The renal thiol (glutathione) oxidase. Subcellular localization and properties

Glutathione contributes to efficient post-Golgi trafficking of incoming HPV16 genome

Human papillomavirus (HPV) is the most common sexually transmitted pathogen in the United States, causing 99% of cervical cancers and 5% of all human cancers worldwide. HPV infection requires transport of the viral genome (vDNA) into the nucleus of basal keratinocytes. During this process, minor capsid protein L2 facilitates subcellular retrograde trafficking of the vDNA from endosomes to the Golgi, and accumulation at host chromosomes during mitosis for nuclear retention and localization during interphase. Here we investigated the relationship between cellular glutathione (GSH) and HPV16 infection. siRNA knockdown of GSH biosynthetic enzymes results in a partial decrease of HPV16 infection. Likewise, infection of HPV16 in GSH depleted keratinocytes is inefficient, an effect that was not seen with adenoviral vectors. Analysis of trafficking revealed no defects in cellular binding, entry, furin cleavage of L2, or retrograde trafficking of HPV16, but GSH depletion hindered post-Golgi trafficking and translocation, decreasing nuclear accumulation of vDNA. Although precise mechanisms have yet to be defined, this work suggests that GSH is required for a specific post-Golgi trafficking step in HPV16 infection.

Rat seminal vesicle FAD-dependent sulfhydryl oxidase. Biochemical characterization and molecular cloning of a member of the new sulfhydryl oxidase/quiescin Q6 gene family

Rat FAD-dependent sulfhydryl oxidase was purified; partial sequencing indicated that it was homologous to human quiescin Q6. A cDNA (GenBank accession no. AF285078) was cloned from rat seminal vesicles, and active recombinant sulfhydryl oxidase was expressed in Chinese hamster ovary epithelial cells. This 2472-nucleotide cDNA has an open reading frame of 1710 base pairs, encoding a protein of 570 amino acids including a 32-amino acid leader sequence and two potential sites for N-glycosylation. One of them is used and the 64,000 M(r) purified protein was transformed to 61,000 by the action of endoglycosidase F. Northern blotting and reverse transcription-polymerase chain reaction analyses showed that there were small amounts of sulfhydryl oxidase in the rat testis, prostate, lung, heart, kidney, spleen, and liver, and that the gene was highly expressed in seminal vesicles and epididymis. Rat sulfhydryl oxidase cDNA corresponds to the human cell growth inhibiting factor cDNA, which could be a differently spliced form of quiescin Q6. Comparing sulfhydryl oxidase sequences with those of human quiescin Q6 and mammalian and Caenorhabditis elegans quiescin Q6-related genes established the existence of a new family of FAD-dependent sulfhydryl oxidase/quiescin Q6-related genes containing protein-disulfide isomerase-type thioredoxin and yeast ERV1 domains.

Homology between egg white sulfhydryl oxidase and quiescin Q6 defines a new class of flavin-linked sulfhydryl oxidases

The flavin-dependent sulfhydryl oxidase from chicken egg white catalyzes the oxidation of sulfhydryl groups to disulfides with the reduction of oxygen to hydrogen peroxide. Reduced proteins are the preferred thiol substrates of this secreted enzyme. The egg white oxidase shows an average 64% identity (from randomly distributed peptides comprising more than 30% of the protein sequence) to a human protein, Quiescin Q6, involved in growth regulation. Q6 is strongly expressed when fibroblasts enter reversible quiescence (Coppock, D. L., Cina-Poppe, D., Gilleran, S. (1998) Genomics 54, 460-468). A peptide antibody against Q6 cross-reacts with both the egg white enzyme and a flavin-linked sulfhydryl oxidase isolated from bovine semen. Sequence analyses show that the egg white oxidase joins human Q6, bone-derived growth factor, GEC-3 from guinea pig, and homologs found in a range of multicellular organisms as a member of a new protein family. These proteins are formed from the fusion of thioredoxin and ERV motifs. In contrast, the flavin-linked sulfhydryl oxidase from Aspergillus niger is related to the pyridine nucleotide-dependent disulfide oxidoreductases, and shows no detectable sequence similarity to this newly recognized protein family.

Sulfhydryl oxidase from egg white. A facile catalyst for disulfide bond formation in proteins and peptides

Both metalloprotein and flavin-linked sulfhydryl oxidases catalyze the oxidation of thiols to disulfides with the reduction of oxygen to hydrogen peroxide. Despite earlier suggestions for a role in protein disulfide bond formation, these enzymes have received comparatively little general attention. Chicken egg white sulfhydryl oxidase utilizes an internal redox-active cystine bridge and a FAD moiety in the oxidation of a range of small molecular weight thiols such as glutathione, cysteine, and dithiothreitol. The oxidase is shown here to exhibit a high catalytic activity toward a range of reduced peptides and proteins including insulin A and B chains, lysozyme, ovalbumin, riboflavin-binding protein, and RNase. Catalytic efficiencies are up to 100-fold higher than for reduced glutathione, with typical K(m) values of about 110-330 microM/protein thiol, compared with 20 mM for glutathione. RNase activity is not significantly recovered when the cysteine residues are rapidly oxidized by sulfhydryl oxidase, but activity is efficiently restored when protein disulfide isomerase is also present. Sulfhydryl oxidase can also oxidize reduced protein disulfide isomerase directly. These data show that sulfhydryl oxidase and protein disulfide isomerase can cooperate in vitro in the generation and rearrangement of native disulfide pairings. A possible role for the oxidase in the protein secretory pathway in vivo is discussed.

Dithiocarbamate toxicity toward thymocytes involves their copper-catalyzed conversion to thiuram disulfides, which oxidize glutathione in a redox cycle without the release of reactive oxygen species

We have reported previously that diethyldithio-carbamate (DDC) and pyrrolidine dithiocarbamate (PDTC) induce apoptosis in rat thymocytes. Apoptosis was shown to be dependent upon the transport of external Cu ions into the cells and was accompanied by the oxidation of intracellular glutathione, indicating the inducement of pro-oxidative conditions (C. S. I. Nobel, M. Kimland, B. Lind, S. Orrenius, and A. F. G. Slater, J. Biol. Chem. 270, 26202-26208, 1995). In the present investigation we have examined the chemical reactions underlying these effects. Evidence is presented to suggest that dithiocarbamates undergo oxidation by CuII ions, resulting in formation of the corresponding thiuram disulfides, which are then reduced by glutathione, thereby generating the parent dithiocarbamate and oxidized glutathione (glutathione disulfide). Although DDC and PDTC were found to partially stabilize CuI ions, limited redox cycling of the metal ion was evident. Redox cycling did not, however, result in the release of reactive oxygen species, which are believed to be scavenged in situ by the dithiocarbamate. DDC and PDTC were, in fact, shown to prevent copper-dependent hydroxyl radical formation and DNA fragmentation in model reaction systems. The thiuram disulfide disulfiram (DSF) was found to induce glutathione oxidation, DNA fragmentation, and cell killing more potently than its parent dithiocarbamate, DDC. Of particular importance was the finding that, compared with DDC, the actions of DSF were less prone to inhibition by the removal of external copper ions with a chelating agent. This observation is consistent with our proposed mechanism of dithiocarbamate toxicity, which involves their copper-catalyzed conversion to cytotoxic thiuram disulfides.

Alteration of redox state of human serum albumin in patients under anesthesia and invasive surgery

Human serum albumin is a mixture of mercapt- (HMA, reduced form) and nonmercaptalbumin (HNA, oxidized form). We studied the mercapt<-->nonmercapt conversion of human serum albumin, which reflects the redox state of the extracellular fluids, in cardiac and other common surgical_ patients using high-performance liquid chromatography. Mean values of [(HMA)/(HMA+HNA)]+/-standard deviation, fHMA+/-sigma], for patients who received common surgery (group 1) and cardiac surgery (group 2) at the start of anesthesia were 0.636+/-0.050 (n = 83) and 0.615+/-0.062 (n = 14), respectively. fHMA values were markedly lower than those for healthy male adults of 0.750+/-0.028 (n = 28). fHMA values increased at 24 h after the start of anesthesia and decreased on the 4th postoperative day in most of the patients. These postoperative changes were prominent in cardiac surgical patients. Although fHMA values after the 7th postoperative day recovered to those at the start of anesthesia in almost all of common surgical patients, those in cardiac surgical patients never recovered even on the 21st postoperative day.

A sulfhydryl oxidase from chicken egg white

A dimeric glycoprotein containing one FAD per approximately 80,000 Mr subunit has been isolated from chicken egg white and found to have sulfhydryl oxidase activity with a range of small molecular weight thiols. Dithiothreitol was the best substrate of those tested, with a turnover number of 1030/min, a Km of 150 microM, and a pH optimum of about 7.5. Oxidation of thiol substrates generates hydrogen peroxide in aerobic solution. Anaerobically, the ferricenium ion is a facile alternative electron acceptor. Reduction of the oxidase with dithionite or dithiothreitol under anaerobic conditions yields a two-electron intermediate (EH2) showing a charge transfer band (lambdamax 560 nm; epsilonobs 2.5 mM-1 cm-1). Complete bleaching of the flavin and discharge of the charge transfer complex require a total of four electrons. Borohydride and catalytic photoreduction give the same spectral changes. EH2, but not the oxidized enzyme, is inactivated by iodoacetamide with alkylation of 2.7 cysteine residues/subunit. These data indicate that the oxidase contains a redox-active disulfide bridge generating a thiolate to oxidized flavin charge transfer complex at the EH2 level. Sulfite treatment does not form the expected flavin adduct with the native enzyme but cleaves the active site disulfide, yielding an air-stable EH2-like species. The close functional resemblance of the oxidase to the pyridine nucleotide-dependent disulfide oxidoreductase family is discussed.

Age-related change in redox state of human serum albumin

Human serum albumin (HSA) is the mixture of human mercaptalbumin (HMA, reduced form) and human nonmercaptalbumin (HNA, oxidized form). We developed a rapid and concise HPLC system to obtain the clear resolution of HSA into HMA and HNA, using an Asahipak GS-520H column. The mean value of the fraction of HMA (f(HMA)) for healthy young male subjects was 0.76 +/- 0.04 (n = 54). However, the f(HMA, 60-90) value for healthy elderly subjects (where the numbers in brackets indicate the range of ages) was 0.48 +/- 0.06 (n = 183). In healthy elderly subjects, f(HMA) was significantly lower than in healthy young male subjects, indicating that HSA in the elderly becomes more oxidized than in the young subjects. Consequently, we suggest that one of the important functions of serum albumin could be to participate in the maintenance of a constant redox potential in the extracellular fluids, thus securing a certain redox buffer capacity. f(HMA) on HSA might reflect this redox buffer capacity with age.

Glutathione and glycine in acute renal failure

Glutathione is an important intracellular antioxidant in virtually all tissues, including the kidney. In the kidney, it has a rapid turnover in tubule cells and likely plays a role in any oxidant-related events which contribute to the tubule cell injury which occurs during acute renal failure. It was surprising, therefore, to find that the component amino acid, glycine, rather than glutathione itself, most strongly modulated the sensitivity of tubules cells to a variety of insults in several in vitro systems where these processes can be studied most directly. This paper reviews available evidence concerning the nature of both glutathione and glycine effects, their expression in vivo in in vitro, and their implications for understanding acute renal failure.

Purification and properties of sulfhydryl oxidase from bovine pancreas

Immunofluorescent studies showed that antibodies prepared against bovine milk sulfhydryl oxidase reacted with acinar cells of porcine and bovine pancreas. A close inspection of the specific location within bovine pancreatic cells revealed that the zymogen granules, themselves, bound the fluorescent antibody. Bovine pancreatic tissue was homogenized in 0.3 M sucrose, then separated into the zymogen granule fraction by differential centrifugation. The intact zymogen granules were immunofluorescent positive when incubated with antibodies to bovine milk sulfhydryl oxidase, and glutathione-oxidizing activity was detected under standard assay conditions. Pancreatic sulfhydryl oxidase was purified from the zymogen fraction by precipitation with 50% saturated ammonium sulfate, followed by Sepharose CL-6B column chromatography. Active fractions were pooled and subjected to covalent affinity chromatography on cysteinylsuccinamidopropyl-glass using 2 mM glutathione as eluant at 37 degrees C. The specific activity of bovine pancreatic sulfhydryl oxidase thus isolated was 10-20 units/mg protein using 0.8 mM glutathione as substrate. Ouchterlony double-diffusion studies showed that antibody directed against the purified bovine milk enzyme reacted identically with pancreatic sulfhydryl oxidase. The antibody also immunoprecipitated glutathione-oxidizing activity from crude pancreatic homogenates. Western blotting analysis indicated a 90,000 Mr antigen-reactive band in both bovine milk and pancreatic fractions while sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed a single silver-staining protein with an apparent Mr 300,000. Thus, we believe that sulfhydryl oxidase may exist in an aggregated molecular form. Bovine pancreatic sulfhydryl oxidase catalyzes the oxidation of low-molecular-weight thiols such as glutathione, N-acetyl-L-cysteine, and glycylglycyl-L-cysteine, as well as that of a high-molecular-weight protein substrate, reductively denatured pancreatic ribonuclease A.

Cytoprotective effects of glycine and glutathione against hypoxic injury to renal tubules

Roles for both the tripeptide, GSH, and individual amino acids in modifying the cellular response to oxygen deprivation-induced injury have been suggested by prior work in kidney and other tissues, but the precise interrelationships have not been clearly defined. We have studied the effects of GSH, its component amino acids, and related compounds on the behavior of isolated renal proximal tubules in a well characterized model of hypoxic injury in vitro. GSH, the combination of cysteine, glutamate, and glycine and glycine alone, when present in the medium during 30 min hypoxia, a duration sufficient to produce extensive irreversible injury in untreated tubules, were protective. Significant effects were detected at 0.25 mM concentrations of the reagents, and protection was nearly complete at concentrations of 1 mM and above. Glutamate and cysteine alone were not protective. The exogenous GSH added to the tubule suspensions was rapidly degraded to its component amino acids. Treatment of tubules with GSH or cysteine, but not glycine, increased intracellular GSH levels. Oxidized GSH was protective. Serine, N-(2-mercaptopropionyl)-glycine, and a panel of agents known to modify injury produced by reactive oxygen metabolites were without benefit. These observations identify a novel and potent action of glycine to modify the course of hypoxic renal tubular cell injury. This effect is independent of changes in cellular GSH metabolism and appears to be unrelated to alterations of cell thiols or reactive oxygen metabolites. Further elucidation of its mechanism may provide insight into both the basic pathophysiology of oxygen deprivation-induced cell injury and a practical way to ameliorate it.

The nonenzymatic oxidation of glutathione in the presence of plasmalike concentrations of disulfides and copper ions

The oxidation of glutathione catalyzed by a combination of low concentrations of disulfides and copper and iron ions (as they occur in the blood plasma) was investigated and compared with data obtained in vivo studies. At pH 7.4 and 37 degrees C oxidation of glutathione (3 mmol/L) in a solution saturated with oxygen could be induced from 0 to 3, 5, 10, and 21 nmol/min and mL by the addition of 0.1, 1.0, 10, and 100 mumol/L CuCl2, respectively. The presence of 50 mumol/L cystinylbisglycine as an additional component increased the rate of oxidation by a factor between two and three. Cystine was only about one third as active as cystinylbisglycine, and trans-4,5-dihydroxy-1,2-dithiane, the disulfide derivative of dithiothreitol, was even less effective in propagating glutathione oxidation. FeCl2 in combination with the disulfides was 30 times less active than copper as a catalyst. With plasmalike concentrations of the reactants, a rate of glutathione oxidation of 0.2 to 0.8 nmol/min and mL, depending on the availability of free plasma copper, could be approximated. This rate corresponds to 8% to 30% of total plasma glutathione oxidation.

Mechanism and relevance of glutathione mutagenicity

The ubiquitous tripeptide glutathione (GSH) has previously been shown to be mutagenic to Salmonella typhimurium TA100 when incubated with kidney subcellular fractions at physiological concentrations (Glatt et al., 1983). Here we report that the mutagenic effect of GSH can be inhibited by the use of the gamma-glutamyl-transpeptidase (gamma-GT) inhibitor anthglutin and by the metal chelators bathocuproine, EDTA and diethyldithiocarbamate. As the chelating agents did not inhibit gamma-GT activity this suggested that the mechanism underlying the mutagenic effect of GSH was at least a two-step process, dependent upon the cleavage of GSH by gamma-GT and the presence of either free transition metals or those contained in enzymes such as glutathione oxidase. As gamma-GT is located on the outer surface of kidney tubule cells and is therefore exposed to relatively low concentrations of GSH, and the precise physiological control of levels of transition metals, this mechanism is unlikely to occur in vivo.

The effect of cytochrome P-450 and reduced glutathione on the ATP-dependent calcium pump of hepatic microsomes from male rats

In the presence of ATP hepatic microsomes sequester calcium. This sequestration is thought to be important in the modulation of free cytosolic calcium concentration. We find that on the addition of NADPH the uptake of calcium by the hepatic microsomes is inhibited 27-85%. This inhibition is reversed by the addition of 1 mM reduced glutathione (85-91% of control), incubation under a nitrogen atmosphere (112% of control), or incubation in a 80% carbon monoxide/20% oxygen atmosphere (75% of control). Superoxide dismutase had no effect on the inhibition, while catalase reversed the inhibition by 35%. The addition of 1 mM reduced glutathione at 2 and 5 min after the addition of NADPH led to uptakes of calcium which paralleled the uptake seen when the reduced glutathione was added at the beginning of the incubation. The effect of reduced glutathione showed saturation kinetics with a Km of 10 microM. Together these data suggest that cytochrome P-450 reduces the activity of the microsomal ATP-dependent calcium pump both by the production of hydrogen peroxide and by the direct oxidation of the protein thiols. The reversal of this effect by reduced glutathione appears to be enzymatically catalyzed.

Purification and properties of the membranal thiol oxidase from porcine kidney

A thiol oxidase was purified from porcine kidney cortex by chromatography of detergent-solubilized plasma membranes on cysteinylsuccinamidopropyl-glass beads, hydroxyapatite, and Sephacryl S-200. The oxidase was purified 2600-fold; 28% recovery of activity was obtained. With glutathione as substrate, the apparent Km was 0.73 mM and the V max was a 4.4 U/mg protein. The reaction catalyzed was 2 RSH + O2----RSSR + H2O2, and superoxide production was not detected during the reaction. Other low molecular weight thiols, including cysteine, dithiothreitol, N-acetylcysteine, and cysteamine, were substrates for the oxidase; 2-mercaptoethanol, reductively denatured ribonuclease A, and chymotrypsinogen A were not substrates. Analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed one band corresponding to 70 kDa; gel filtration on a Sephacryl column produced a single elution of activity with a protein corresponding to 120 kDa, indicating that the functional form is a dimer. On a high-pressure gel permeation column the protein eluted at 70 kDa under dilute conditions but at greater than 200 kDa at high concentrations, indicating that the protein also aggregates into larger multimers. Activity was inhibited by copper chelators, L-(alpha S,5S)-alpha-amino-3-chloro-4,5-dihydro-5-isoxazoleacetic acid (acivicin), H2O2, and N-ethylmaleimide, suggesting the presence of copper and a sulfhydryl group at the active site. Following treatment with metal chelators, enzyme activity was reconstituted with CuSO4, but not with FeSO4. The purified enzyme contained 1 mol copper per subunit which was undetectable by electron paramagnetic resonance, suggesting that the copper is in a binuclear complex.

Peroxidase catalysed oxygen activation by arylamine carcinogens and phenol

Peroxidase catalysed the formation of active oxygen in the presence of NADH or GSH and traces of H2O2 and arylamine or phenolic substrates. Some oxygen activation occurred with some arylamines even in the absence of NADH or GSH. Oxygen consumption was proportional to the NADH oxidized or GSSG formed. Approximately 0.80 and 0.40 mol of oxygen were consumed per mole of NADH or GSH oxidized respectively. The requirement for trace amounts of hydrogen peroxide and arylamine or phenolic substrates suggest that redox cycling resulted in H2O2 formation. It is proposed that initially formed phenoxy radicals or arylamine cation radicals oxidize NADH or GSH to radicals which react with oxygen to form superoxide radicals and H2O2.

Distribution of oxidized and reduced forms of glutathione and cysteine in rat plasma

The distribution of the glutathionyl moiety between reduced and oxidized forms in rat plasma was markedly different than that for the cysteinyl moiety. Most of the glutathionyl moiety was present as mixed disulfides with cysteine and protein whereas most of the cysteinyl moiety was present as cystine. Seventy percent of total glutathione equivalents was bound to proteins in disulfide linkage. The distribution of glutathione equivalents in the acid-soluble fraction was 28.0% as glutathione, 9.5% as glutathione disulfide, and 62.6% as the mixed disulfide with the cysteinyl moiety. In contrast, 23% of total cysteine equivalents was protein-bound. The distribution of cysteine equivalents in the acid-soluble fraction was 5.9% as cysteine, 83.1% as cystine, and 10.8% as the mixed disulfide with the glutathionyl moiety. A first-order decline in glutathione occurred upon in vitro incubation of plasma and was due to increased formation of mixed disulfides of glutathione with cysteine and protein. This indicates that plasma thiols and disulfides are not at equilibrium, but are in a steady-state maintained in part by transport of these compounds between tissues during the inter-organ phase of their metabolism. The large amounts of protein-bound glutathione and cysteine provide substantial buffering which must be considered in analysis of transient changes in glutathione and cysteine. In addition, this buffering may protect against transient thiol-disulfide redox changes which could affect the structure and activity of plasma and plasma membrane proteins.