Disulfide-disulfide interchange catalyzed by a liver supernatant enzyme.

An enzyme widely distributed in rabbit tissues which catalyzes an interchange between N,N-di-dinitrophenyl-L-cystine and oxidized glutathione to form the mixed disulfide is described. D-Penicillamine disulfide can be substituted for oxidized glutathione and the mixed disulfide of cysteine and glutathione can serve as the sole substrate giving as one product of interchange, oxidized glutathione. The enzyme is very labile and only limited purification of it has been achieved. The activity increases with increasing pH above 6.6, the Km for N,N-di-dinitrophenyl-L-cystine is 0.2 mM and for oxidized glutathione 0.8 mM. The enzyme is inhibited by SH reagents with protection against iodoacetamide inactivation provided by N,N-di-dinitrophenyl-L-cystine. Evidence is presented that disulfide-disulfide interchange enzyme is a different activity from the previously described protein disulfide isomerase and thiol transferase.     

Thiol/disulfide redox equilibrium and kinetic behavior of chicken liver fatty acid synthase

Chicken liver fatty acid synthase is rapidly inactivated and cross-linked at pH 7.2 and 8.0 by incubation with low concentrations of common biological disulfides including glutathione disulfide, coenzyme A disulfide, and glutathione-coenzyme A-mixed disulfide. Glutathione disulfide inactivation of the enzyme is accompanied by the oxidation of a total of 4-5 enzyme thiols per monomer. Only one glutathione equivalent is incorporated per monomer as a protein-mixed disulfide, and its rate of incorporation is significantly slower than the rate of inactivation. The formation of protein-SS-protein disulfides results in significant cross-linking of enzyme subunits. The inactive enzyme is rapidly and completely reactivated, and the cross-linking is completely reversed by incubation of the enzyme with thiols (10-20 mM) including dithiothreitol, mercaptoethanol, and glutathione. In a glutathione redox buffer (GSH + GSSG), disulfide bond formation comes to equilibrium. The enzyme activity at equilibrium is dependent both on the ratio of glutathione to glutathione disulfide and on the total glutathione concentration. The equilibrium constant for the redox equilibration of fatty acid synthase in a glutathione redox buffer is 15 mM (Ered + GSSG in equilibrium Eox + 2GSH). The formation of at least one protein-protein disulfide per monomer dominates the redox properties of the enzyme while the formation of one protein-mixed disulfide with glutathione (Kmixed = 0.45) has little effect on activity. The oxidation equilibrium constant suggests that there would be no significant cycling between the reduced and the oxidized enzyme in response to likely physiological variations in the hepatic glutathione status. The possibility that changes in the concentration of cellular glutathione may act as a mechanism for metabolic control of other enzymes is discussed.     

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.     

Regulation of rat liver microsomal glutathione S-transferase activity by thiol/disulfide exchange

The regulation of purified glutathione S-transferase from rat liver microsomes was studied by examining the effects of various sulfhydryl reagents on enzyme activity with 1-chloro-2,4-dinitrobenzene as the substrate. Diamide (4 mM), cystamine (5 mM), and N-ethylmaleimide (1 mM) increased the microsomal glutathione S-transferase activity by 3-, 2-, and 10-fold, respectively, in absence of glutathione; glutathione disulfide had no effect. In presence of glutathione, microsomal glutathione S-transferase activity was increased 10-fold by diamide (0.5 mM), but the activation of the transferase by N-ethylmaleimide or cystamine was only slightly affected by presence of glutathione. The activation of microsomal glutathione S-transferase by diamide or cystamine was reversed by the addition of dithiothreitol. Glutathione disulfide increased microsomal glutathione S-transferase activity only when membrane-bound enzyme was used. These results indicate that microsomal glutathione S-transferase activity may be regulated by reversible thiol/disulfide exchange and that mixed disulfide formation of the microsomal glutathione S-transferase with glutathione disulfide may be catalyzed enzymatically in vivo.     

Analysis of free sulfhydryl groups and disulfide bonds in Na+,K+-ATPase

The content of free SH groups and disulfide bonds in the purified pig kidney Na+,K+-ATPase was determined by ammetric titration with silver nitrate. In the native enzyme, most of the free SH groups are masked due to their location in the polypeptide chain regions poorly accessible to SH reagents. Denaturation with 5% SDS and 8 M urea makes these regions accessible thus revealing 22 free SH groups/mol of the protein. After complete blocking of free SH groups with silver ions, 8 SH groups/mol of the protein are being released upon sulfitolysis which indicates the presence of four disulfide bonds in the enzyme. At least one disulfide bridge is located in the alpha-subunit whereas the beta-subunit contains three disulfide bonds.     

Mutational analysis of parasite trypanothione reductase: acquisition of glutathione reductase activity in a triple mutant

African trypanosomes contain a cyclic derivative of oxidized glutathione, N1,N8-bis(glutathionyl)spermidine, termed trypanothione. This is the substrate for the parasite enzyme trypanothione reductase, a key enzyme in disulfide/dithiol redox balance and a target enzyme for trypanocidal therapy. Trypanothione reductase from these and related trypanosomatid parasites is structurally homologous to host glutathione reductase but the two enzymes show mutually exclusive substrate specificities. To assess the basis of host vs parasite enzyme recognition for their disulfide substrates, the interaction of bound glutathione with active-site residues in human red cell glutathione reductase as defined by prior X-ray analysis was used as the starting point for mutagenesis of three residues in trypanothione reductase from Trypanosoma congolense, a cattle parasite. Mutation of three residues radically alters enzyme specificity and permits acquisition of glutathione reductase activity at levels 10(4) higher than in wild-type trypanothione reductase.     

Irreversible inhibition of the human placental NADP-linked 15-hydroxyprostaglandin dehydrogenase/9-ketoprostaglandin reductase by glutathione thiosulfonate

Oxidation of glutathione disulfide by a mixture of performic and hydrochloric acids leads to the formation of several compounds that are stronger inhibitors than glutathione disulfide of the placental enzyme that possess both NADP-linked 15-hydroxyprostaglandin dehydrogenase and 9-ketoprostaglandin reductase activities. The only one of these inhibitors that has been identified is glutathione thiosulfonate. The others are unstable and may include glutathione sulfinyl sulfone and glutathione disulfone. Since the enzyme appears to have a glutathione binding site in close proximity to its active site and glutathione thiosulfonate reacts with free sulfhydryl groups, the effects of this thiosulfonate on the enzyme were examined in more detail. Glutathione thiosulfonate and methyl methanethiosulfonate cause a time-dependent irreversible inhibition of both the hydroxyprostaglandin dehydrogenase and the ketoprostaglandin reductase activities, presumably by reacting with a free sulfhydryl at the prostaglandin binding site. Experiments with PGA1-glutathione show that this sulfhydryl is not necessary for the catalytic activity of the enzyme as long as the substrate can bind at the glutathione site.     

Conversion of glutathione to glutathione disulfide, a catalytic function of gamma-glutamyl transpeptidase.

A purification procedure, based on that previously used for rat kidney gamma-glutamyl transpeptidase, was used for the purification of glutathione oxidase (which converts glutathione to gluthathione disulfide). The two activities co-purified, the ratio of the activities remaining constant through all steps of the isolation procedure. The purified enzyme was separable into 12 isozymic species by isoelectric focusing. All 12 isozymes exhibited a constant ratio of transpeptidase to glutathione oxidase activities, strongly supporting the conclusion that conversion of glutathione to glutathione disulfide is a catalytic function of gamma-glutamyl transpeptidase. Modulation of oxidase activity by inhibitors and acceptor substrates of transpeptidase is discussed in relation to the possible glutathione binding sites involved in gamma-glutamyl transfer and oxidase activities of the enzyme.     

Accumulation of cystine from glutathione-cysteine mixed disulfide in cystinotic fibroblasts; blockade by an inhibitor of gamma-glutamyl transpeptidase

Cystinotic and normal skin fibroblasts in tissue culture were treated with varying concentrations of reduced glutathione, oxidized glutathione and glutathione-cysteine mixed disulfide, substrates of gamma-glutamyl transpeptidase, the catabolic enzyme of the gamma-glutamyl cycle. Cystine accumulated more rapidly and to a greater extent from the glutathione-cysteine mixed disulfide in cystinotic than in normal cells. Inhibition of gamma-glutamyl transpeptidase activity by serine in a borate buffer partially blocked this accumulation of cystine. Reduced glutathione and oxidized glutathione have lesser effects on cystine accumulation. Stored cystine in cystinotic tissues may derive in part from glutathione-cysteine mixed disulfide via transpeptidation.     

Irreversible inhibition of the human placental NADP-linked 15-hydroxyrpostaglandin dehydrogenase/9-ketoprostaglandin reductase by glutathione thiosulfonate

Oxidation of glutathione disulfide by a mixture of performic and hydrochloric acids leads to the formation of several compounds that are stronger inhibitors than glutathione disulfide of the placental enzyme that posses both NADP-linked 15-hydroxypyrostaglandin dehydrogenase and 9-ketoprostaglandin reductase activities. The only one of these inhibitors that has been identified is glutathione thiosulfonate. The others are unstble and may include glutathione sulfinyl sulfone and glutathione disulfone. Since the enzyme appears to have a glutathione binding site in close proximity to its active site and glutathione thiosulfonate reacts with free sulfhydryl groups, the effects of this thiosulfonate on the enzyme were examined in more detail. Glutahione thiosulfonate and methyl methanethiosulfonate cause a time-dependent irreversible inhibition of both the hydroxyprostaglandin dehydrogenase and the ketoprostaglandin reductase activities, presumably by reacting with a free sulfhydryl at the prostaglandin binding site. Experiments with PGA-glutathione show that this sulfhydryl is not necessary for the catalytic activity of the enzyme as long as the substrate can bind at the glutahione site.     

Mixed disulfide with glutathione as an intermediate in the reaction catalyzed by glutathione reductase from yeast and as a major form of the enzyme in the cell

Glutathione reductase catalyzes the reduction of glutathione disulfide by NADPH. The FAD of the reductase is reduced by NADPH, and reducing equivalents are passed to a redox-active disulfide to complete the first half-reaction. The nascent dithiol of two-electron reduced enzyme (EH(2)) interchanges with glutathione disulfide forming two molecules of glutathione in the second half-reaction. It has long been assumed that a mixed disulfide (MDS) between one of the nascent thiols and glutathione is an intermediate in this reaction. In addition to the nascent dithiol composed of Cys(45) and Cys(50), the enzyme contains an acid catalyst, His(456), having a pK(a) of 9.2 that protonates the first glutathione (residue numbers refer to the yeast enzyme sequence). Reduction of yeast glutathione reductase by glutathione and reoxidation of EH(2) by glutathione disulfide indicate that the mixed disulfide accumulates, in particular, at low pH. The reaction of glutathione disulfide with EH(2) is stoichiometric in the absence of an excess of glutathione. The equilibrium position among E(ox), MDS, and EH(2) is determined by the glutathione concentration and is not markedly influenced by pH between 6.2 and 8.5. The mixed disulfide is the principal product in the reaction of glutathione with oxidized enzyme (E(ox)) at pH 6. 2. Its spectrum can be distinguished from that of EH(2) by a slightly lower thiolate (Cys(50))-FAD charge-transfer absorbance at 540 nm. The high GSH/GSSG ratio in the cytoplasm dictates that the mixed disulfide will be the major enzyme species.     

Contrasting effects of various sulfhydryl reagents on the activity of lecithin: Cholesterol acyltransferase

Lecithin:cholesterol acyltransferase, E.C. 2.3.1.43, can be either stimulated or inhibited by reducing reagents containing free sulfhydryl groups. Mercaptoethanol and dithiothreitol stimulate enzyme activity while cysteine and reduced glutathione inhibit activity. The oxidizing disulfide reagent 2-pyridine disulfide has minimal effects on enzyme activity by itself but suppresses the stimulatory effect of mercaptoethanol.     

Thiol-disulfide Transhydrogenase from Baker’s Yeast and a New Method for the Direct Assay of an Enzyme-catalyzed Thiol-disulfide Interchange Activity

This paper presents a study on the enzyme reduction of the disulfide bond and the following results have been found.

In enzyme preparation, antioxidants showed a stability effect and EDTA appeared to have both enzyme stabilization and solubilization. On the distribution of the enzyme activity in subcellular fractions, the water soluble fraction appeared to contain the major released enzyme activity. The enzyme was inhibited with several metals. Hg²⁺ and transition metals were the most toxic. The substrate specificity of this enzyme was wide for the low molecular substrates, but the protein disulfide reducing activity was not detected in this preparation. It was assumed that the thiol-disulfide transhydrogenase was coupled with glutathione reductase and the disulfide substrates were reduced by the system involving the two enzymes. A new method for the direct recording of an enzyme-catalyzed thiol-disulfide interchange using diphenyl disulfide and p,p-dinitro diphenyl disulfide was devised.     

Anomalous electrochemical behavior of clostripain: Evidence for disulfide isolation conformers

Summary Purified preparations of clostripain exhibit two distinct components on analytical and preparative acrylamide gel electrophoresis as well as adsorption chromatography on hydroxylapatite. Both components are of identical molecular size and specific activity. By reducing the enzyme for an extended period of time prior to chromatography, the specific activity increases by a factor of four and the enzyme elutes from the hydroxylapatite column as a homogeneous peak. Enzyme labeled at the active site with³H-TLCK exhibits a similar chromatographic behavior to native enzyme on hydroxylapatite.It is inferred that such behavior may be attributed to a two phase disulfide reduction, one involving reduction of a disulfide thereby freeing an active site SH group and a second disulfide reduction resulting in the chromatographic transition.     

Identification and reactivity of the catalytic site of pig liver thioltransferase

The active site cysteine of pig liver thioltransferase was identified as Cys22. The kinetics of the reaction between Cys22 of the reduced enzyme and iodoacetic acid as a function of pH revealed that the active site sulfhydryl group had a pKa of 2.5. Incubation of reduced enzyme with [1-14C]cysteine prevented the inactivation of the enzyme by iodoacetic acid at pH 6.5, and no stable protein-cysteine disulfide was found when the enzyme was separated from excess [1-14C]cysteine, suggesting an intramolecular disulfide formation. The results suggested a reaction mechanism for thioltransferase. The thiolated Cys22 first initiates a nucleophilic attack on a disulfide substrate, resulting in the formation of an unstable mixed disulfide between Cys22 and the substrate. Subsequently, the sulfhydryl group at Cys25 is deprotonated as a result of micro-environmental changes within the active site domain, releasing the mixed disulfide and forming an intramolecular disulfide bond. Reduced glutathione, the second substrate, reduces the intramolecular disulfide forming a transient mixed disulfide which is then further reduced by glutathione to regenerate the reduced enzyme and form oxidized glutathione. The rate-limiting step for a typical reaction between a disulfide and reduced glutathione is proposed to be the reduction of the intramolecular disulfide form of the enzyme by reduced glutathione.     

Evidence for the proximity of two sulfhydryl groups at the active site of 6-phosphogluconate dehydrogenase

The reaction between 6-phosphogluconate dehydrogenase from Candida utilis and 5,5′-dithiobis(2-nitrobenzoate) results in the inactivation of the enzyme. At pH 6.0 the inactivation can be correlated with the modification of only one SH group per enzyme subunit. The modified SH group can react with another SH group forming an intramolecular disulfide bridge. Since the modified enzymes, either with an SH group modified or with a cystine disulfide bridge, are still able to bind the substrate and the coenzyme, gross conformational changes seem unlikely to have occurred. The results obtained suggest that the SH groups of two cysteine residues are located close to each other in the three-dimensional structure of the active site of the enzyme.     

Redox regulation of yeast flavin-containing monooxygenase

The flavin-dependent monooxygenase from yeast (yFMO) oxidizes biological thiols such as cysteine, cysteamine, and glutathione. The enzyme makes a major contribution to the pools of oxidized thiols that, together with reduced glutathione from glutathione reductase, create the optimum cellular redox environment. We show that the activity of yFMO, as a soluble enzyme or in association with the ER membrane of microsomal fractions, is correlated with the redox potential. The enzyme is active under conditions normally found in the cytoplasm, but is inhibited as GSSG accumulates to give a redox potential similar to that found in the lumen of the ER. Site-directed mutations show that Cys 353 and Cys 339 participate in the redox regulation. Cys 353 is the principal residue in the redox-sensitive switch. We hypothesize that it may initiate formation of a mixed disulfide that is partially inhibitory to yFMO. The mixed disulfide may exchange with Cys 339 to form an intramolecular disulfide bond that is fully inhibitory.     

Purification by affinity chromatography of yeast glutathione reductase, the enzyme responsible for the NADPH-dependent reduction of the mixed disulfide of coenzyme A and glutathione.

Glutathione reductase (NAD(P)H : oxidised-glutathione oxidoreductase, EC 1.6.4.2) was purified from baker's yeast by a new procedure involving affinity chromatography on 2',5'-ADP-Sepharose 4B. The yield was 65% of essentially homogeneous enzyme. The activity was assayed with both glutathione disulfide (GSSG) and the mixed disulfide of coenzyme A and glutathione (CoAssg). The two disulfide substrates gave coinciding activity profiles and a constant ratio of the activities in different chromatographic and electrophoretic systems. No evidence was obtained for the existence of a reductase specific for CoASSG distinct from glutathione reductase. It is concluded that normal baker's yeast contains a single reductase active with both GSSG and CoASSG.     

Enzymatic catalysis of the reversible sulfitolysis of glutathione disulfide and the biological reduction of thiosulfate esters

Rat liver supernatants were shown to contain an enzymatic activity catalyzing in both forward and reverse directions the reversible sulfitolysis of glutathione disulfide. The enzymatic sulfitolysis has maximal activity at pH 7. S-Sulfoglutathione, which is a product of the sulfitolysis, was isolated by passage through an ion-exchange column. Three different assays were applied to determine S-sulfoglutathione, viz., methods based on the ninhydrin reaction, the formation of a thiazoline derivative in strong acid, and the use of radioactively labeled glutathione. The reversal of the sulfitolysis, i.e., the reaction of S-sulfoglutathione with glutathione, was studied directly by determination of sulfite with radioactive N-ethylmaleimide, or indirectly by coupling to the NADPH- and glutathione reductase-linked reduction of glutathione disulfide.Chromatographic analysis of rat liver supernatants demonstrated that all fractions catalyzing the reversible sulfitolysis did also catalyze the previously studied thiol-disulfide interchange of glutathione and the mixed disulfide of cysteine and glutathione.The reduction of thiosulfate esters, such as S-sulfocysteine and trimethylammonium-ethylthiosulfate, with glutathione was also catalyzed by the enzyme active in the sulfitolysis, which indicates an important biosynthetic role of the enzyme in microorganisms synthesizing cysteine via S-sulfocysteine. The enzyme is also capable of participating in the formation of the naturally occurring S-sulfoglutathione.     

The reversible oxidation of vicinal SH groups in 4-aminobutyrate aminotransferase. Probes of conformational changes

4-Aminobutyrate aminotransferase is inactivated by preincubation with iodosobenzoate at pH 7. The reaction of 2 SH residues/dimer resulted in formation of an oligomeric species of Mr = 100,000 detectable by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The subunits cross-linked via a disulfide bond are dissociated by addition of 2-mercaptoethanol which also restores full catalytic activity (Choi, S. Y., and Churchich, J.E. (1985) J. Biol. Chem. 260, 993-997). The substrate 2-oxoglutarate prevents inactivation of the enzyme by iodosobenzoate and the subsequent formation of one disulfide bond, whereas 4-aminobutyrate has no effect on the reactivity of SH groups with iodosobenzoate. Modified 4-aminobutyrate aminotransferase (containing 1 disulfide bond) catalyzes a half-transamination reaction; but it is unable to react with 2-oxoglutarate to generate the aldimine form of the enzyme. The spectroscopic properties (fluorescence yield and polarization of fluorescence) of PMP bound to the modified enzyme are different from those of pyridoxamine phosphate (PMP) bound to the native enzyme. The polarization of fluorescence values of PMP bound to the cross-linked enzyme, excited over the spectral range 310-370 nm, are greater (25%) than those of the cofactor of the native enzyme. An increase in the polarization values implies that the motion of PMP is restricted when the subunits are cross-linked via a disulfide bond.