Toxicological implications of the mixed-function oxidase catalyzed metabolism of carbon disulfide.

The results of these studies have indicated that the decrease in the activity of the hepatic mixed-function oxidase enzyme system and the concentration of cytochrome P-450 seen on incubation of carbon disulfide (CS2) with rat liver microsomes in the presence of NADPH is the result of the binding of the sulfur atom released in the mixed-function oxidase catalyzed metabolism of CS2 to carbonyl sulfide (COS). Moreover, it appears that COS is further metabolized by the mixed-function oxidase enzyme system to CO2 and that, analogous to the metabolism of CS2 to COS, the sulfur atom released in this reaction also binds to the microsomes and inhibits benzphetamine metabolism and decreases the concentration of cytochrome P-450 detectable as its carbon monoxide complex. The results of these studies also suggest that the decrease in the concentration of cytochrome P-450 and the liver damage seen on in vivo administration of CS2 to phenobarbital pretreated rats, is due to the mixed-function oxidase catalyzed release and binding of the sulfur atoms of CS2. The decrease in the concentration of cytochrome P-450 seen on incubation of CS2 with rat liver microsomes in the presence of NADPH does not appear to be the result of destruction of the heme group or its dissociation from the apoenzyme since the total amount of protoheme is unchanged in microsomes which have been incubated with CS2 and NADPH as compared to those not incubated with these compounds.     

Metabolism of carbon tetrachloride to phosgene

Aerobic incubation of hepatic microsomal fractions in the presence of carbon tetrachloride, NADPH and cysteine resulted in the formation of phosgene which was identified by gas chromatography/mass spectrometry as the adduct, 2-oxothiazolidine-4-carboxylic acid, formed by its reaction with cysteine. [¹³C]-Carbon tetrachloride was metabolized to 2-[¹³C]-oxothiazolidine-4-carboxylic acid the , when carbon tetrachloride was incubated in the presence of [¹⁸O]-O₂, 2- [¹⁸O]-oxothiazolidine-4-carboxylic acid was formed. The reaction was inhibited by carbon monoxide showing the involvement of the cytochrome P-450-dependent mixed function oxidase system. The metabolism of carbon tetrachloride to phosgene may play a role in the production of hepatotoxicity by this compound.     

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.     

Transient Kinetic Analysis of Hydrogen Sulfide Oxidation Catalyzed by Human Sulfide Quinone Oxidoreductase

The first step in the mitochondrial sulfide oxidation pathway is catalyzed by sulfide quinone oxidoreductase (SQR), which belongs to the family of flavoprotein disulfide oxidoreductases. During the catalytic cycle, the flavin cofactor is intermittently reduced by sulfide and oxidized by ubiquinone, linking H₂S oxidation to the electron transfer chain and to energy metabolism. Human SQR can use multiple thiophilic acceptors, including sulfide, sulfite, and glutathione, to form as products, hydrodisulfide, thiosulfate, and glutathione persulfide, respectively. In this study, we have used transient kinetics to examine the mechanism of the flavin reductive half-reaction and have determined the redox potential of the bound flavin to be −123 ± 7 mV. We observe formation of an unusually intense charge-transfer (CT) complex when the enzyme is exposed to sulfide and unexpectedly, when it is exposed to sulfite. In the canonical reaction, sulfide serves as the sulfur donor and sulfite serves as the acceptor, forming thiosulfate. We show that thiosulfate is also formed when sulfide is added to the sulfite-induced CT intermediate, representing a new mechanism for thiosulfate formation. The CT complex is formed at a kinetically competent rate by reaction with sulfide but not with sulfite. Our study indicates that sulfide addition to the active site disulfide is preferred under normal turnover conditions. However, under pathological conditions when sulfite concentrations are high, sulfite could compete with sulfide for addition to the active site disulfide, leading to attenuation of SQR activity and to an alternate route for thiosulfate formation.     

The enzyme that synthesizes tetrahydrobiopterin from 6-pyruvoyl-tetrahydropterin in the lemon mutant silkworm consists of two carbonyl reductases

Tetrahydrobiopterin plays an important role in the biosynthesis of certain neurotransmitters. Using DEAE-Sepharose FF column chromatography, we separated the enzyme that synthesizes tetrahydrobiopterin from 6-pyruvoyl-tetrahydropterin [which is different from sepiapterin reductase (EC 1.1.1.153)] in the lemon mutant of the silkworm Bombyx mori into two fractions, which were named carbonyl reductase I (CR I) and carbonyl reductase II (CR II). The CR I enzyme converted 6-pyruvoyl-tetrahydropterin to 6-lactoyl-tetrahydropterin, while CR II converted 6-pyruvoyl-tetrahydropterin to 1'-hydroxy-2'-oxopropyl-tetrahydropterin, both reactions occurring only in the presence of NADPH. Neither of the two carbonyl reductases alone was able to catalyze the conversion of 6-pyruvoyl-tetrahydropterin to tetrahydrobiopterin in the presence of NADPH. However, when CR I was mixed with CR II in the reaction mixture, 6-pyruvoyl-tetrahydropterin was reduced to tetrahydrobiopterin in the presence of NADPH. Moreover, CR I catalyzed the formation of tetrahydrobiopterin from 1'-hydroxy-2'-oxopropyl-tetrahydropterin, while CR II converted 6-lactoyl-tetrahydropterin to tetrahydrobiopterin, both reactions occurring only in the presence of NADPH. Our results suggest that there are two potential routes for formation of tetrahydrobiopterin from 6-pyruvoyl-tetrahydropterin in the lemon mutant silkworm. In the first route, 1'-hydroxy-2'-oxopropyl-tetrahydropterin is formed from 6-pyruvoyl-tetrahydropterin by CR II and then reduced to tetrahydrobiopterin by CR I, both reactions occurring only in the presence of NADPH. In the other route, 6-pyruvoyl-tetrahydropterin is reduced to 6-lactoyl-tetrahydropterin by CR I and then converted to tetrahydrobiopterin by CR II, both reactions occurring only in the presence of NADPH.     

Chromate metabolism in liver microsomes

The carcinogenicity and mutagenicity of various chromium compounds have been found to be markedly dependent on the oxidation state of the metal. The carcinogen chromate was reduced to chromium(III) by rat liver microsomes in vitro. Metabolism of chromate by microsomal enzymes occurred only in the presence of either NADPH or NADH as cofactor. The chromium(III) generated upon metabolism formed a complex with the NADP⁺ cofactor. Significant binding of chromium to DNA occurred only when chromate was incubated in the presence of microsomes and NADPH. Specific inhibitors of the mixed function oxidase enzymes, 2′-AMP, metyrapone, and carbon monoxide, inhibited the rate of reduction of chromate by microsomes and NADPH. The possible relationship of metabolism of chromate and its interaction with nucleic acids to its carcinogenicity and mutagenicity is discussed.     

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.     

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.     

The effects of NADPH and 3-hydroxy-3-methylglutaryl-CoA on the thiol/disulfide redox behavior of rat liver microsomal 3-hydroxy-3-methylglutaryl-CoA reductase

Microsomal 3-hydroxy-3-methylglutaryl-CoA reductase isolated from the livers of rats fed a diet containing cholestyramine (HMGR-C) is oxidized to a protein-SS-protein disulfide via a thermodynamically favorable thiol/disulfide exchange in glutathione redox buffers which approach the normal in vivo redox poise. In the presence of either substrate (NADPH or 3-hydroxy-3-methylglutaryl-CoA), the equilibrium thiol/disulfide redox behavior of HMGR-C is substantially different than that observed in the absence of substrates or in the presence of both substrates. NADPH present during redox equilibrium in a glutathione redox buffer decreases the equilibrium constant for formation of the protein-SS-protein disulfide (Kox,i) from 0.55 +/- 0.07 M to 0.18 +/- 0.02 M and increases the Kox,m for formation of an inactive protein-SS-glutathione mixed disulfide from less than 1 to 6 +/- 1. The presence of 3-hydroxy-3-methylglutaryl-CoA during redox equilibrium has a similar effect, decreasing the Kox,i for protein-SS-protein disulfide formation to 0.10 +/- 0.02 M and increasing the Kox,m for protein-SS-glutathione mixed disulfide formation to 3.8 +/- 0.9. A three-state model is developed which describes the simultaneous accumulation of protein-SS-protein and protein-SS-glutathione mixed disulfides at redox equilibrium with glutathione redox buffers. Because of the different redox behavior of the free and substrate-liganded forms of the enzyme, addition of 3-hydroxy-3-methylglutaryl-CoA or NADPH to HMGR-C at redox equilibrium results in increased reduction and activation of the enzyme.     

Sulfenic acid formation in human serum albumin by hydrogen peroxide and peroxynitrite

Human serum albumin (HSA), the most abundant protein in plasma, has been proposed to have an antioxidant role. The main feature responsible for this property is its only thiol, Cys34, which comprises approximately 80% of the total free thiols in plasma and reacts preferentially with reactive oxygen and nitrogen species. Herein, we show that the thiol in HSA reacted with hydrogen peroxide with a second-order rate constant of 2.26 M(-1) s(-1) at pH 7.4 and 37 degrees C and a 1:1 stoichiometry. The formation of intermolecular disulfide dimers was not observed, suggesting that the thiol was being oxidized beyond the disulfide. With the reagent 7-chloro-4-nitrobenzo-2-oxa-1,3-diazol (NBD-Cl), we were able to detect the formation of sulfenic acid (HSA-SOH) from the UV-vis spectra of its adduct. The formation of sulfenic acid in Cys34 was confirmed by mass spectrometry using 5,5-dimethyl-1,3-cyclohexanedione (dimedone). Sulfenic acid was also formed from exposure of HSA to peroxynitrite, the product of the reaction between nitric oxide and superoxide radicals, in the absence or in the presence of carbon dioxide. The latter suggests that sulfenic acid can also be formed through free radical pathways since following reaction with carbon dioxide, peroxynitrite yields carbonate radical anion and nitrogen dioxide. Sulfenic acid in HSA was remarkably stable, with approximately 15% decaying after 2 h at 37 degrees C under aerobic conditions. The formation of glutathione disulfide and mixed HSA-glutathione disulfide was determined upon reaction of hydrogen peroxide-treated HSA with glutathione. Thus, HSA-SOH is proposed to serve as an intermediate in the formation of low molecular weight disulfides, which are the predominant plasma form of low molecular weight thiols, and in the formation of mixed HSA disulfides, which are present in approximately 25% of circulating HSA.     

Mia40 Combines Thiol Oxidase and Disulfide Isomerase Activity to Efficiently Catalyze Oxidative Folding in Mitochondria

Mia40 (a mitochondrial import and assembly protein) catalyzes disulfide bond formation in proteins in the mitochondrial intermembrane space. By using Cox17 (a mitochondrial copper-binding protein) as a natural substrate, we discovered that, in the presence of Mia40, the formation of native disulfides is strongly favored. The catalytic mechanism of Mia40 involves a functional interplay between the chaperone site and the catalytic disulfide. Mia40 forms a specific native disulfide in Cox17 much more rapidly than other disulfides, in particular, non-native ones, which originates from the recently described high affinity for hydrophobic regions near target cysteines and the long lifetime of the mixed disulfide. In addition to its thiol oxidase function, Mia40 is active also as a disulfide reductase and isomerase. We found that species with inadvertently formed incorrect disulfides are rebound by Mia40 and reshuffled, revealing a proofreading mechanism that is steered by the conformational folding of the substrate protein.     

Conversion of canavanine to alpha-keto-gamma-guanidinooxybutyrate and to vinylglyoxylate and 2-hydroxyguanidine

It was observed previously that hydroxyguanidine is formed in the reaction of canavanine(2-amino-4-guanidinooxybutanoate) with amino acid oxidases. The present work shows that hydroxyguanidine is formed by a nonenzymatic beta,gamma-elimination reaction following enzymatic oxidation at the alpha-C and that the abstraction of the beta-H is general-base catalyzed. The elimination reaction requires the presence in the alpha-position of an anion-stabilizing group--the protonated imino group (iminium ion group) or the carbonyl group. The iminium ion group is more activating than the carbonyl group. Elimination is further facilitated by protonation of the guanidinooxy group. The other product formed in the elimination reaction was identified as vinylglyoxylate (2-oxo-3-butenoate), a very highly electrophilic substance. The product resulting from hydrolysis following oxidation was identified as alpha-keto-gamma-guanidinooxybutyrate (ketocanavanine). The ratio of hydroxyguanidine to ketocanavanine depended upon the concentration and degree of basicity of the basic catalyst and on pH. In the presence of semicarbazide, the elimination reaction was prevented because the imino group in the semicarbazone derivative of ketocanavanine is not significantly protonated. Incubation of canavanine with 5'-deoxypyridoxal also yielded hydroxyguanidine. Since the elimination reactions take place under mild conditions, they may occur in vivo following oxidation at the alpha-C of L-canavanine (ingested or formed endogenously) or of other amino acids with a good leaving group in the gamma-position (e.g., S-adenosylmethionine, methionine sulfoximine, homocyst(e)ine, or cysteine-homocysteine mixed disulfide) by an L-amino acid oxidase, a transaminase, or a dehydrogenase. Therefore, vinylglyoxylate may be a normal metabolite in mammals which at elevated concentrations may contribute to the in vivo toxicity of canavanine and of some of the other above-mentioned amino acids.     

Metabolism of diphenyloxazole (PPO) by mouse liver microsomes.

2, 5-Diphenyloxazole (PPO) is an inducer and inhibitor of aryl hydrocarbon hydroxylase. We report that PPO is itself metabolized to an alkali-extractable metabolite with intense fluorescence. The fluorescence spectra of excitation and emission indicate peaks at 345 nm and 510 nm, respectively. The reaction is linear with respect to time and enzyme concentration. NADPH is required for activity and the reaction is inhibited by carbon monoxide and 7, 8-benzoflavone but not by SKF-525A or hexobarbital. The intensity of fluorescence produced is similar to that of benzo (a) pyrene. PPO may be a useful model compound in studies of drug metabolism by the mixed function oxidase.     

Fungal gliotoxin targets the onset of superoxide-generating NADPH oxidase of human neutrophils

Gliotoxin from Aspergillus, bearing a S&bond;S bond in its structure, prevented the onset of O(-)(2) generation by the human neutrophil NADPH oxidase in response to phorbol myristate acetate (PMA). Gliotoxin affected the activation process harder than the activated oxidase, as shown by its stronger inhibition when added to neutrophils prior to, than post-PMA at maximum enzyme turnover. Decreased O(-)(2) generation persisted even if cells treated with gliotoxin were subsequently washed, with half-inhibition concentrations (IC(50)) of 5.3, and 3.5 microM for treatments of 15 and 30 min, respectively. In addition, gliotoxin made neutrophils reduce cytochrome c regardless of absence of PMA, through its reaction with intracellular reductants in an oxygen-dependent process, named redox cycling. Thus, we next tested whether preincubation of neutrophils with gliotoxin under hypoxic conditions would relieve the inhibition of NADPH oxidase. Instead, this prevention of redox cycling significantly favored damage to the NADPH oxidase with an IC(50) of 0.009 microM. Moreover, conversion of gliotoxin to its dithiol derivative by addition of reduced dithiothreitol during incubation protected cells from losing oxidase activity. These findings support that the disulfide form of gliotoxin targets NADPH oxidase activation.     

Hepatic carbonyl sulfide metabolism.

Carbonyl sulfide (COS) is rapidly metabolized by isolated rat hepatocytes, as determined by COS disappearance. However, upon termination of the reaction by acidification much of the metabolized COS reappears in the headspace of the reaction vessel. The COS disappearance when determined after acidification is equal to the formation of carbon dioxide and an inorganic sulfur containing compound(s). The metabolism of COS by hepatocytes is inhibited by acetazolamine but not by carbon disulfide or inhibitors of the cytochrome P-450 containing monooxygenase system. Upon subcellular fractionation, the majority of hepatic COS metabolizing activity is found in the cytosol. Additional experiments with a partially purified enzyme indicate that COS is a substrate for hepatic carbonic anhydrase.     

Trypsinolysis promotes disulfide formation between 21- and 50-kilodalton segments of myosin subfragment 1 during reaction with 5,5'-dithiobis(2-nitrobenzoic acid)

The reaction of 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) with S1 and tryptic S1 has been examined to identify the sites of mixed and intramolecular disulfides formed in the initial and final stages of the reaction in these two forms of S1. With undigested S1, the two mixed disulfide bonds initially formed were found to be in the 21-kDa segment. The intramolecular disulfide bond, formed in the subsequent slow phase of the reaction, was also found to be mainly confined to the 21-kDa segment although a small fraction arose from disulfide formation between the 21-kDa and 50-kDa segments. Only 35% of the light chain was modified in undigested S1 after 24 h. For tryptic S1, the initial reaction also led to the formation of mixed disulfides in the 21-kDa segment. However, in the second slower phase, the formation of the intramolecular disulfide occurred primarily between thiols in the 21-kDa and 50-kDa fragments, and in this case, the light chain was labeled to about 60% after 24 h. The enhanced formation of disulfide links between 21-kDa and 50-kDa domains in tryptic S1 points to an increase in flexibility between the thiol-containing regions of these segments.     

Neutrophil extracellular trap cell death requires both autophagy and superoxide generation

Neutrophil extracellular traps (NETs) are extracellular chromatin structures that can trap and degrade microbes. They arise from neutrophils that have activated a cell death program called NET cell death, or NETosis. Activation of NETosis has been shown to involve NADPH oxidase activity, disintegration of the nuclear envelope and most granule membranes, decondensation of nuclear chromatin and formation of NETs. We report that in phorbol myristate acetate (PMA)-stimulated neutrophils, intracellular chromatin decondensation and NET formation follow autophagy and superoxide production, both of which are required to mediate PMA-induced NETosis and occur independently of each other. Neutrophils from patients with chronic granulomatous disease, which lack NADPH oxidase activity, still exhibit PMA-induced autophagy. Conversely, PMA-induced NADPH oxidase activity is not affected by pharmacological inhibition of autophagy. Interestingly, inhibition of either autophagy or NADPH oxidase prevents intracellular chromatin decondensation, which is essential for NETosis and NET formation, and results in cell death characterized by hallmarks of apoptosis. These results indicate that apoptosis might function as a backup program for NETosis when autophagy or NADPH oxidase activity is prevented.     

Photochemical reactions of 4-thiouridine disulfide and 4-benzylthiouridine--the involvement of the 4-pyrimidinylthiyl radical.

The reactions of a disulfide and a benzylsulfide derived from 4-thiouridine were studied in aqueous acetonitrile using stationary and laser flash photolysis methods. Irradiation of the compounds results in specific cleavage of the S-S bond in the disulfide and the S-CH(2) bond in the sulfide. Identical pyrimidine-derived intermediates were observed in the transient absorption spectra (lambda(max) = 420 nm, epsilon(max) approximately 2500 M(-1) cm(-1)) recorded for both compounds in laser flash photolysis experiments. The intermediate was identified as the 4-pyrimidinylthiyl radical. Irradiation of the disulfide in the absence of oxygen gives 4-thiouridine while the sulfide under identical conditions produced, additionally, 3-benzyl-4-thiouridine as a stable photoproduct. The formation of the latter photoproduct provides evidence for the existence of the N-centered 4-thioxopyrimidynyl radical formed from the initially produced S-centered (thiyl) radical. The 4-thiouridine is formed from the radicals generated in the primary photochemical step by an H abstraction reaction from the solvent (acetonitrile) or from additives (alcohols) that were purposely added. Interestingly, in contrast to the benzylsulfide, the photoreaction of the disulfide is quenched by molecular oxygen with the concomitant formation of uridine. However it appears that uridine is not produced as a result of the reaction of the radicals with oxygen. A mechanism is proposed for the photochemical transformations of the disulfide and benzylsulfide derived from 4-thiouridine. The proposed mechanism is based on the structures of the identified stable photoproducts, the values of the photoreaction quantum yields determined under differing irradiation conditions, and the flash photolysis results.     

Inhibition of protein carbonyl formation and lipid peroxidation by glutathione in rat liver microsomes.

The peroxidation of rat liver microsomal lipids is stimulated in the presence of iron by the addition of NADPH or ascorbate and is inhibited by the addition of glutathione (GSH). The fate of GSH and the oxidative modification of proteins under these conditions have not been well studied. Rat liver microsomes were incubated at 37 degrees C under 95% O2:5% CO2 in the presence of 10 microM ferric chloride, 400 microM ADP, and either 450 microM ascorbic acid or 400 microM NADPH. Lipid peroxidation was assessed in the presence 0, 0.2, 0.5, 1, or 5 mM GSH by measuring thiobarbituric acid reactive substance (TBARS) and oxidative modification of proteins by measuring protein thiol and carbonyl groups. GSH inhibited TBARS and protein carbonyl group formation in both ascorbate and NADPH systems in a dose-dependent manner. Heat denaturing of microsomes or treatment with trypsin resulted in the loss of this protection. The formation of protein carbonyl groups could be duplicated by incubating microsomes with 4-hydroxynonenal. Ascorbate-dependent peroxidation caused a loss of protein thiol groups which was diminished by GSH only in fresh microsomes. Both boiling and trypsin treatment significantly decreased the basal protein thiol content of microsomes and enhanced ascorbate-stimulated lipid peroxidation. Protection against protein carbonyl group formation by GSH correlated with the inhibition of lipid peroxidation and appeared not to be due to the formation of the GSH conjugate of 4-hydroxynonenal as only trace amounts of this conjugate were detected. Ninety percent of the GSH lost after 60 min of peroxidation was recoverable as borohydride reducible material in the supernatant fraction. The remaining 10% could be accounted for as GSH-bound protein mixed disulfides. However, only 75% of the GSH lost during peroxidation appeared as glutathione disulfide, suggesting that some was converted to other soluble borohydride reducible forms. These data support a role for protein thiol groups in the GSH-mediated protection of microsomes against lipid peroxidation.