Significance of Thiol-Disulfide Exchange in Resting Stages of Plant Development

Abstract: Desiccation tolerance is a fundamental principle for resting stages of plant development which include the dormancy of seeds and the quiescent stages of resurrection plants. To prevent the deleterious effects of cellular desiccation, a complex interplay of several adaption mechanisms is required. The ability to cope with free radicals, the formation of which is well documented in desiccated tissues, is one of these basic requirements. Detoxification of free radicals by several antioxidants and scavenging enzymes include reactions of reduced glutathione (GSH) resulting in the formation of glutathione disulfide (GSSG). In free radical processing pathways GSSG is considered to be immediately reduced back to GSH by the action of glutathione reductase (EC 1.6.4.2.). However, in desiccated tissues GSSG accumulates. Protein-glutathione mixed disulfides (PSSG) are also reported to increase in plants under drought leading to the hypothesis that glutathione protects protein thiol groups from auto-oxidation. The irreversible formation of intramolecular disulfides resulting in denaturation of proteins would be one of the primary sites of desiccation injury. We suggest that PSSG is formed by the reaction of GSSG with high molecular weight thiols and introduce a thiol-disulfide cycle that involves reduction/oxidation processes of glutathione and protein thiol groups during the dehydration/rehydration processes in desiccation tolerant tissues.     

Reexamination of the role of interplay between glutathione and protein disulfide isomerase

Protein disulfide isomerase (PDI) has an essential role in the process of disulfide bond formation, where it catalyzes disulfide bond formation, reduction, and isomerization. It is thought that the major route for oxidizing dithiols in folding proteins to disulfides is via Ero1-mediated oxidation of PDI. Since the discovery of Ero1, the role of glutathione in disulfide bond formation has been downplayed. In this study, the role of glutathione in disulfide bond formation was reexamined. Here we have studied in vitro the kinetics of the glutathione-mediated oxidation and reduction of the catalytic a domains of human PDI and yeast Pdi1p. The results obtained from stopped-flow and quenched-flow experiments show that the reactions of PDI and Pdi1p are faster and more complex than previously thought. Our results suggest that the kinetics of oxidation of PDI and Pdi1p by oxidized glutathione are remarkably similar, whereas the kinetics of reduction by reduced glutathione shows clear differences. The data generated here on the rapid reactivity of PDI towards glutathione suggest that reevaluation is required for several aspects of the field of catalyzed disulfide bond formation, including the potential physiological role of glutathione.     

Donor substrate specificity and thiol reduction of glutathione disulfide peroxidase.

By isolation of a mixed disulfide product of glutathione and cysteine, glutathione peroxidase was shown to be highly specific for only one donor substrate. Using the coupled assay of NADPH and yeast glutatione reductase, which is highly specific for flutathione disulfide, it was shown that the apparent inhibition of glutathione peroxidase by mercaptoethanol can be described kinetically and that it is competitive with glutathione. Also, when limiting amounts of hydroperoxide were present in the reaction mixture with mercaptoethanol or cysteine, the total amount of glutathione disulfide produced decreased as compared with that in a reaction mixture without mercaptoethanol or cysteine. This finding is consistent with enzymatic formation of mixed disulfides. Data presented suggest that the selenium in glutathione peroxidase was oxidized to a seleninic acid in the absence of glutathione. These results can be explained by a mechanism for glutathione peroxidase wherein the selenium atom is the only atom in the enzyme that undergoes oxidation reduction.     

Glucagon activation of the thiol:protein disulfide oxidoreductase in isolated, rat, hepatic microsomes

The hepatic, microsomal, thiol:protein disulfide oxidoreductase catalyzes the glutathione (GSH) reduction of protein disulfides to sulfhydryl groups. In the presence of physiological concentrations of glucagon this activity increased from 2.3 to 6.4 fold in isolated microsomes. The stimulation had a P50 for glucagon of 7.8 X 10(-10) M which was only observed at microsomal protein concentrations of less than 100 micrograms/ml and in the presence of a GSH reducing system. This latter observation suggests that the stimulation may be inhibited by the presence of oxidized glutathione. These data support the hypothesis that glucagon may act in part by stimulating the reduction of protein disulfides by the thiol:protein disulfide oxidoreductase.     

Early intermediates in the PDI-assisted folding of ribonuclease A

The oxidative refolding of ribonuclease A has been investigated in several experimental conditions using a variety of redox systems. All these studies agree that the formation of disulfide bonds during the process occurs through a nonrandom mechanism with a preferential coupling of certain cysteine residues. We have previously demonstrated that in the presence of glutathione the refolding process occurs through the reiteration of two sequential reactions: a mixed disulfide with glutathione is produced first which evolves to form an intramolecular S-S bond. In the same experimental conditions, protein disulfide isomerase (PDI) was shown to catalyze formation and reduction of mixed disulfides with glutathione as well as formation of intramolecular S-S bonds. This paper reports the structural characterization of the one-disulfide intermediate population during the oxidative refolding of Ribonuclease A under the presence of PDI and glutathione with the aim of defining the role of the enzyme at the early stages of the reaction. The one-disulfide intermediate population occurring at the early stages of both the uncatalyzed and the PDI-catalyzed refolding was purified and structurally characterized by proteolytic digestion followed by MALDI-MS and LC/ESIMS analyses. In the uncatalyzed refolding, a total of 12 disulfide bonds out of the 28 theoretical possible cysteine couplings was observed, confirming a nonrandom distribution of native and nonnative disulfide bonds. Under the presence of PDI, only two additional nonnative disulfides were detected. Semiquantitative LC/ESIMS analysis of the distribution of the S-S bridged peptides showed that the most abundant species were equally populated in both the uncatalyzed and the catalyzed process. This paper shows the first structural characterization of the one-disulfide intermediate population formed transiently during the refolding of ribonuclease A in quasi-physiological conditions that mimic those present in the ER lumen. At the early stages of the process, three of the four native disulfides are detected, whereas the Cys26-Cys84 pairing is absent. Most of the nonnative disulfide bonds identified are formed by nearest-neighboring cysteines. The presence of PDI does not significantly alter the distribution of S-S bonds, suggesting that the ensemble of single-disulfide species is formed under thermodynamic control.     

Microsomal mixed-function oxidase-dependent renaturation of reduced ribonuclease

A purified hepatic microsomal mixed-function drug oxidase (EC 1.14.13.8) catalyzes oxidation of cysteamine to cystamine. Since cysteamine is a normal intracellular metabolite, this reaction could provide an enzymic mechanism for the continuous generation of disulfides required for formation of disulfide bonds in newly synthesized proteins. This hypothesis was tested by studying the renaturation of reduced ribonuclease in media containing glutathione reductase, purified microsomal oxidase, an NADPH-generating system, and physiological concentrations of glutathione and cysteamine. Under these conditions renaturation of reduced-disorganized ribonuclease is completely dependent upon the microsomal oxidase, and optimal renaturation rates are obtained when the relative activities of glutathione reductase and cysteamine oxidase approximate levels present in whole liver homogenates.     

Kinetics of disulfide exchange reactions of monomer and dimer loops of cysteine-valine-cysteine peptides

Rate constants have been determined in 3 M guanidine hydrochloride for disulfide exchange reactions between glutathione and two synthetic peptides containing a cysteine-valine-cysteine region. Equilibrium experiments demonstrate the absence of noncovalent peptide aggregation in this solvent. Procedures are given for separating seven different components in quenched reactions, including the fully reduced cysteine cluster, the monomeric disulfide loop, parallel and antiparallel dimer loops, and the three monomers containing one or two mixed disulfides with glutathione. Intramolecular rate constants for (1) formation of a sterically strained monomer loop, (2) transfer of glutathione between the two cysteines on the same peptide chain, and (3) formation of unstrained dimer loops correspond to a series of processes forming rings of increasing size. In one sequence, these rate constants are 3, 6, and about 21 s-1, respectively. The larger loops are formed more easily. In the other sequence, rate constants for formation and opening of monomer loops are accelerated 180- and 1300-fold, respectively, relative to analogous reactions in a peptide containing eight residues between the two cysteines. This gives a 7-fold smaller equilibrium constant for ring closure in the cysteine cluster. Dimer formation occurs by a mechanism utilizing the accelerated opening of monomer loops. Results provide information assisting efforts to develop strategies for directing disulfide pairing in novel protein structures. Results also help define factors contributing to formation of undesired oligomers during efforts to refold cysteine-containing proteins obtained by bacterial expression of mammalian genes.     

Catalysis of thiol/disulfide exchange: single-turnover reduction of protein disulfide-isomerase by glutathione and catalysis of peptide disulfide reduction

Protein disulfide-isomerase, a protein localized to the lumen of the endoplasmic reticulum of eukaryotic cells, catalyzes the posttranslational formation and rearrangement of protein disulfide bonds. As isolated from bovine liver, the enzyme contains 0.8 free sulfhydryl group per mole of protein monomer and 3.1 disulfide bonds. Single-turnover experiments in which the disulfide bonds of the native enzyme are reduced by glutathione reveal three distinct reduction steps corresponding to the sequential reduction of the three disulfide bonds. The fastest disulfide to be reduced undergoes a change in the rate-determining step with increasing GSH concentration from a step which is second-order with respect to GSH concentration to a step which is first-order in GSH concentration. The disulfide which is reduced at an intermediate rate displays kinetics that are first-order in GSH concentration, and the slowest disulfide to be reduced exhibits kinetics which are second-order in GSH concentration. The enzyme catalyzes the steady-state reduction of a disulfide-containing hexapeptide (CYIQNC) by GSH. Initial velocity kinetic experiments are consistent with a sequential addition of the substrates to the enzyme. Saturation behavior is not observed at high levels of both substrates (Km for GSH much greater than 14 mM, Km for CYIQNC much greater than 1 mM). Only one of the three disulfides appears to be kinetically competent in the steady-state reduction of CYIQNC by GSH. The second-order thiol/disulfide exchange reactions catalyzed by the enzyme are 400-6000-fold faster than the corresponding uncatalyzed reactions.     

Disulfide Bond Formation in the Mammalian Endoplasmic Reticulum

The formation of disulfide bonds between cysteine residues occurs during the folding of many proteins that enter the secretory pathway. As the polypeptide chain collapses, cysteines brought into proximity can form covalent linkages during a process catalyzed by members of the protein disulfide isomerase family. There are multiple pathways in mammalian cells to ensure disulfides are introduced into proteins. Common requirements for this process include a disulfide exchange protein and a protein oxidase capable of forming disulfides de novo. In addition, any incorrect disulfides formed during the normal folding pathway are removed in a process involving disulfide exchange. The pathway for the reduction of disulfides remains poorly characterized. This work will cover the current knowledge in the field and discuss areas for future investigation.One of the characteristics of proteins that enter the secretory pathway is that they frequently contain covalent linkages called disulfide bonds within and between constituent polypeptide chains. The presence of these linkages is thought to confer stability when secreted proteins are exposed to the extracellular milieu or when membrane proteins are recycled through acidic endocytic compartments. In addition to structural disulfides it is now clear that a number of proteins use the formation and breaking of disulfides as a mechanism for regulation of activity (Schwertassek et al. 2007). Hence, it is important that we have a clear understanding of how correct disulfides are formed within proteins both during the protein folding process and to regulate protein function. The focus of this article will be on how correct disulfides are introduced into proteins within the secretory pathway, specifically within the endoplasmic reticulum (ER) during folding and assembly.The formation of disulfides within polypeptides begins as the protein is being cotranslationally translocated into the ER (Chen et al. 1995). The initial collapse of the polypeptide and formation of secondary structure brings cysteine residues into close enough proximity for them to form disulfides. Correct disulfide formation requires enzymes to both introduce disulfides between proximal cysteines and to reduce disulfides that form during folding but that are not present in the final native structure (Jansens et al. 2002). In addition, proteins that do not fold correctly are targeted for degradation and may require their disulfides to be broken before dislocation across the ER membrane into the cytosol (Ushioda et al. 2008). Hence, there must be a reduction and oxidation pathway present in the ER to ensure that native disulfides form and nonnative disulfides are broken during protein folding.Central to both reduction and oxidation pathways is the protein disulfide isomerase (PDI) family of enzymes (Ellgaard and Ruddock 2005) that are capable of exchanging disulfides with their substrate proteins (Fig. 1). Whether disulfide exchange results in the formation or breaking of a disulfide depends on the relative stability of the disulfides in the enzyme and substrate. To drive the formation of disulfides, the PDI family member must itself be oxidized. It is now clear that there are a number of ways for the disulfide exchange proteins to be oxidized by specific oxidases. Importantly, these oxidases do not introduce disulfides into nascent polypeptide chains; rather, they specifically oxidize members of the PDI family. The exception to this rule is the enzyme quiescin sulfydryl oxidase (QSOX; see below). The pathway for disulfide reduction is not as well characterized. It is known that the PDI family members can be reduced by the low molecular mass thiol glutathione (GSH) (Chakravarthi and Bulleid 2004; Jessop and Bulleid 2004; Molteni et al. 2004) but no enzymatic process for reduction has been identified. The glutathione redox balance within the ER is significantly more oxidized than in the cytosol (Hwang et al. 1992; Dixon et al. 2008), indicating that GSH is actively oxidized to glutathione disulfide either during the reduction of PDI family members or by reducing disulfides in nascent polypeptides directly. However, there is currently no clear indication as to how glutathione disulfide is itself reduced.Open in a separate windowFigure 1.PDI family of enzymes catalyzes disulfide exchange reactions in the endoplasmic reticulum. Nascent polypeptide chains are cotranslationally translocated across the ER membrane whereupon cysteines in close proximity can form disulfides. The reaction is catalyzed by members of the PDI family (depicted as PDI) by a disulfide exchange reaction resulting in the reduction of the PDI active site. If nonnative disulfides are formed these can be reduced by the reverse disulfide exchange reaction, resulting in the oxidation of the PDI active site.Both the formation and breaking of disulfides can be thought of as electron transport pathways that require suitable electron acceptors or donors to drive the flow of electrons. For the purposes of this article the two pathways will be discussed separately, but it should be appreciated that each pathway occurs within the same organelle so the possibility of crossover between them is real. Whether futile redox reactions occur between the pathways is unclear but any kinetic segregation of the pathways will be highlighted where it is known to occur.     

Protein disulfide-isomerase is a substrate for thioredoxin reductase and has thioredoxin-like activity

We have demonstrated that calf liver protein disulfide-isomerase (Mr 57,000) is a substrate for calf thymus thioredoxin reductase and catalyzes NADPH-dependent insulin disulfide reduction. This reaction can be used as a simple assay for protein disulfide-isomerase during purification in place of the classical method of reactivation of incorrectly oxidized ribonuclease A. Protein disulfide-isomerase contains two redox-active disulfides/molecule which were reduced by NADPH and calf thioredoxin reductase (Km approximately 35 microM). The isomerase was a poor substrate for NADPH and Escherichia coli thioredoxin reductase, but the addition of E. coli thioredoxin resulted in rapid reduction of two disulfides/molecule. Tryptophan fluorescence spectra were shown to monitor the redox state of protein disulfide-isomerase. Fluorescence measurements demonstrated that thioredoxin--(SH)2 reduced the disulfides of the isomerase and allowed the kinetics of the reaction to be followed; the reaction was also catalyzed by calf thioredoxin reductase. Equilibrium measurements showed that the apparent redox potential of the active site disulfide/dithiols of the thioredoxin domains of protein disulfide-isomerase was about 30 mV higher than the disulfide/dithiol of E. coli thioredoxin. Consistent with this, experiments using dithiothreitol or NADPH and thioredoxin reductase-dependent reduction and precipitation of insulin demonstrated differences between protein disulfide-isomerase and thioredoxin, thioredoxin being a better disulfide reductase but less efficient isomerase. Protein disulfide-isomerase is thus a high molecular weight member of the thioredoxin system, able to interact with both mammalian NADPH-thioredoxin reductase and reduced thioredoxin. This may be important for nascent protein disulfide formation and other thiol-dependent redox reactions in cells.     

Role of thiamine thiol form in nitric oxide metabolism

In alkaline media the thiamine cyclic form is converted into a thiol form (pK(a) 9.2) with an opened thiazole ring. The thiamine thiol form releases nitric oxide from S-nitrosoglutathione (GSNO). Thiamine disulfide, mixed thiamine disulfide with glutathione, and nitric oxide are produced in the reaction. Free glutathione was recorded in small amounts. The concentration of formed nitric oxide agreed well with the concentration of degraded GSNO. The concentration of released nitric oxide was determined under anaerobic conditions spectrophotometrically by production of nitrosohemoglobin. In air, the release of nitric oxide was recorded by the production of nitrite or the oxidation of oxyhemoglobin to methemoglobin. The concentration of the thiol form in the body under physiological pH values (7.2-7.4) did not exceed 1.5-2.0%. We believe that due to the exchange reactions between the thiamine thiol form and S-nitrosocysteine protein residues, nitric oxide can be released and mixed thiamine-protein disulfides are formed. The mixed thiamine disulfides (including thiamine ester disulfides) as well as the thiamine disulfide form are quite easily reduced by low molecular weight thiols to form the thiamine cyclic form with a closed thiazole ring. A possible role of the thiamine thiol form in releasing deposited nitric oxide from low-molecular-weight S-nitrosothiols and protein S-nitrosothiols and in regulation of blood flow in the vascular bed is discussed.     

Structural basis for target protein recognition by the protein disulfide reductase thioredoxin

Thioredoxin is ubiquitous and regulates various target proteins through disulfide bond reduction. We report the structure of thioredoxin (HvTrxh2 from barley) in a reaction intermediate complex with a protein substrate, barley alpha-amylase/subtilisin inhibitor (BASI). The crystal structure of this mixed disulfide shows a conserved hydrophobic motif in thioredoxin interacting with a sequence of residues from BASI through van der Waals contacts and backbone-backbone hydrogen bonds. The observed structural complementarity suggests that the recognition of features around protein disulfides plays a major role in the specificity and protein disulfide reductase activity of thioredoxin. This novel insight into the function of thioredoxin constitutes a basis for comprehensive understanding of its biological role. Moreover, comparison with structurally related proteins shows that thioredoxin shares a mechanism with glutaredoxin and glutathione transferase for correctly positioning substrate cysteine residues at the catalytic groups but possesses a unique structural element that allows recognition of protein disulfides.     

The apparent glutathione oxidase activity of gamma-glutamyl transpeptidase. Chemical mechanism

The apparent glutathione oxidase activity of gamma-glutamyl transpeptidase is due to nonenzymatic oxidation and transhydrogenation reactions of cysteinylglycine, an enzymatic product formed from glutathione by hydrolysis or autotranspeptidation. Since cysteinylglycine reacts with oxygen more rapidly than does glutathione, the rate of disulfide formation is increased and either cystinyl-bis-glycine or the mixed disulfide of cysteinylglycine and glutathione forms as an intermediate product. Nonenzymatic transhydrogenation reactions of these disulfides with glutathione yield glutathione disulfide and thus account for the apparent glutathione oxidase activity of gamma-glutamyl transpeptidase. A sensitive assay for glutathione oxidation is described, and it is shown that covalent inhibitors of gamma-glutamyl transpeptidase abolish the oxidase activity of the purified enzyme and of crude homogenates of mouse and rat kidney.     

Protein-thiol substitution or protein dethiolation by thiol/disulfide exchange reactions: the albumin model

Dethiolation experiments of thiolated albumin with thionitrobenzoic acid and thiols (glutathione, cysteine, homocysteine) were carried out to understand the role of albumin in plasma distribution of thiols and disulfide species by thiol/disulfide (SH/SS) exchange reactions. During these experiments we observed that thiolated albumin underwent thiol substitution (Alb-SS-X+RSH<-->Alb-SS-R+XSH) or dethiolation (Alb-SS-X+XSH<-->Alb-SH+XSSX), depending on the different pK(a) values of thiols involved in protein-thiol mixed disulfides (Alb-SS-X). It appeared in these reactions that the compound with lower pK(a) in mixed disulfide was a good leaving group and that the pK(a) differences dictated the kind of reaction (substitution or dethiolation). Thionitrobenzoic acid, bound to albumin by mixed disulfide (Alb-TNB), underwent rapid substitution after thiol addition, forming the corresponding Alb-SS-X (peaks at 0.25-1 min). In turn, Alb-SS-X were dethiolated by the excess nonprotein SH groups because of the lower pK(a) value in mixed disulfide with respect to that of other thiols. Dethiolation of Alb-SS-X was accompanied by formation of XSSX and Alb-SH up to equilibrium levels at 35 min, which were different for each thiol. Structures by molecular simulation of thiolated albumin, carried out for understanding the role of sulfur exposure in mixed disulfides in dethiolation process, evidenced that the sulfur exposure is important for the rate but not for determining the kind of reaction (substitution or dethiolation). Our data underline the contribution of SH/SS exchanges to determine levels of various thiols as reduced and oxidized species in human plasma.     

Disulfide inhibition of copper-catalyzed oxidation of ascorbic acid: spectrophotometric evidence for accumulation of a stable complex

Copper-catalyzed oxidation of ascorbic acid was retarded in the presence of the biological disulfide compounds cystine and oxidized glutathione. The evidence suggested that this effect was due to the formation of a stable complex involving the copper ion, the disulfide compound, and ascorbic acid or a derivative formed during the oxidative process. This indicated that less copper was available for the formation of oxygen complexes which are not as stable as the disulfide complexes. Ellman's reagent (Nbs2) was reduced when it was substituted for the biological disulfides or when added, with EDTA, to solutions in which ascorbic acid, copper ion, and the biological disulfides had been allowed to interact. The complex formed with cystine was detected at 360 nm but the glutathione complex was not detected at this wavelength. It is proposed that disruption of cystine or glutathione complexes by EDTA results in formation of 2,3-diketogulonic acid which acts as a reductant of Ellman's reagent.     

Effects of the aminonucleoside of puromycin on kidney cortex sulfhydryl and disulfide-containing components and their respective oxidoreductase activities.

Comparative study of glutathione reductase and of mixed disulfide reducing activity assayed with a bovine serum albumin-glutathione substrate in kidney cortex of normal and of aminonucleoside-nephrotic rats reveals significantly higher activities in the latter. Total acid-soluble sulfhydryl and reduced glutathione (GSH) were also found to be significantly higher in kidney cortex of the aminonucleoside-treated rats. Neither total mixed disulfides nor mixed disulfides in which glutathione is covalently bound by disulfide linkage to kidney cortex protein are significantly altered by the nephrosis-producing aminonucleoside.     

The use of cysteinyl peptides to effect portage transport of sulfhydryl-containing compounds in Escherichia coli

We describe a method by which sulfhydryl compounds may be transported into Escherichia coli as the mixed disulfides with a cysteine residue of a di- or tripeptide. Transport occurs through the di- or oligopeptide transport systems, and it is suggested that subsequent release of the sulfhydryl compound occurs as a result of a disulfide exchange reaction with components of the sulfhydryl-rich cytoplasm. The free sulfhydryl compounds used here (2-mercaptopyridine and 4-[N-(2-mercaptoethyl)]aminopyridine-2,6-dicarboxylic acid) show weak growth-inhibitory properties in their own right, but disulfide linkage to a cysteinyl peptide results in a considerable enhancement (up to 2 orders of magnitude). This is the first example of the use of the peptide transport systems of E. coli to effect portage transport of a poorly permeant molecule by using attachment to the side chain of one of the amino acid residues of a peptide; all previous examples have involved the incorporation of amino acid analogues into the peptide backbone. The synthesis of cysteinyl peptides containing disulfide-linked 2-mercaptopyridine is described. Displacement of the 2-mercaptopyridine by sulfhydryl compounds of interest proceeds rapidly and quantitatively in aqueous alkaline solution to provide the required peptide disulfides.     

Glutathione is required to regulate the formation of native disulfide bonds within proteins entering the secretory pathway

The formation of native disulfide bonds is an essential event in the folding and maturation of proteins entering the secretory pathway. For native disulfides to form efficiently an oxidative pathway is required for disulfide bond formation and a reductive pathway is required to ensure isomerization of non-native disulfide bonds. The oxidative pathway involves the oxidation of substrate proteins by PDI, which in turn is oxidized by endoplasmic reticulum oxidase (Ero1). Here we demonstrate that overexpression of Ero1 results in the acceleration of disulfide bond formation and correct protein folding. In contrast, lowering the levels of glutathione within the cell resulted in acceleration of disulfide bond formation but did not lead to correct protein folding. These results demonstrate that lowering the level of glutathione in the cell compromises the reductive pathway and prevents disulfide bond isomerization from occurring efficiently, highlighting the crucial role played by glutathione in native disulfide bond formation within the mammalian endoplasmic reticulum.     

Near-UV circular dichroism of trypsin inhibitor of adzuki beans attributable to disulfide groups.

The trypsin inhibitor of adzuki (Phaseolus angularis) beans shows a CD spectrum with a negative extremum at 280 nm and a positive shoulder around 245 nm. Since the inhibitor lacks tryptophan and tyrosine, the observed CD spectrum can be attributed to the six disulfide groups in the molecule. The CD features completely disappeared on reduction of the disulfide groups, and converged into a single negative extremum at 270 nm when the groups were modified to form mixed disulfides with glutathione. These observations of the CD properties of the inhibitor strongly suggest the presence of disulfide groups constrained with respect to their dihedral angles.     

Multiple ways to make disulfides

Our concept of how disulfides form in proteins entering the secretory pathway has changed dramatically in recent years. The discovery of endoplasmic reticulum (ER) oxidoreductin 1 (ERO1) was followed by the demonstration that this enzyme couples oxygen reduction to de novo formation of disulfides. However, mammals deficient in ERO1 survive and form disulfides, which suggests the presence of alternative pathways. It has recently been shown that peroxiredoxin 4 is involved in peroxide removal and disulfide formation. Other less well-characterized pathways involving quiescin sulfhydryl oxidase, ER-localized protein disulfide isomerase peroxidases and vitamin K epoxide reductase might all contribute to disulfide formation. Here we discuss these various pathways for disulfide formation in the mammalian ER and highlight the central role played by glutathione in regulating this process.