Catalysis of the oxidative folding of ribonuclease A by protein disulfide isomerase: dependence of the rate on the composition of the redox buffer

The velocity of the oxidative renaturation of reduced ribonuclease A catalyzed by protein disulfide isomerase (PDI) is strongly dependent on the composition of a glutathione/glutathione disulfide redox buffer. As with the uncatalyzed, glutathione-mediated oxidative folding of ribonuclease, the steady-state velocity of the PDI-catalyzed reaction displays a distinct optimum with respect to both the glutathione (GSH) and glutathione disulfide (GSSG) concentrations. Optimum activity is observed at [GSH] = 1.0 mM and [GSSG] = 0.2 mM. The apparent kcat at saturating RNase concentration is 0.46 +/- 0.05 mumol of RNase renatured min-1 (mumol of PDI)-1 compared to the apparent first-order rate constant for the uncatalyzed reaction of 0.02 +/- 0.01 min-1. Changes in GSH and GSSG concentration have a similar effect on the rate of both the PDI-catalyzed and uncatalyzed reactions except under the more oxidizing conditions employed, where the catalytic effectiveness of PDI is diminished. The ratio of the velocity of the catalyzed reaction to that of the uncatalyzed reaction increases as the quantity [GSH]2/[GSSG] increases and approaches a constant, limiting value at [GSH]2/[GSSG] greater than 1 mM, suggesting that a reduced, dithiol form of PDI is required for optimum activity. As long as the glutathione redox buffer is sufficiently reducing to maintain PDI in an active form [( GSH]2/[GSSG] greater than 1 mM), the rate acceleration provided by PDI is reasonably constant, although the actual rate may vary by more than an order of magnitude. PDI exhibits half of the maximum rate acceleration at a [GSH]2/[GSSG] of 0.06 +/- 0.01 mM.     

Oxidative protein folding in vitro: a study of the cooperation between quiescin-sulfhydryl oxidase and protein disulfide isomerase

The flavin-dependent quiescin-sulfhydryl oxidase (QSOX) inserts disulfide bridges into unfolded reduced proteins with the reduction of molecular oxygen to form hydrogen peroxide. This work investigates how QSOX and protein disulfide isomerase (PDI) cooperate in vitro to generate native pairings in two unfolded reduced proteins: ribonuclease A (RNase, four disulfide bonds and 105 disulfide isomers of the fully oxidized protein) and avian riboflavin binding protein (RfBP, nine disulfide bonds and more than 34 million corresponding disulfide pairings). Experiments combining avian or human QSOX with up to 200 muM avian or human reduced PDI show that the isomerase is not a significant substrate of QSOX. Both reduced RNase and RfBP can be efficiently refolded in an aerobic solution containing micromolar concentrations of reduced PDI and nanomolar levels of QSOX without any added oxidized PDI or glutathione redox buffer. Refolding of RfBP is followed continuously using the complete quenching of the fluorescence of free riboflavin that occurs on binding to apo-RfBP. The rate of refolding is half-maximal at 30 muM reduced PDI when the reduced client protein (1 muM) is used in the presence of 30 nM QSOX. The use of high concentrations of PDI, in considerable excess over the folding protein client, reflects the concentration prevailing in the lumen of the endoplasmic reticulum and allows the redox poise of these in vitro experiments to be set with oxidized and reduced PDI. In the absence of either QSOX or redox buffer, the fastest refolding of RfBP is accomplished with excess reduced PDI and just enough oxidized PDI to generate nine disulfides in the protein client. These in vitro experiments are discussed in terms of current models for oxidative folding in the endoplasmic reticulum.     

A Pro to His mutation in active site of thioredoxin increases its disulfide-isomerase activity 10-fold. New refolding systems for reduced or randomly oxidized ribonuclease.

Thioredoxin (Trx) from Escherichia coli was compared with bovine protein disulfide-isomerase (PDI) for its ability to catalyze native disulfide formation in either reduced or randomly oxidized (scrambled) ribonuclease A (RNase). On a molar basis, a 100-fold higher concentration of Trx than of PDI was required to give the same rate of native disulfide formation measured as recovery of RNase activity. A Pro-34 to His (P34H Trx) mutation in the active site of E. coli Trx (WCGPC), mimicking the two suggested active sites in PDI (WCGHC), increased the catalytic activity in disulfide formation about 10-fold. The mutant P34H Trx displayed a 35-mV higher redox potential (E'0) of the active site disulfide/dithiol relative to wild type Trx, making it more similar to the redox potential observed for PDI. This higher redox potential correlates well with the enhanced activity and suggests a role for the histidine side chain. Enzymatic isomerization of disulfides in scrambled, oxidized RNase requires the presence of a catalytic thiol such as GSH to initiate the thiol-disulfide interchange. Bovine thioredoxin reductase, together with NADPH, could replace GSH. For oxidative folding of reduced RNase in air with Trx, P34H Trx, or PDI, catalytic amounts of sodium selenite (1 microM) resulted in rapid disulfide formation and high yields of ribonuclease activity equivalent to previously known redox buffers of GSH and GSSG. These results demonstrate no obligatory role for glutathione in disulfide formation. A possible mechanism for the unknown thiol oxidative process accompanying folding and protein disulfide formation in vivo is discussed.     

Catalysis of the oxidative folding of bovine pancreatic ribonuclease A by protein disulfide isomerase

The major oxidative folding pathways of bovine pancreatic ribonuclease A at pH 8.0 and 25 degrees C involve a pre-equilibrium steady state among ensembles of intermediates with zero, one, two, three and four disulfide bonds. The rate-determining steps are the reshuffling of the unstructured three-disulfide ensemble to two native-like three-disulfide species, des-[65-72] and des-[40-95], that convert to the native structure during oxidative formation of the fourth disulfide bond. Under the same regeneration conditions, with oxidized and reduced DTT, used previously for kinetic oxidative-folding studies of this protein, the addition of 4 microM protein disulfide isomerase (PDI) was found to lead to catalysis of each disulfide-formation step, including the rate-limiting rearrangement steps in which the native-like intermediates des-[65-72] and des-[40-95] are formed. The changes in the distribution of intermediates were also determined in the presence and absence of PDI at three different temperatures (with the DTT redox system) as well as at 25 degrees C (with the glutathione redox system). The results indicate that the acceleration of the formation of native protein by PDI, which we observed earlier, is due to PDI catalysis of each of the intermediate steps without changing the overall pathways or folding mechanism.     

Characterization of redox state and reductase activity of protein disulfide isomerase under different redox environments using a sensitive fluorescent assay

In this study, dieosin glutathione disulfide (Di-E-GSSG) was synthesized by the reaction of eosin isothiocyanate with GSSG. Di-E-GSSG had low fluorescence which increased approximately 70-fold on reduction of its disulfide bond. The substrate was used to monitor the disulfide reductase activity of PDI. Di-E-GSSG is the most sensitive pseudo substrate for PDI reductase activity reported to date. This probe was further used as an analytical reagent to develop an end point assay for measuring the redox state of PDI. The reduction of Di-E-GSSG by reduced enzyme was studied in the absence of reducing agents and the redox state of PDI was monitored as a function of the stoichiometric changes in the amount of eosin-glutathione (EGSH) generated by the active-site dithiols of PDI. The redox state of PDI was also studied under variable [GSH]/[GSSG] ratios. The results indicate that PDI is in approximately 1/2-reduced state where the [GSH]/[GSSG] ratio is between 1:1 and 3:1, conditions similar to the lumen of endoplasmic reticulum or in the extracellular environment. On the other hand, [GSH]/[GSSG] ratios of > or =8:1, such as in cytosol, all active-site thiols would be reduced. The study was extended to utilize Di-E-GSSG to investigate the effect of variable redox ratios on the platelet surface PDI reductase activity.     

Effect of protein and peptide inhibitors on the activity of protein disulfide isomerase

The protein disulfide isomerase catalyzed reduction of insulin by glutathione is inhibited by peptides of various length and amino acid composition. Peptide inhibitors are competitive against insulin and noncompetitive against GSH, consistent with a sequential rather than a double displacement mechanism. Peptides of unrelated primary sequence that do not contain cysteine inhibit the GSH-insulin transhydrogenase activity of PDI, and the affinity of these peptides toward the enzyme is largely dependent on the peptide length rather than composition, hydrophobicity, or charge. Cysteine-containing peptides are 4-8-fold better inhibitors than non-cysteine-containing peptides of the same length, suggesting a cysteine-specific component to the interaction with the enzyme. Oxidized insulin chain B also inhibits the oxidative folding of reduced ribonuclease in a glutathione redox buffer with an inhibition constant that is comparable to that observed for the inhibition of insulin reduction, suggesting a similar if not identical binding site for the catalysis of oxidative protein folding and the reduction of insulin.     

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.     

Both chaperone and isomerase functions of protein disulfide isomerase are essential for acceleration of the oxidative refolding and reactivation of dimeric alkaline protease inhibitor

Oxidative refolding of the dimeric alkaline protease inhibitor (API) from Streptomyces sp. NCIM 5127 has been investigated. We demonstrate here that both isomerase and chaperone functions of the protein folding catalyst, protein disulfide isomerase (PDI), are essential for efficient refolding of denatured-reduced API (dr-API). Although the role of PDI as an isomerase and a chaperone has been reported for a few monomeric proteins, its role as a foldase in refolding of oligomeric proteins has not been demonstrated hitherto. Spontaneous refolding and reactivation of dr-API in redox buffer resulted in 45% to 50% reactivation. At concentrations <0.25 microM, reactivation rates and yields of dr-API are accelerated by catalytic amounts of PDI through its isomerase activity, which promotes disulfide bond formation and rearrangement. dr-API is susceptible to aggregation at concentrations >25 microM, and a large molar excess of PDI is required to enhance reactivation yields. PDI functions as a chaperone by suppressing aggregation and maintains the partially unfolded monomers in a folding-competent state, thereby assisting dimerization. Simultaneously, isomerase function of PDI brings about regeneration of native disulfides. 5-Iodoacetamidofluorescein-labeled PDI devoid of isomerase activity failed to enhance the reactivation of dr-API despite its intact chaperone activity. Our results on the requirement of a stoichiometric excess of PDI and of presence of PDI in redox buffer right from the initiation of refolding corroborate that both the functions of PDI are essential for efficient reassociation, refolding, and reactivation of dr-API.     

Glutathione limits Ero1-dependent oxidation in the endoplasmic reticulum

Many proteins of the secretory pathway contain disulfide bonds that are essential for structure and function. In the endoplasmic reticulum (ER), Ero1 alpha and Ero1 beta oxidize protein disulfide isomerase (PDI), which in turn transfers oxidative equivalents to newly synthesized cargo proteins. However, oxidation must be limited, as some reduced PDI is necessary for disulfide isomerization and ER-associated degradation. Here we show that in semipermeable cells, PDI is more oxidized, disulfide bonds are formed faster, and high molecular mass covalent protein aggregates accumulate in the absence of cytosol. Addition of reduced glutathione (GSH) reduces PDI and restores normal disulfide formation rates. A higher GSH concentration is needed to balance oxidative folding in semipermeable cells overexpressing Ero1 alpha, indicating that cytosolic GSH and lumenal Ero1 alpha play antagonistic roles in controlling the ER redox. Moreover, the overexpression of Ero1 alpha significantly increases the GSH content in HeLa cells. Our data demonstrate tight connections between ER and cytosol to guarantee redox exchange across compartments: a reducing cytosol is important to ensure disulfide isomerization in secretory proteins.     

Rate enhancement of the oxidative folding of lysozyme by the use of aromatic thiol containing redox buffers

Almost all therapeutic proteins and most extracellular proteins contain disulfide bonds. The production of these proteins in bacteria or in vitro is challenging due to the need to form the correctly matched disulfide bonds during folding. One important parameter for efficient in vitro folding is the composition of the redox buffer, a mixture of a small molecule thiol and small molecule disulfide. The effects of different redox buffers on protein folding, however, have received limited attention. The oxidative folding of denatured reduced lysozyme was followed in the presence of redox buffers containing varying concentrations of five different aromatic thiols or the traditional aliphatic thiol glutathione (GSH). Aromatic thiols eliminated the lag phase at low disulfide concentrations, increased the folding rate constant up to 11-fold, and improved the yield of active protein relative to GSH. The yield of active protein was similar for four of the five aromatic thiols and for glutathione at pH 7 as well as for glutathione at pH 8.2. At pH 6 the positively charged aromatic thiol provided a higher yield than the negatively charged thiols.     

Mutations in domain a' of protein disulfide isomerase affect the folding pathway of bovine pancreatic ribonuclease A

Protein disulfide isomerase (PDI, EC 5.3.4.1), an enzyme and chaperone, catalyses disulfide bond formation and rearrangements in protein folding. It is also a subunit in two proteins, the enzyme collagen prolyl 4-hydroxylase and the microsomal triglyceride transfer protein. It consists of two catalytically active domains, a and a', and two inactive ones, b and b', all four domains having the thioredoxin fold. Domain b' contains the primary peptide binding site, but a' is also critical for several of the major PDI functions. Mass spectrometry was used here to follow the folding pathway of bovine pancreatic ribonuclease A (RNase A) in the presence of three PDI mutants, F449R, Delta455-457, and abb', and the individual domains a and a'. The first two mutants contained alterations in the last alpha helix of domain a', while the third lacked the entire domain a'. All mutants produced genuine, correctly folded RNase A, but the appearance rate of 50% of the product, as compared to wild-type PDI, was reduced 2.5-fold in the case of PDI Delta455-457, 7.5-fold to eightfold in the cases of PDI F449R and PDI abb', and over 15-fold in the cases of the individual domains a and a'. In addition, PDI F449R and PDI abb' affected the distribution of folding intermediates. Domains a and a' catalyzed the early steps in the folding but no disulfide rearrangements, and therefore the rate observed in the presence of these individual domains was similar to that of the spontaneous process.     

Both PDI and PDIp can attack the native disulfide bonds in thermally-unfolded RNase and form stable disulfide-linked complexes

Protein disulfide isomerase (PDI) and its pancreatic homolog (PDIp) are folding catalysts for the formation, reduction, and/or isomerization of disulfide bonds in substrate proteins. However, the question as to whether PDI and PDIp can directly attack the native disulfide bonds in substrate proteins is still not answered, which is the subject of the present study. We found that RNase can be thermally unfolded at 65°C under non-reductive conditions while its native disulfide bonds remain intact, and the unfolded RNase can refold and reactivate during cooling. Co-incubation of RNase with PDI or PDIp during thermal unfolding can inactivate RNase in a PDI/PDIp concentration-dependent manner. The alkylated PDI and PDIp, which are devoid of enzymatic activities, cannot inactivate RNase, suggesting that the inactivation of RNase results from the disruption of its native disulfide bonds catalyzed by the enzymatic activities of PDI/PDIp. In support of this suggestion, we show that both PDI and PDIp form stable disulfide-linked complexes only with thermally-unfolded RNase, and RNase in the complexes can be released and reactivated dependently of the redox conditions used. The N-terminal active site of PDIp is essential for the inactivation of RNase. These data indicate that PDI and PDIp can perform thiol-disulfide exchange reactions with native disulfide bonds in unfolded RNase via formation of stable disulfide-linked complexes, and from these complexes RNase is further released.     

Catalysis of thiol/disulfide exchange. Glutaredoxin 1 and protein-disulfide isomerase use different mechanisms to enhance oxidase and reductase activities

Glutaredoxin (Grx) and protein-disulfide isomerase (PDI) are members of the thioredoxin superfamily of thiol/disulfide exchange catalysts. Thermodynamically, rat PDI is a 600-fold better oxidizing agent than Grx1 from Escherichia coli. Despite that, Grx1 is a surprisingly good protein oxidase. It catalyzes protein disulfide formation in a redox buffer with an initial velocity that is 30-fold faster than PDI. Catalysis of protein and peptide oxidation by the individual catalytic domains of PDI and by a Grx1-PDI chimera show that differences in active site chemistry are fundamental to their oxidase activity. Mutations in the active site cysteines reveal that Grx1 needs only one cysteine to catalyze rapid substrate oxidation, whereas PDI requires both cysteines. Grx1 is a good oxidase because of the high reactivity of a Grx1-glutathione mixed disulfide, and PDI is a good oxidase because of the high reactivity of the disulfide between the two active site cysteines. As a protein disulfide reductase, Grx1 is also superior to PDI. It catalyzes the reduction of nonnative disulfides in scrambled ribonuclease and protein-glutathione mixed disulfides 30-180 times faster than PDI. A multidomain structure is necessary for PDI to catalyze effective protein reduction; however, placing Grx1 into the PDI multidomain structure does not enhance its already high reductase activity. Grx1 and PDI have both found mechanisms to enhance active site reactivity toward proteins, particularly in the kinetically difficult direction: Grx1 by providing a reactive glutathione mixed disulfide to supplement its oxidase activity and PDI by utilizing its multidomain structure to supplement its reductase activity.     

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.     

Impact of an easily reducible disulfide bond on the oxidative folding rate of multi-disulfide-containing proteins.

The burial of native disulfide bonds, formed within stable structure in the regeneration of multi-disulfide-containing proteins from their fully reduced states, is a key step in the folding process, as the burial greatly accelerates the oxidative folding rate of the protein by sequestering the native disulfide bonds from thiol-disulfide exchange reactions. Nevertheless, several proteins retain solvent-exposed disulfide bonds in their native structures. Here, we have examined the impact of an easily reducible native disulfide bond on the oxidative folding rate of a protein. Our studies reveal that the susceptibility of the (40-95) disulfide bond of Y92G bovine pancreatic ribonuclease A (RNase A) to reduction results in a reduced rate of oxidative regeneration, compared with wild-type RNase A. In the native state of RNase A, Tyr 92 lies atop its (40-95) disulfide bond, effectively shielding this bond from the reducing agent, thereby promoting protein oxidative regeneration. Our work sheds light on the unique contribution of a local structural element in promoting the oxidative folding of a multi-disulfide-containing protein.     

Formation of enzyme—substrate disulfide linkage during catalysis by protein disulfide isomerase

During the regeneration of native ribonuclease A (RNase) from the disulfide scrambled molecule by protein disulfide isomerase (PDI), the substrate forms a covalent intermediate with the enzyme through disulfide linkage(s). This has been shown by the appearance of a band at the molecular weight position expected in SDS-PAGE at the same time as the increase in RNase activity. The new band decreased when the regeneration of RNase activity approached completion and disappeared by treatment of the reaction mixture with excess dithiothreitol.     

Selective inhibition of protein disulfide isomerase by estrogens

Protein disulfide isomerase (PDI) is a multifunctional microsomal enzyme that participates in the formation of protein disulfide bonds. PDI catalyzes the reduction of protein disulfide bonds in the presence of excess reduced glutathione and has been implicated in the reductive degradation of insulin; E. coli thioredoxin is homologous to two regions in PDI and can also degrade insulin. PDI activity, measured by 125I-insulin degradation or reactivation of randomly oxidized RNase in the presence of reduced glutathione, is non-competitively inhibited by estrogens; half-maximal inhibition was observed at approximately 100 nM estrogen. Other steroid hormones at 1 microM had little or no effect. PDI segment 120-163 (which corresponds to exon 3 of the PDI gene) and 182-230 have significant similarity with estrogen receptor segments 350-392 and 304-349, respectively, located in the estrogen binding domain but not with the steroid domains of the progesterone and glucocorticoid receptors or with thioredoxin, which is insensitive to estrogens. We propose the hypothesis that enzymes can acquire sensitivity to a hormone via exon shuffling to the enzyme gene from the DNA region coding for the hormone binding domain of the hormone's receptor.     

Redox conditions for stimulation of in vitro folding and assembly of the glycoprotein hormone chorionic gonadotropin

The formation of native disulfide bonds during in vitro protein folding can be limiting in obtaining biologically active proteins. Thus, optimization of redox conditions can be critical in maximizing the yield of renatured, recombinant proteins. We have employed a folding model, that of the beta subunit of human chorionic gonadotropin (hCG- beta), to investigate in vitro oxidation conditions that facilitate the folding of this protein, and have compared the in vitro rates obtained with the rate of folding that has been observed in intact cells. Two steps in the folding pathway of hCG-beta were investigated: the rate-limiting events in the folding of this protein, and the assembly of hCG-beta with, hCG-alpha. The rates of these folding events were determined with and without protein disulfide isomerase (PDI) using two different types of redox reagents: cysteamine and its oxidized equivalent, cystamine, and reduced and oxidized glutathione. Rates of the rate-limiting folding events were twofold faster in cysteamine/cystamine redox buffers than in glutathione buffers in the absence of PDI. Optimal conditions for hCG-beta folding were attained in a 2 mM glutathione buffer, pH 7.4, that contained 1 mg/mL PDI and in 10muM cysteamine/cystamine, pH 8.7, without PDI. Under these conditions, the half-time of the ratelimiting folding event was 16 to 20 min and approached the rate observed in intact cells (4 to 5 min). Moreover, folding of the beta subunit under these conditions yields a functional protein, based on its ability to assemble with the alpha subunit. The rates of assembly of hCG-beta with hCG-alpha in the cysteamine/cystamine or glutathione/PDI redox buffers were comparable (t(1/2/sb> = 9 to 12 min)). These studies show that rates of folding and assembly events that involve disulfide bond formation can be optimized by a simple buffer system composed of cysteamine and cystamine. (c) 1994 John Wiley & Sons, Inc.     

Studies on the function of yeast protein disulfide isomerase in renaturation of proteins.

Renaturation of two enzymes lacking disulfide bonds, citrate synthase (CS), and glyceraldehyde 3-phosphate dehydrogenase (GAPDH) and another protein containing disulfide bonds, lysozyme (LZM), were studied in order to dissect the possible chaperone function from the isomerase function of yeast protein disulfide isomerase (PDI). Our findings suggest no independent chaperone activity of yeast PDI with respect to the two enzymes lacking disulfide bonds, GAPDH and CS, since neither of these enzymes required PDI for renaturation. In contrast, a high level of renaturation of LZM was observed in the presence of PDI. Renaturation of LZM involved formation and rearrangement of disulfide bonds. Additional studies using LZM as a substrate were done to examine the role of cysteine residues in the two active sites of PDI. Studies with a series of cysteine to serine mutants and truncation mutants of yeast PDI revealed that the two active sites of PDI were not equal in activity. An intramolecular disulfide bond in at least one active site of PDI was required for the oxidation of reduced LZM. The first cysteine in each active site was necessary for disulfide bond rearrangement, i.e., isomerization, in LZM, while the second cysteine was not.     

Nonenzymic reactivation of reduced bovine pancreatic ribonuclease by air oxidation and by glutathione oxidoreduction buffers.

With the glutathione system that leads to rapid regeneration of reduced lysozyme (Saxena, V. P., and Wetlaufer, D. B. (1971) Biochemistry 9, 5015), reduced pancreatic ribonuclease (RNase) regenerated activity in high yield (greater than 90%) but at a considerably lower rate (t1/2 approximately 75 min). Systematic examination of the effects upon regeneration of the concentrations and ratios of reduced and oxidized glutathione (GSH and GSSG) showed the same broad optima for RNase as were earlier found for lysozyme: [GSSG] = 5 X 10(-4) M, [GSH] = 5 X 10(-3) M. Regeneration of reduced RNase by air oxidation was shown to be inhibitable by 10(-4) M EDTA, whereas the glutathione regeneration was unaffected by EDTA. In addition the air-oxidative regeneration showed a strong temperature dependence, in contrast with the glutathione system. The mechanisms of these two kinds of regenerations are therefore different. Six potentially catalytic metal ions were tested in the air-oxidative regeneration of RNase: Cu2+, Co2+, Mn2+, Fe3+, Zn2+, and Ni2+. Of these, only Cu2+ enhanced the rate of regeneration of RNase activity, although both Cu2+ and Co2+ catalyzed thioloxidation of reduced RNase. The rates and yields of RNase regenerations were independent of protein concentration from 3 X 10(-7) M to 1.2 X 10(-5) M in the glutathione system. Preincubation of freshly dissolved reduced RNase under nonoxidizing conditions before adding glutathione did not change the rate or extent of regeneration. Studies of its pH dependence showed that the glutathione regeneration depends on the deprotonation of prototropic groups with 7.5 less than pK less than 8.0. The major ion exchange chromatographic peaks from glutathione and air-oxidative regenerations appeared to be identical with native RNase, by the criteria of specific activity, chromatographic mobility, and circular dichroic spectra. The glutathione system permits regeneration at much higher RNase concentration than the air regeneration, with rates and yields comparable to the greatest reported for air regeneration.