroxylation of intracisternal unhydroxylated procollagen by endogenous prolyl hydroxylase was approximately an order of magnitude less than the value obtained when enzyme solubilized from microsomes was used with an exogenous substrate. These results are compatible with a concentrative uptake of ascorbate into microsomes. The uptake of [14C]ascorbate into microsomes was confirmed and it required only iron, in either the ferrous or ferric form, and was time and temperature dependent, proportional to microsome concentration, and substrate saturable at 2-3 mM ascorbate. Iron-dependent ascorbate uptake also was observed with L-929 cell microsomes. [14C]Ascorbate seemed to be taken up without prior oxidation, since only unlabeled ascorbate, and not dehydroascorbate, competed for uptake into limb bone microsomes. A functional requirement for Fe2+ in ascorbate transport was demonstrated using the intracisternal proline hydroxylating system. L-929 cell microsomes were preincubated with ascorbate with or without the metal and then external ascorbate was oxidized to inactive dehydroascorbate using ascorbic acid oxidase, which cannot penetrate the microsomal membrane. Samples which did not receive iron during the preincubation received it, along with other requirements for prolyl hydroxylase, in a final incubation to measure hydroxylation. Significant hydroxylation was obtained only in samples incubated with iron prior to oxidase treatment, consistent with the conclusion that an iron-dependent process was required to translocate ascorbate and protect it from the oxidase.     

The acidic C-terminal domain of protein disulfide isomerase is not critical for the enzyme subunit function or for the chaperone or disulfide isomerase activities of the polypeptide.

Protein disulfide isomerase (PDI) is a multifunctional polypeptide that acts as a subunit in the animal prolyl 4-hydroxylases and the microsomal triglyceride transfer protein, and as a chaperone that binds various peptides and assists their folding. We report here that deletion of PDI sequences corresponding to the entire C-terminal domain c, previously thought to be critical for chaperone activity, had no inhibitory effect on the assembly of recombinant prolyl 4-hydroxylase in insect cells or on the in vitro chaperone activity or disulfide isomerase activity of purified PDI. However, partially overlapping critical regions for all these functions were identified at the C-terminal end of the preceding thioredoxin-like domain a'. Point mutations introduced into this region identified several residues as critical for prolyl 4-hydroxylase assembly. Circular dichroism spectra of three mutants suggested that two of these mutations may have caused only local alterations, whereas one of them may have led to more extensive structural changes. The critical region identified here corresponds to the C-terminal alpha helix of domain a', but this is not the only critical region for any of these functions.     

An Additional Function of the Rough Endoplasmic Reticulum Protein Complex Prolyl 3-Hydroxylase 1·Cartilage-associated Protein·Cyclophilin B: THE CXXXC MOTIF REVEALS DISULFIDE ISOMERASE ACTIVITY IN VITRO*

Collagen biosynthesis occurs in the rough endoplasmic reticulum, and many molecular chaperones and folding enzymes are involved in this process. The folding mechanism of type I procollagen has been well characterized, and protein disulfide isomerase (PDI) has been suggested as a key player in the formation of the correct disulfide bonds in the noncollagenous carboxyl-terminal and amino-terminal propeptides. Prolyl 3-hydroxylase 1 (P3H1) forms a hetero-trimeric complex with cartilage-associated protein and cyclophilin B (CypB). This complex is a multifunctional complex acting as a prolyl 3-hydroxylase, a peptidyl prolyl cis-trans isomerase, and a molecular chaperone. Two major domains are predicted from the primary sequence of P3H1: an amino-terminal domain and a carboxyl-terminal domain corresponding to the 2-oxoglutarate- and iron-dependent dioxygenase domains similar to the α-subunit of prolyl 4-hydroxylase and lysyl hydroxylases. The amino-terminal domain contains four CXXXC sequence repeats. The primary sequence of cartilage-associated protein is homologous to the amino-terminal domain of P3H1 and also contains four CXXXC sequence repeats. However, the function of the CXXXC sequence repeats is not known. Several publications have reported that short peptides containing a CXC or a CXXC sequence show oxido-reductase activity similar to PDI in vitro. We hypothesize that CXXXC motifs have oxido-reductase activity similar to the CXXC motif in PDI. We have tested the enzyme activities on model substrates in vitro using a GCRALCG peptide and the P3H1 complex. Our results suggest that this complex could function as a disulfide isomerase in the rough endoplasmic reticulum.     

Oxidative protein folding in eukaryotes: mechanisms and consequences

The endoplasmic reticulum (ER) provides an environment that is highly optimized for oxidative protein folding. Rather than relying on small molecule oxidants like glutathione, it is now clear that disulfide formation is driven by a protein relay involving Ero1, a novel conserved FAD-dependent enzyme, and protein disulfide isomerase (PDI); Ero1 is oxidized by molecular oxygen and in turn acts as a specific oxidant of PDI, which then directly oxidizes disulfide bonds in folding proteins. While providing a robust driving force for disulfide formation, the use of molecular oxygen as the terminal electron acceptor can lead to oxidative stress through the production of reactive oxygen species and oxidized glutathione. How Ero1p distinguishes between the many different PDI-related proteins and how the cell minimizes the effects of oxidative damage from Ero1 remain important open questions.     

A Novel Reaction of Peroxiredoxin 4 towards Substrates in Oxidative Protein Folding

Peroxiredoxin 4 (Prx4) is the only endoplasmic reticulum localized peroxiredoxin. It functions not only to eliminate peroxide but also to promote oxidative protein folding via oxidizing protein disulfide isomerase (PDI). In Prx4-mediated oxidative protein folding we discovered a new reaction that the sulfenic acid form of Prx4 can directly react with thiols in folding substrates, resulting in non-native disulfide cross-linking and aggregation. We also found that PDI can inhibit this reaction by exerting its reductase and chaperone activities. This discovery discloses an off-pathway reaction in the Prx4-mediated oxidative protein folding and the quality control role of PDI.     

Ascorbate is consumed stoichiometrically in the uncoupled reactions catalyzed by prolyl 4-hydroxylase and lysyl hydroxylase

The hydroxylation of proline and lysine residues by the collagen hydroxylases is coupled with a stoichiometric decarboxylation of 2-oxoglutarate. Ascorbate is virtually a specific requirement for these enzymes, but previous studies have demonstrated that it is not consumed during most catalytic cycles. Prolyl 4-hydroxylase and lysyl hydroxylase are known also to catalyze an uncoupled decarboxylation of 2-oxoglutarate in the absence of the peptide substrate. It is shown here that, unlike the complete hydroxylation reaction, the uncoupled decarboxylation reaction involves stoichiometric ascorbate consumption. This stoichiometric ascorbate consumption was also seen when the rate of the uncoupled prolyl 4-hydroxylase reaction was enhanced by the addition of poly(L-proline). Since collagen hydroxylases may catalyze occasional uncoupled reaction cycles even in the presence of the peptide substrates, the main function of ascorbate in these reactions in vivo is suggested to be that of reactivating the enzymes after such uncoupled cycles.     

Concomitant hydroxylation of proline and lysine residues in collagen using purified enzymes in vitro

Concomitant hydroxylation of proline and lysine residues in protocollagen was studied using purified enzymes. The data suggest that prolyl 4-hydroxylase (prolyl-glycyl-peptide, 2-oxoglutarate: oxygen oxidoreductase (4-hydroxylating), EC 1.14.11.2) and lysyl hydroxylase (peptidyllysine, 2-oxoglutarate; oxygen 5-oxidoreductase, EC 1.14.11.4) are competing for the protocollagen substrate, this competition resulting in an inhibition of the lysyl hydroxylase but not of the prolyl 4-hydroxylase reaction. When the same protocollagen was used for these hydroxylases, the affinity of prolyl 4-hydroxylase to the protocollagen substrate was about 2-fold higher than that of lysyl hydroxylase. Hydroxylation of lysine residues in protocollagen had no effect on the affinity of prolyl 4-hydroxylase, whereas hydroxylation of proline residues decreased the affinity of lysyl hydroxylase to one-half of the value determined before the hydroxylation. When enzyme preparations containing different ratios of lysyl hydroxylase activity to prolyl 4-hydroxylase activity were used to hydroxylase protocollagen substrate, it was found that in the case of a low ratio the hydroxylation of lysine residues seemed to proceed only after a short lag period. Accordingly, it seems probable that most proline residues are hydroxylated to 4-hydroxyproline residues before hydroxylation of lysine residues if the prolyl 4-hydroxylase and lysyl hydroxylase are present as free enzymes competing for the same protocollagen substrate.     

The function of ascorbate with respect to prolyl 4-hydroxylase activity

1. Incubation in the presence of 2-oxoglutarate and oxygen inactivates prolyl 4-hydroxylase (prolyl-glycyl-peptide, 2-oxoglutarate:oxygen oxidoreductase, EC 1.14.11.2), with a t 1/2 of 80 s at 37 degrees C. This inactivation is not affected by the presence or absence of the prolyl peptide substrate or added Fe(II). 2. This inactivation can be prevented by either ascorbate or dithiothreitol. It can be reversed by dithiothreitol but not by ascorbate. 3. Although the iron-containing form of prolyl 4-hydroxylase requires ascorbate for activity, ascorbate is not stoicheiometrically consumed in the reaction catalysed by the enzyme. Ascorbate cannot be replaced by alloxan, lactate, NADH plus phenazine methosulphate, dithiothreitol or L-cysteine. 4. Ascorbate has a double function with respect to prolyl 4-hydroxylase activity. On the one hand, it is required to initiate the reaction when the enzyme has become oxidized during isolation. On the other hand it is required for the protection against inactivation induced by 2-oxoglutarate and oxygen, presumably by preventing S-S bridge formation. The latter function may be of physiological importance.     

Reductive unfolding and oxidative refolding of a Bowman-Birk inhibitor from horsegram seeds (Dolichos biflorus): evidence for "hyperreactive" disulfide bonds and rate-limiting nature of disulfide isomerization in folding

Horsegram protease inhibitor belongs to the Bowman-Birk class (BBIs) of low molecular weight (8-10 kDa), disulfide-rich, "dual" inhibitors, which can bind and inhibit trypsin and chymotrypsin either independently or simultaneously. They have seven conserved disulfide bonds. Horsegram BBI exhibits remarkable stability against denaturants like urea, guanidine hydrochloride (GdmCl) and heat, which can be attributed to these conserved disulfide bonds. On reductive denaturation, horsegram BBI follows the "two-state" mode of unfolding where all the disulfide bonds are reduced simultaneously resulting in the fully reduced protein without any accumulation of partially reduced intermediates. Reduction with dithiothreitol (DTT) followed apparent first-order kinetics and the rate constants (k(r)) indicated that the disulfide bonds were "hyperreactive" in nature. Oxidative refolding of the fully reduced and denatured inhibitor was possible at very low protein concentration in the presence of "redox" combination of reduced and oxidized glutathiones. Simultaneous recovery of trypsin and chymotryptic inhibitory activities indicated the concomitant folding of both the inhibitory subdomains. Folding efficiency decreased in the absence of the glutathiones and in the presence of denaturants (6 M urea and 4 M GdmCl), indicating the importance of disulfide shuffling and the formation of noncovalent interactions and secondary structural elements, respectively, for folding efficiency. Folding rate was significantly improved in the presence of protein disulfide isomerase (PDI). A 3-fold enhancement of rate was observed in the presence of PDI at molar ratio of 1:20 (PDI/inhibitor), indicating that disulfide bond formation and isomerization to be rate limiting in folding. Peptide prolyl cis-trans isomerase (PPI) did not affect rate at low concentrations, but at molar ratios of 1:1.5 (PPI/inhibitor), there was 1.4-fold enhancement of the folding rate, indicating that the prolyl imidic bond isomerizations may be slowing down the folding reaction but were not rate limiting.     

Oxidative protein folding by an endoplasmic reticulum-localized peroxiredoxin

Endoplasmic reticulum (ER) oxidation 1 (ERO1) transfers disulfides to protein disulfide isomerase (PDI) and is essential for oxidative protein folding in simple eukaryotes such as yeast and worms. Surprisingly, ERO1-deficient mammalian cells exhibit only a modest delay in disulfide bond formation. To identify ERO1-independent pathways to disulfide bond formation, we purified PDI oxidants with a trapping mutant of PDI. Peroxiredoxin IV (PRDX4) stood out in this list, as the related cytosolic peroxiredoxins are known to form disulfides in the presence of hydroperoxides. Mouse embryo fibroblasts lacking ERO1 were intolerant of PRDX4 knockdown. Introduction of wild-type mammalian PRDX4 into the ER rescued the temperature-sensitive phenotype of an ero1 yeast mutation. In the presence of an H(2)O(2)-generating system, purified PRDX4 oxidized PDI and reconstituted oxidative folding of RNase A. These observations implicate ER-localized PRDX4 in a previously unanticipated, parallel, ERO1-independent pathway that couples hydroperoxide production to oxidative protein folding in mammalian cells.     

Efficient folding of the insect neuropeptide eclosion hormone by protein disulfide isomerase.

Eclosion hormone is an insect neuropeptide that consists of 62 amino acid residues including three disulfide bonds. We have previously reported its hypothetical 3D structure consisting mainly of three alpha-helices. In this paper, we report the effects of chaperone proteins on the refolding of denatured eclosion hormone in a redox buffer containing reduced and oxidized glutathione. Urea-denatured eclosion hormone was spontaneously reactivated within 1 min with a yield of more than 90%, while beta-mercaptoethanol-denatured eclosion hormone was reactivated in a few minutes with a yield of 75%. Under the same experimental conditions, eclosion hormone treated with beta-mercaptoethanol and urea was reactivated slowly with a yield of 47% over a period of 2 h. Protein disulfide isomerase, a eucaryotic chaperone protein, markedly increased the reactivation yield and rate of the totally denatured hormone. GroE oligomers slightly improved the reactivation yield but peptidyl prolyl isomerase had no influence on yield or rate. We propose that the folding pathway of eclosion hormone involves at least two rate-limiting steps, and that protein disulfide isomerase is likely to be involved in the folding in insect neuronal cells.     

Substrate recognition by the protein disulfide isomerases

Protein folding in the endoplasmic reticulum is often associated with the formation of native disulfide bonds. Their primary function is to stabilize the folded structure of the protein, although disulfide bond formation can also play a regulatory role. Native disulfide bond formation is not trivial, so it is often the rate-limiting step of protein folding both in vivo and in vitro. Complex coordinated systems of molecular chaperones and protein folding catalysts have evolved to help proteins attain their correct folded conformation. This includes a family of enzymes involved in catalyzing thiol-disulfide exchange in the endoplasmic reticulum, the protein disulfide isomerase (PDI) family. There are now 17 reported PDI family members in the endoplasmic reticulum of human cells, but the functional differentiation of these is far from complete. Despite PDI being the first catalyst of protein folding reported, there is much that is still not known about its mechanisms of action. This review will focus on the interactions of the human PDI family members with substrates, including recent research on identifying and characterizing their substrate-binding sites and on determining their natural substrates in vivo.     

Is protein disulfide isomerase a redox-dependent molecular chaperone?

Protein disulfide isomerase (PDI) is a multifunctional protein catalysing the formation of disulfide bonds, acting as a molecular chaperone and being a component of the enzymes prolyl 4-hydroxylase (P4H) and microsomal triglyceride transfer protein. The role of PDI as a molecular chaperone or polypeptide-binding protein is mediated primarily through an interaction of substrates with its b' domain. It has been suggested that this binding is regulated by the redox state of PDI, with association requiring the presence of glutathione, and dissociation the presence of glutathione disulfide. To determine whether this is the case, we investigated the ability of PDI to bind to a folding polypeptide chain within a functionally intact endoplasmic reticulum and to be dissociated from the alpha-subunit of P4H in vitro in the presence of reducing or oxidizing agents. Our results clearly demonstrate that binding of PDI to these polypeptides is not regulated by its redox state. We also demonstrate that the dissociation of PDI from substrates observed in the presence of glutathione disulfide can be explained by competition for the peptide-binding site on PDI.     

Glutathione-dependent ascorbate recycling activity of rat serum albumin

An efficient regeneration of vitamin C (ascorbate) from its oxidized byproduct, dehydroascorbate (DHAA), is necessary to maintain sufficient tissue levels of the reduced form of the vitamin. Additionally, the recycling may be more significant in mammals, such as guinea pigs and humans, who have lost the ability to synthesize ascorbate de novo, than it is in most other mammals who have retained the ability to synthesize the vitamin from glucose. Both a chemical and an enzymatic reduction of DHAA to ascorbate have been proposed. Several reports have appeared in which proteins, including thioltransferase, protein disulfide isomerase, and 3-alpha-hydroxysteroid dehydrogenase, characterized for other activities have been identified as having DHAA reductase activity in vitro. Whether these previously characterized proteins catalyze the reduction of DHAA in vivo is unclear. In the present study, a 66 kD protein was purified strictly on the basis of its DHAA-reductase activity and was identified as rat serum albumin. The protein was further characterized and results support the suggestion that serum albumin acts as an antioxidant and exerts a significant glutathione-dependent DHAA-reductase activity that may be important in the physiologic recycling of ascorbic acid.     

Crystal structure of the protein disulfide bond isomerase, DsbC, from Escherichia coli

DsbC is one of five Escherichia coli proteins required for disulfide bond formation and is thought to function as a disulfide bond isomerase during oxidative protein folding in the periplasm. DsbC is a 2 x 23 kDa homodimer and has both protein disulfide isomerase and chaperone activity. We report the 1.9 A resolution crystal structure of oxidized DsbC where both Cys-X-X-Cys active sites form disulfide bonds. The molecule consists of separate thioredoxin-like domains joined via hinged linker helices to an N-terminal dimerization domain. The hinges allow relative movement of the active sites, and a broad uncharged cleft between them may be involved in peptide binding and DsbC foldase activities.