Enzyme-catalysed conjugations of glutathione with unsaturated compounds

The histopathological and biochemical response of the stomach of male F344/N rats following two weeks of oral dosing with ethyl acrylate

Male F344/N rats were dosed with ethyl acrylate (EA) either by daily gavage or in the drinking water for 2 weeks. The gavage dose levels were 0, 2, 10, 20, 50, 100, and 200 mg/kg; the drinking water dose concentrations were 0, 200, 1,000, 2,000, and 4,000 ppm (corresponding to 0, 23, 99, 197, and 369 mg/kg/day, respectively). In those animals dosed by gavage, irritation of the forestomach increased in incidence and severity over the 20-200 mg/kg dose range. In those animals dosed with EA in the drinking water, a much lower incidence of forestomach irritation and less severe lesions were observed at corresponding dose levels. No lesions were observed in the glandular stomach from either of the 2 modes of oral administration. Following 2 weeks of gavage dosing with EA, the total non-protein sulfhydryl (NPSH) content of the forestomach and glandular stomach, and the NPSH concentration of the liver were determined 2-24 hr after the last gavage dose. Animals dosed at 200 mg/kg reached approximately 11% of the initial NPSH content in the forestomach at 6 hr after dosing. NPSH depletion of this magnitude has been associated with cytotoxicity of other tissues in other studies. By contrast, either the glandular stomach nor liver were depleted of NPSH to levels generally associated with toxicity. These observations are consistent with the conclusion that bolus dosing of EA induces severe depletion of critical cellular thiols in the forestomach with toxic consequences, but not in the glandular stomach or liver. Changing the mode of oral administration for EA to continued small doses in the drinking water allowed efficient detoxification and did not induce sulfhydryl depletion or comparable forestomach toxicity at the same daily body burden.

Effective depletion of glutathione in rat striatum and substantia nigra by L-buthionine sulfoximine in combination with 2-cyclohexene-1-one

The effects of L-buthionine sulfoximine (L-BSO), 2-cyclohexene-1-one and diethylmaleate (DEM) on the concentration of rat brain glutathione (GSH) were investigated. Both DEM and 2-cyclohexene-1-one, administered subcutaneously, produced marked and rapid reduction of brain GSH, but 2-cyclohexene-1-one appeared less toxic than DEM. Six hours after 2-cyclohexene-1-one (100 microliters/kg) the striatal GSH concentration was 35% of control values, whereas the level was 55% of controls at 24 h and 80% of controls at 48 h. Similar results were obtained with DEM (800 microliters/kg). L-BSO (3.2 mg), administered intracerebroventricularly, produced a slower depletion of brain GSH. A 55% reduction of striatal GSH was obtained 24 h after the administration, and the level was approximately 50% of control at 48 h. Thus, the effect of 2-cyclohexene-1-one and DEM is rapid in onset but relatively short lasting, whereas the disappearance of brain GSH after L-BSO is slower but the effect is more long-lasting. By combining L-BSO with either 2-cyclohexene-1-one or DEM both a rapid and long-lasting GSH depletion was obtained that was more profound than after any of the drugs alone. The combination of L-BSO and 2-cyclohexene-1-one was well tolerated, but the combination of L-BSO and DEM led to death in half of the rats the second day after injection. The disappearance rate of GSH after L-BSO alone gives an estimate of the turn-over of GSH. We found the turn-over of GSH to be higher in the substantia nigra pars compacta than in the striatum. The present work suggest that L-BSO and 2-cyclohexene-1-one would be very useful for evaluation of the biological role of GSH in the central nervous system.

Reactivity of glutathione with alpha, beta-unsaturated ketone flavouring substances

The relative reactivities of a number of alpha, beta-unsaturated ketones used as flavourings were determined using glutathione as the nucleophile. Monosubstitution at the beta-position of the alpha, beta-unsaturated system impeded nucleophilic addition by approximately 1000 times. Beta-Disubstitution reduced reactivity by more than 100,000 times. Endocyclic alpha, beta-unsaturated ketones were generally less reactive than alicyclic analogues. By way of comparison, the most reactive flavouring investigated, 2-octene-4-one, was consumed by glutathione about 700 times less rapidly than was methylvinyl ketone. Methylvinyl ketone was found to condense with guanylic acid 240,000 times more slowly than with glutathione. It is concluded that alpha, beta-unsaturated ketones used as flavourings generally possess low electrophilicity.

Effect of oral glutathione on hepatic glutathione levels in rats and mice

Administration of oral glutathione (GSH) increases hepatic GSH levels in fasted rats, in mice treated with GSH depletors such as diethyl maleate and in mice treated with high doses of paracetamol. An increase in hepatic GSH levels after administration of oral GSH does not occur in animals treated with buthionine sulphoximine, an inhibitor of GSH synthesis. Administration of oral GSH leads to an increase in the concentration of L-cysteine, a precursor of GSH, in portal blood plasma. Oral administration of L-methionine produced a significant decrease of hepatic ATP in fasted rats, but not in fed rats. Administration of N-acetylcysteine or GSH did not affect the hepatic ATP levels. The results show that the oral intake of GSH is a safe and efficient form of administration of its constituent amino acids in cases when GSH synthesis is required to replete hepatic GSH levels.

Dichlorovinyl cysteine (DCVC) in the mouse kidney: tissue-binding and toxicity after glutathione depletion and probenecid treatment

The kidney binding of dichloro[14C]vinyl cysteine (14C-DCVC, 8 mg/kg body wt) and the kidney histopathology of DCVC (5 mg/kg body wt) were examined and compared in female C57BL mice subjected to various treatments. To evaluate the roles of organic anion transport and glutathione (GSH) status, mice were pretreated with probenecid (inhibitor of organic anion transport), L-buthionine-S,R-sulfoximine (BSO; inhibitor of GSH synthesis) or with diethyl maleate (DEM; GSH-depleting agent). In addition, the sites of 14C-DCVC binding in BSO-treated and control mice were monitored by microautoradiography. Probenecid was found to inhibit both kidney binding and toxicity of DCVC. In BSO-treated mice, DCVC binding remained roughly unchanged, whereas nephrotoxicity was severely increased and topographically extended to the subcapsular region. Microautoradiography showed that the site of DCVC binding in the straight portion of the proximal tubule was not changed by BSO. In DEM-treated mice, a clearly decreased DCVC binding was observed, while the effect on nephrotoxicity was minute. The effects of probenecid on DCVC binding and toxicity support a role for carrier-mediated transport of DCVC equivalents into the target cells. The BSO result suggests a protective function of GSH towards the nephrotoxicity of DCVC. Moreover, they support our previous contention that a primary lesion occurs at the site of DCVC binding, followed by a secondary, dose-dependent lesion localized outside the DCVC-binding region. In the case of DEM it is proposed that a DEM-GSH conjugate might compete for the uptake and/or activation of DCVC in the target cells.

Effects of trans-sobrerol on drug metabolizing enzymes in the rat

1. Metabolism of 14C-trans-sobrerol (I) by Sprague-Dawley rat liver microsomes did not result in covalent binding to proteins, lipid peroxidation or cytochrome P-450 destruction. 2. Subacute and chronic treatment of Sprague-Dawley rats with (I) resulted only in an increase in liver cytosolic GSH-S-transferase. 3. Acute treatment of rats with trans-sobrerol or its metabolite, 8-hydroxycarvotanacetone (II) produced considerable GSH depletion, faster in the case of II, in both liver and lung; the original GSH levels were restored within 24 h. No significant increase in lipid peroxidation was found even when GSH was at its lowest level. 4. UDP-glucuronyltransferase and GSH-S-transferase conjugation occurred with trans-sobrerol and some of its metabolites although at low rates.

Careful consideration of the effects induced by glutathione depletion in rat liver and heart. The involvement of cytosolic and mitochondrial glutathione pools

One of the most widely used mechanisms by which the role of glutathione (GSH) in cellular functions has been withdrawn, is to deplete GSH intracellularly. The importance of the procedure and xenobiotic chosen to get it is discussed. Mitochondrial GSH plays certainly an important role in maintaining cellular homeostasis. This contribution varies depending on the tissue and the conclusions obtained about the functions of this GSH pool in one organ may not be applied to others. Original data on the subcellular distribution of GSH in myocardial tissue of the rat are presented, and the effect of phorone on both cardiac GSH pools is compared with the effect in liver. The mechanical failure of myocardium after ischemic or reperfusion damage might involve mitochondrial GSH, in view of the literature data referring to the role of thiol groups in energy transfer from mitochondria to cytosol.

Three models of free radical-induced cell injury

Three models of free radical-induced cell injury are presented in this review. Each model is described by the mechanism of action of few prototype toxic molecules. Carbon tetrachloride and monobromotrichloromethane were selected as model molecules for alkylating agents that do not induce GSH depletion. Bromobenzene and allyl alcohol were selected as prototypes of GSH depleting agents. Paraquat and menadione were presented as prototypes of redox cycling compounds. All these groups of toxins are converted, during their intracellular metabolism, to active species which can be radical species or electrophilic intermediates. In most cases the activation is catalyzed by the microsomal mixed function oxidase system, while in other cases (e.g. allyl alcohol) cytosolic enzymes are responsible for the activation. Radical species can bind covalently to cellular macromolecules and can promote lipid peroxidation in cellular membranes. Of course both phenomena produce cell damage as in the case of CCl4 or BrCCl3 intoxication. However, the covalent binding is likely to produce damage at the molecular site where it occurs; lipid peroxidation, on the other hand, besides causing loss of membrane structure, also gives rise to toxic products such as 4-hydroxyalkenals and other aldehydes which in principle can move from the site of origin and produce effects at distant sites. Electrophilic intermediates readily reacts with cellular nucleophiles, primarily with GSH. The result is a severe GSH depletion as in the case of bromobenzene or allyl alcohol intoxication. When the depletion reaches some threshold values lipid peroxidation develops abruptly and in an extensive way. This event is accompanied by cellular death. The reason for which lipid peroxidation develops in a cell severely depleted of GSH remains to be clarified. Probably the loss of the defense systems against a constitutive oxidative stress is not compatible with cellular life. Some free radicals generated by one-electron reduction can react with oxygen to give superoxide anions which can be converted to other more dangerous reactive oxygen species. This is the case of paraquat and menadione. Damage to cellular macromolecules is due to the direct action of these oxygen radicals and, at least in the menadione-induced cytotoxicity, lipid peroxidation is not involved. All these initial events affect the protein sulfhydryl groups in the membranes. Since some protein thiols are essential components of the molecular arrangement responsible for the Ca2+ transport across cellular membranes, loss of such thiols can affect the calcium sequestration activity of subcellular compartments, that is the capacity of mitochondria and microsomes to regulate the cytosolic calcium level.(ABSTRACT TRUNCATED AT 400 WORDS)

Methods for depleting brain glutathione

To search for a technique to deplete reduced glutathione (GSH) in brain, the influence of various types of compounds on brain GSH levels was investigated in mice. Of the compounds tested, cyclohexene-1-one, cycloheptene-1-one and diethyl maleate were shown to be potent GSH depletors in brain as well as in liver. The depletion of cerebral GSH ranged about 40-60% of control levels at 1 and 3 hr after intraperitoneal injection. Cyclohexene, cycloheptene, phorone, acetaminophen, and benzyl chloride caused mild depletion of cerebral GSH, but buthionine sulfoximine did not alter cerebral GSH levels. Further, intracerebroventricular injection of cyclohexene-1-one and cycloheptene-1-one caused depletion of brain GSH to about 60-80% of control levels at 1 hr after injection, and the effects persisted for at least 6 hr. Under these conditions, hepatic GSH was not altered. These results demonstrated that cyclohexene-1-one and cycloheptene-1-one can cause not only a marked depletion of brain GSH by systemic administration, but also depletion of cerebral GSH by intracerebroventricular injection by virtue of being water-soluble compounds. Thus, methods for depleting brain GSH employing both compounds are available for exploring possible functions of cerebral GSH in in vivo systems.

Rat kidney function related to tissue glutathione levels. Effects of different glutathione depletors

1. Rat renal function was evaluated during acute depletion of glutathione (GSH) produced by different doses of diethyl-maleate (DEM) or buthionine-sulfoximine (BSO). 2. Similar alterations in renal function were observed when similar GSH levels were obtained independently of the GSH depletor employed. 3. These results confirm the relationship between GSH levels and renal function.

Glutathione depletion by hyperphagia-induced obesity

Reduced glutathione (GSH) levels in freeze-clamped livers of rats and mice in which hyperphagia is induced by cafeteria diet are 45% lower than in controls. Freshly isolated hepatocytes from mice fed cafeteria diet show a 45% decrease in GSH concentration and a 54% decrease in oxidized glutathione (GSSG) concentration when compared with controls. The rate of GSH synthesis in isolated hepatocytes from control mice is significantly higher than in those from mice fed cafeteria diet. Oral GSH is effective to prevent the decrease in hepatic GSH levels found in cafeteria fed mice.

Alpha-adrenergic modulation of glutathione metabolism in isolated rat hepatocytes

Glutathione metabolism was studied in isolated hepatocytes from 48-h starved rats. Phenylephrine (10 microM, final concentration) was incubated in the presence of a mixture of L-glutamine, glycine, L-serine, and L-methionine (at 10 times their normal plasma concentration). Alpha-adrenergic stimulation provoked a decrease in glutathione (GSH) synthesis. This effect was accompanied by an enhanced efflux of glutathione from the cells. Phenylephrine stimulated the rate of glutathione disulfide (GSSG) formation; however, this effect was clearly insufficient to explain the disappearance of GSH. Our results suggest that the decrease in cellular GSH levels observed under conditions of shock, stress, or peripheral inflammation can be explained by a dual effect, i.e., an increase in glutathione efflux and an inhibition of its synthesis.

Identification of a common chemical signal regulating the induction of enzymes that protect against chemical carcinogenesis

Carcinogenesis is blocked by an extraordinary variety of agents belonging to many different classes--e.g., phenolic antioxidants, azo dyes, polycyclic aromatics, flavonoids, coumarins, cinnamates, indoles, isothiocyanates, 1,2-dithiol-3-thiones, and thiocarbamates. The only known common property of these anticarcinogens is their ability to elevate in animal cells the activities of enzymes that inactivate the reactive electrophilic forms of carcinogens. Structure-activity studies on the induction of quinone reductase [NAD(P)H:(quinone-acceptor) oxidoreductase, EC 1.6.99.2] and glutathione S-transferases have revealed that many anti-carcinogenic enzyme inducers contain a distinctive and hitherto unrecognized chemical feature (or acquire this feature after metabolism) that regulates the synthesis of these protective enzymes. The inducers are Michael reaction acceptors characterized by olefinic (or acetylenic) bonds that are rendered electrophilic (positively charged) by conjugation with electron-withdrawing substrates. The potency of inducers parallels their efficiency in Michael reactions. Many inducers are also substrates for glutathione S-transferases, which is further evidence for their electrophilicity. These generalizations have not only provided mechanistic insight into the perplexing question of how such seemingly unrelated anticarcinogens induce chemoprotective enzymes, but also have led to the prediction of the structures of inducers with potential chemoprotective activity.

Oxidative cell injury in the killing of cultured hepatocytes by allyl alcohol

The killing of cultured hepatocytes by allyl alcohol depended on the metabolism of this hepatotoxin by alcohol dehydrogenase to the reactive electrophile, acrolein. An inhibitor of alcohol dehydrogenase, pyrazole, prevented both the toxicity of allyl alcohol and the rapid depletion of GSH. Treatment of the hepatocytes with a ferric iron chelator, deferoxamine, or an antioxidant, N,N'-diphenyl-p-phenylenediamine (DPPD), prevented the cell killing but not the metabolism of allyl alcohol and the resulting depletion of GSH. Inhibition of glutathione reductase by 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU) sensitized the hepatocytes to allyl alcohol, an effect that was not attributable to the reduction in GSH with BCNU. The cell killing with allyl alcohol was preceded by the peroxidation of cellular lipids as evidence by an accumulation of malondialdehyde in the cultures. Deferoxamine and DPPD prevented the lipid peroxidation in parallel with their protection from the cell killing. These data indicate that acrolein produces an abrupt depletion of GSH that is followed by lipid peroxidation and cell death. Such oxidative cell injury is suggested to result from the inability to detoxify endogenous hydrogen peroxide and the ensuing iron-dependent formation of a potent oxidizing species. Oxidative cell injury more consistently accounts for the hepatotoxicity of allyl alcohol than does the covalent binding of acrolein to cellular macromolecules.

Role of cutaneous GSH in 12-O-tetradecanoyl-phorbol 13-acetate-induced mouse skin tumor promotion

The role of glutathione (GSH) in skin tumor promotion was ascertained in the present study by investigating the effect of the GSH depletor, diethyl-maleate (DEM), on the tumor-promoting ability of TPA in DMBA-initiated mouse skin. DEM lowered the tumor yield and the tumor incidence by 80% (p less than 0.001) in the DMBA + TPA treated group. The rate of tumor formation was also found to be influenced by DEM. The results suggest that clonal expansion of tumor-initiated cells, stimulated by TPA, depends upon the availability of reduced GSH in the tissue. The mechanism by which depletion of reduced GSH could result in inhibition of skin tumor promotion is not known. However, inactivation of GSH and thus blockage of the physiological function of reduced GSH in the biochemical events obligatory to tumor-cell proliferation in mouse skin could be the possible mechanisms providing effective control over proliferation of tumor cells.

Impairment of bromosulfophthalein hepatic transport and cholestasis induced by diethyl maleate in the rabbit

The present study was designed to investigate the effect of hepatic glutathione depletion induced by intraperitoneal administration of diethyl maleate (DEM) on the maximum biliary transport (Tm) and on the biliary excretion of bromosulfophthalein (BSP) in anaesthetized rabbits when the dye was perfused endovenously at doses exceeding Tm. The Tm of total BSP (BSPt) and that of conjugated BSP (BSPc) were significantly reduced after DEM administration whereas that of unconjugated BSP (BSPu) was markedly increased. A reduction in the biliary excretion of BSPt and BSPc, in the percentage of BSPc, in the cumulative excretion of BSPt and in the percent-dose recovery were also observed. However, no change in hepatic glutathione S-transferase activity was noted after DEM. The cholestasis observed following DEM administration coursed with falls in the biliary secretion of sodium, chloride and bicarbonate.

Glutathione depleting agents and lipid peroxidation

The mechanisms by which glutathione (GSH) depleting agents produce cellular injury, particularly liver cell injury have been reviewed. Among the model molecules most thoroughly investigated are bromobenzene and acetaminophen. The metabolism of these compounds leads to the formation of electrophilic reactants that easily conjugate with GSH. After substantial depletion of GSH, covalent binding of reactive metabolites to cellular macromolecules occurs. When the hepatic GSH depletion reaches a threshold level, lipid peroxidation develops and severe cellular damage is produced. According to experimental evidence, the cell death seems to be more strictly related to lipid peroxidation rather than to covalent binding. Loss of protein sulfhydryl groups may be an important factor in the disturbance of calcium homeostasis which, according to several authors, leads to irreversible cell injury. In the bromobenzene-induced liver injury loss of protein thiols as well as impairment of mitochondrial and microsomal Ca2+ sequestration activities are related to lipid peroxidation. However, some redox active compounds such as menadione and t-butylhydroperoxide produce direct oxidation of protein thiols.

Glutathione metabolism under the influence of hydroperoxides in the lactating mammary gland of the rat. Effect of glucose and extracellular ATP

Tert-butyl hydroperoxide decreases GSH and total free glutathione (GSH + 2GSSG) contents of acini from lactating mammary glands. The decrease in total free glutathione can be explained by an increase in mixed disulfide formation and by excretion of GSSG to the extracellular medium, and subsequent degradation catalyzed by gamma-glutamyl transpeptidase. Low concentrations of glucose prevented the changes in glutathione levels induced by the peroxide. In the presence of extracellular ATP, glucose did not prevent these changes. However, incubations with the peroxide, did not alter the rate of other metabolic pathways by acini.

Glutathione content and GSH S-transferase activity in midgut gland of Procambarus clarkii. Sex differences, the effect of fasting, and their implications in cadmium toxicity

1. Glutathione content and GSH S-transferase activity in the midgut gland of Procambarus clarkii (P. c.) of different sex and body weight are presented. 2. Procambarus clarkii females' GSH concentration in the midgut gland decreases to a higher extent upon fasting, compared with males. 3. Procambarus clarkii females, both in control and fasting conditions, have a slightly higher GSH S-transferase activity than males. 4. Cadmium present in water only affects GSH content and GSH S-transferase activity (after 96 hr) in midgut gland, with cadmium chloride concentrations higher than 100 micrograms/l.

Pharmacokinetic aspects of sulfobromophthalein transport after diethyl maleate pretreatment in rats

The pharmacokinetics of sulfobromophthalein was studied in the rat after depletion of hepatic glutathione levels induced by intraperitoneal administration of diethyl maleate (4.0 mmol/kg). After an intravenous bolus injection of sulphobromophthalein (120 mumol/kg) a biexponential plasma decay was found both in control and diethyl maleate pretreated rats. The initial plasma clearance Cl12 was not modified by diethyl maleate administration. The rate constant of biliary excretion K23 was significantly lowered in diethyl maleate pretreated rats, which could by explained by the change in the biliary excretory process. The cumulative biliary excretion of sulphobromophthalein was decreased by about 50% following diethyl maleate injection, with a reduction of the percentage of conjugated dye excreted into bile.

Glutathione conjugation of chlorobenzylidene malononitriles in vitro and the biotransformation to mercapturic acids in rats

The glutathione conjugation of 2-chloro-, 3-chloro-, 4-chloro- and 2,6-dichlorobenzylidene malononitrile (chloroBMNs) was investigated in vitro. In incubation mixtures containing rat liver cytosol (9000 g), the decrease in the initial amount of glutathione due to the various chloroBMNs ranged from 40 to 60% and occurred both enzymatically and spontaneously at physiological conditions (37 degrees C, pH 7.4). 2,6-DichloroBMN, however, depleted glutathione largely spontaneously (38 +/- 3%). The steric hindrance of the two chlorosubstituents probably plays an important role during the glutathione-S-transferase catalyzed reaction. The hydrolysis of the chloroBMNs to the corresponding chlorobenzaldehydes and malononitrile was studied in a mixture of buffer pH 7.4 and ethanol. The rate of hydrolysis of 2,6-dichloroBMN was slower than those of the related chloroBMNs. This means that 2,6-dichloroBMN will be the most stable compound in the presence of water. Only IP administration of 2-chloroBMN (CS) to adult male Wistar rats gave enhancement of urinary thioether excretion. A thioether could be isolated and was identified as the N-acetyl-S-[2-chlorobenzyl]-L-cysteine. The quantity of this benzylmercapturic acid in the urine of rats amounted to 4.4% dose (0.07 mmol/kg, n = 12). After IP administration of 2-chloro- and 3-chlorobenzaldehyde to rats benzylmercapturic acid excretion in the urine was found to be 7.6 and 1.1% of the dose, respectively. Administration of the related 4-chloro- and 2,6-dichlorobenzaldehyde, however, resulted in no urinary mercapturic acid excretion.(ABSTRACT TRUNCATED AT 250 WORDS)

Changes in biliary secretion and lactate metabolism induced by diethyl maleate in rabbits

Diethyl maleate is a compound which binds with glutathione by means of a glutathione S-transferase and is excreted into bile leading to a rapid depletion of hepatic glutathione. In the rabbit, the activity of the enzyme is fairly low and we were thus prompted to study the possible effects of diethyl maleate on biliary secretion and metabolic status in this species. The administration of diethyl maleate induced a transient choleresis followed by cholestasis. The choleresis coursed with increases in the biliary output of sodium and unaccounted anions, whereas those of chloride, bicarbonate and bile acids were unaffected. Our data seem to confirm that choleresis is due to the osmotic activity of diethyl maleate compounds excreted into bile, as has been reported in rats and dogs. The cholestasis observed coursed with falls in the outputs of sodium, chloride and bicarbonate though that of bile acids remained constant. Following diethyl maleate administration, a metabolic acidosis appeared with progressive increases of blood lactate concentration. In bile the concentration of this anion closely followed that of plasma. The cholestasis is attributed to a lowered biliary secretion of bicarbonate probably secondary to the metabolic alteration. The hepatic values of cytoplasmatic and mitochondrial NADH/NAD ratios and of adenine nucleotide concentrations suggest that the increase in blood lactate results rather from a fall in its hepatic utilization that from an increase in its production.

Toxicity of ozone and nitrogen dioxide to alveolar macrophages: comparative study revealing differences in their mechanism of toxic action

The toxicity of ozone and nitrogen dioxide is generally ascribed to their oxidative potential. In this study their toxic mechanism of action was compared using an intact cell model. Rat alveolar macrophages were exposed by means of gas diffusion through a Teflon film. In this in vitro system, ozone appeared to be 10 times more toxic than nitrogen dioxide. alpha-Tocopherol protected equally well against ozone and nitrogen dioxide. It was demonstrated that alpha-tocopherol provided its protection by its action as a radical scavenger and not by its stabilizing structural membrane effect, as (1) concentrations of alpha-tocopherol that already provided optimal protection against ozone and nitrogen dioxide did not influence the membrane fluidity of alveolar macrophages and (2) neither one of the structural alpha-tocopherol analogs tested (phytol and the methyl ether of alpha-tocopherol) could provide a protection against ozone or nitrogen dioxide comparable to the one provided by alpha-tocopherol. It was concluded that reactive intermediates scavenged by alpha-tocopherol are important in the toxic mechanism of both ozone and nitrogen dioxide induced cell damage. However, further results presented strongly confirmed that the kind of radicals and/or reactive intermediates, and thus the toxic reaction mechanism involved, must be different in ozone- and nitrogen dioxide-induced cell damage. This was concluded from the observations that showed that (1) vitamin C provided significantly better protection against nitrogen dioxide than against an equally toxic dose of ozone, (2) glutathione depletion affected the cellular sensitivity toward ozone to a significantly greater extent than the sensitivity towards nitrogen dioxide, and (3) the scavenging action of alpha-tocopherol was accompanied by a significantly greater reduction in its cellular level during nitrogen dioxide exposure than during exposure to ozone. One of the possibilities compatible with the results presented in this study might be that lipid (peroxyl) free radicals formed in a radical-mediated peroxidative pathway, resulting in a substantial breakdown of cellular alpha-tocopherol, are involved in nitrogen dioxide-induced cell damage, and that lipid ozonides, scavenged by alpha-tocopherol as well, are involved in ozone-induced cell damage.

On the mechanisms of glutathione depletion in hepatocytes exposed to morphine and ethylmorphine

Incubation of isolated rat hepatocytes with either morphine or ethylmorphine resulted in glutathione (GSH) depletion followed by loss of cell viability. Pretreatment of cells with 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU) to inactivate glutathione reductase did not markedly affect the rates of GSH depletion seen in untreated cells. In contrast, hexobarbital stimulated H2O2 production in isolated liver microsomes, incubated aerobically with NADPH, whereas the effects of morphine and ethylmorphine on microsomal H2O2 production were minimal. Finally, incubation of hepatocytes with radioactively labeled morphine resulted in formation of 2 glutathione conjugates, one of which was tentatively identified as formyl glutathione. We conclude that GSH consumption during the metabolism of morphine or ethylmorphine by hepatocytes is due mainly to formation of glutathione conjugates.

Effect of diethylmaleate and other glutathione depletors on protein synthesis

The alpha, beta-unsaturated carbonyl compound diethylmaleate (DEM) depletes glutathione (GSH) from liver and other tissues, and for this reason it is often used in toxicological research to study the GSH-mediated metabolism of xenobiotics. In addition to GSH depletion, however, DEM has been shown to have other nonspecific effects, such as alteration of monooxygenase activities or glycogen metabolism. In this study we found that DEM (1 ml/kg) inhibited protein synthesis in brain and liver, following in vivo administration to mice. Protein synthesis was measured as the incorporation of [3H]valine into trichloroacetic acid-precipitable material. Administration of DEM also decreased body temperature by 2-3 degrees. By increasing the environmental temperature from 22 degrees to 35 degrees the hypothermic effect of DEM was prevented, without affecting its ability to deplete GSH from brain and liver. Furthermore, when mice were maintained at 35 degrees, DEM still caused a significant decrease in protein synthesis, suggesting that this effect was only partially due to hypothermia. To test whether inhibition of protein synthesis was related to GSH depletion, groups of animals were dosed with the alpha, beta-unsaturated carbonyl phorone (diisopropylidenacetone) or the specific inhibitor of GSH synthesis, buthionine sulfoximine (BSO). Phorone decreased GSH in liver and brain; however, it had no effect on protein synthesis. BSO decreased GSH levels in liver and kidney, but not in brain, and did not have any effect on protein synthesis in any of these tissues, nor did it cause any hypothermia. Furthermore, when hepatic GSH content was decreased by in vivo administration of DEM or BSO, there was no inhibition of protein synthesis measured in vitro. These results indicate that, at the dose normally used to deplete GSH from various tissues. DEM also exerts an inhibitory effect on protein synthesis, which appears to be only partially due to its hypothermic effect, and is independent from GSH depletion. BSO, which, in our experimental conditions, lacks this and other nonspecific effects, might be a good alternative for studies aimed at characterizing the role of GSH in the metabolism and toxicity of chemicals.

Lipid peroxidation and cellular damage in extrahepatic tissues of bromobenzene-intoxicated mice

The mechanisms of bromobenzene toxicity in extrahepatic tissues of mice were studied. Kidney, lung, heart and brain were examined. As observed in this as well as in a previous report for the liver, bromobenzene intoxication caused a progressive decrease in the glutathione content of all the tissues examined. Cellular damage (as assessed by both biochemical determinations and histologic observations) appeared after 6 hours in the case of the kidney and the heart and after 15 hours in the case of the lung. Lipid peroxidation (as assessed by the tissue content of malonic dialdehyde, a parameter correlating with both the diene conjugation absorption and the amount of carbonyl functions in cellular phospholipids) was found to occur at the same times at which cellular damage was observed or even before. As in the case of bromobenzene-induced liver injury, when the individual values for cell damage obtained at 15-20 hours were plotted against the corresponding glutathione contents, a severe cellular damage was generally observed when the glutathione levels reached a threshold value (3.0-0.5 nmol/mg protein). Such a glutathione threshold was also observed for the onset of lipid peroxidation. Glutathione depletion and lipid peroxidation are therefore general phenomena occurring not only in the liver but in all the tissues as a consequence of bromobenzene poisoning. The possibility that lipid peroxidation is the cause of bromobenzene-induced damage to liver and extrahepatic tissues is discussed.

The role of mitochondrial glutathione and cellular protein sulfhydryls in formaldehyde toxicity in glutathione-depleted rat hepatocytes

Depletion of cellular GSH by diethyl maleate (DEM) potentiates CH2O toxicity in isolated rat hepatocytes and it was postulated that this increase in toxicity is due to the further decrease in GSH caused by CH2O in DEM-pretreated hepatocytes (1). The present investigation was conducted to investigate further the effects of CH2O, DEM, and acrolein (a compound which is structurally related to CH2O and DEM) on subcellular GSH pools and on protein sulfhydryl groups (PSH). CH2O caused a decrease in cytosolic GSH but had no effect on mitochondrial GSH either in previously untreated hepatocytes or in DEM-pretreated hepatocytes in which GSH was approximately 25% of control. DEM decreased both cytosolic and mitochondrial GSH but it did not produce toxicity. Neither CH2O (up to 7.5 mM) nor DEM (20 mM) decreased PSH. However, in cells pretreated with 1 mM DEM, CH2O (7.5 mM) decreased PSH and this effect preceded cell death. Acrolein decreased both cytosolic and mitochondrial GSH and it also decreased PSH significantly prior to causing cell death. CH2O and acrolein stimulated phosphorylase alpha activity, indicative of an increase in cytosolic free Ca2+, by a PSH-independent and PSH-dependent mechanism, respectively. These results suggest that the further depletion of cellular GSH by CH2O in DEM-pretreated cells is not due to the depletion of mitochondrial GSH. CH2O toxicity in DEM-pretreated cells is, however, correlated with depletion of PSH. The critical sulfhydryl protein(s) responsible for cell death remain to be more clearly defined.

A comparison of the heat and radiation sensitivity of rodent and human derived cells cultured in vitro

A human lung and breast carcinoma cell line of epithelial origin (A-549 and MCF-7) were compared with a rodent fibroblast line (V-79) for their sensitivity to killing by X rays and heat, in addition, a correlation was sought between loss of endogenous thiols and thermosensitivity. Endogenous cellular thiols play a major role in many protective, enzymatic and synthetic processes in mammalian cells. Glutathione, a key non-protein thiol, not only protects against radiation and peroxide-induced damage, but is also a primary intracellular reductant. Thiol depletion was achieved using two agents that work by totally different mechanisms--one a substrate for glutathione-S-transferase (Diethylmaleate) and the other an inhibitor of a key enzyme in the gamma-glutamyl cycle (Buthionine-SR-Sulfoximine). The results of this study demonstrated that thiol depletion by DEM to 50% of the control values had no effect on the response of hamster cells to acute (45 degrees C) or chronic (42.5 degrees C) hyperthermia. Substantial potentiation of heat damage, however, was seen at thiol levels below 10% at 42.5 degrees C. Thiol depletion by BSO to levels of 25% of the control values had no sensitizing effect on the heat sensitivity of hamster or human lung carcinoma cells at 45 degrees C. For any given heat exposure, the human cells were markedly more resistant to killing than the hamster cells, however, they were more radiosensitive than the V79, line when exposed to 300 kVp X rays (D0's of 1.65 vs. 2.52 Gy). The results of this study indicate that thiols do not play a critical role in mammalian cell thermosensitivity at 45 degrees C and indicate that the use of human carcinoma cell lines may better predict heat inactivation in human cells in vivo.

Evidence that glutathione participates in the induction of a stress protein

A step in the induction of a 30- to 35-kD stress protein may be the reaction of chemical inducers with glutathione. Effective inducers are sulfhydryl reagents. Further, a comparison of three reagents, 1-chloro-2,4-dinitrobenzene, diethylmaleate, and N-ethylmaleimide, indicates that the first two, which have considerable selectivity for glutathione, are strong inducers of the stress protein but the third, which is much more reactive with protein sulfhydryls, is either a poor or ineffective inducer. A decrease in cellular glutathione does not appear to be inductive, however. An increase in modified glutathione remains as a possible signal for the induction of this stress protein.

Effects of oxidative stress caused by hyperoxia and diquat. A study in isolated hepatocytes

The effects of oxidative stress caused by hyperoxia or administration of the redox active compound diquat were studied in isolated hepatocytes, and the relative contribution of lipid peroxidation, glutathione (GSH) depletion, and NADPH oxidation to the cytotoxicity of active oxygen species was investigated. The redox cycling of diquat occurred primarily in the microsomal fraction since diquat was found not to penetrate into the mitochondria. Depletion of intracellular GSH by pretreatment of the animals with diethyl maleate promoted lipid peroxidation and sensitized the cells to oxidative stress. Diquat toxicity was also greatly enhanced when glutathione reductase was inhibited by pretreatment of the cells with 1,3-bis(2-chloroethyl)-1-nitrosourea. Despite extensive lipid peroxidation, loss of cell viability was not observed, with either hyperoxia or diquat, until the GSH level had fallen below approximately 6 nmol/10(6) cells. The iron chelator desferrioxamine provided complete protection against both diquat-induced lipid peroxidation and loss of cell viability. In contrast, the antioxidant alpha-tocopherol inhibited lipid peroxidation but provided only partial protection from toxicity. The hydroxyl radical scavenger alpha-keto-gamma-methiol butyric acid, finally, also provided partial protection against diquat toxicity but had no effect on lipid peroxidation. The results indicate that there is a critical GSH level above which cell death due to oxidative stress is not observed. As long as the glutathione peroxidase - glutathione reductase system is unaffected, even relatively low amounts of GSH can protect the cells by supporting glutathione peroxidase-mediated metabolism of H2O2 and lipid hydroperoxides.

Effects of glutathione depletion on gluconeogenesis in isolated hepatocytes

Glutathione-depleted hepatocytes, by incubation with diethylmaleate (DEM) or phorone (2,6-dimethyl-2,5-heptadiene-4-one), i.e., substrates of the GSH S-transferases (EC 2.5.1.18), showed rates of gluconeogenesis from various precursors significantly lower than controls; however the rate of glucose synthesis from fructose was similar to that of controls. Isolated hepatocytes from rats pretreated with those substrates 1 h before isolation to deplete hepatic glutathione (GSH) also showed a decrease of the rate of gluconeogenesis from lactate plus pyruvate. Incubation of hepatocytes with L-buthionine sulfoximine, a specific inhibitor of gamma-glutamyl-cysteine synthetase (EC 6.3.2.2), resulted in a decreased rate of gluconeogenesis from lactate plus pyruvate only when GSH values were lower than 1 mumol/g cells. Freeze-clamped livers from GSH-depleted rats showed a higher concentration of malate and glycerol 3-phosphate, indicating that GSH depletion probably affects phosphoenolpyruvate carboxykinase and glycerol-3-phosphate dehydrogenase activities. Several indicators of cell viability, such as lactate dehydrogenase leakage, malondialdehyde accumulation, ATP concentration, or urea synthesis from different precursors, were not affected by GSH depletion under the experimental conditions used here. Besides, the GSH/GSSG ratio remained unchanged in all cases.

The role of glutathione and changes in thiol homeostasis in cultured lung cells exposed to ozone

Cells of an alveolar type II cell-line (A549) were exposed to ozone, using an in vitro exposure model. In this study, attention was focused on the cellular glutathione system. It was demonstrated that cellular levels of both reduced (GSH) and oxidized glutathione (GSSG) were significantly reduced after exposure of the cells to ozone. When A549 cells were incubated with methionine sulfoximine and diethylmaleate, glutathione levels were depleted, and the cells showed a marked increase in sensitivity towards ozone. Some of the possible mechanisms by which the observed effects might be explained were investigated. It was shown that glutathione lost from the cells was not incorporated into "mixed disulfides", but could be detected in the surrounding medium. Furthermore, it was shown that A549 cells do not contain any detectable glutathione peroxidase activity. Therefore it was concluded that glutathione peroxidase-catalysed reduction of lipid peroxides could not be responsible for the observed protective role of glutathione. Finally some other mechanisms by which glutathione might accomplish its antioxidant effect are discussed.

Covalent binding and glutathione depletion in the rat following niridazole (ambilhar) pretreatment

In vivo and in vitro studies with rats have shown that (14C) niridazole (Ambilhar) binds covalently to tissue proteins, but not to nucleic acids. In the in vitro experiments, binding required the presence of NADPH in the incubation medium, suggesting the production of an active metabolite via a cytochrome P-450-mediated reaction. Niridazole also caused significant dose-dependent decreases in liver and kidney glutathione levels, even though it had no apparent effect on blood glutathione. Alteration of tissue glutathione availability by pretreatment with chloracetamide or cysteine respectively either increased or decreased the NADPH-dependent covalent binding. Pretreatment with phenobarbital, 3-methylcholanthrene or cobaltous chloride, which change the rate of metabolism of (14C) niridazole, similarly altered the extent of protein binding. It is shown that the decrease in tissue glutathione concentration is not due to an effect of the drug on the activities of either glucose-6-phosphate dehydrogenase or glutathione-S-transferases. However, there is a significant reduction in glutathione reductase activity in all the tissues studied. The possible relationships between the results obtained and the cytotoxic effects of niridazole have been discussed.

Studies on mechanisms of ornithine decarboxylase activity regulation in regenerating liver

Rat liver (hydrocortisone-induced) ornithine decarboxylase has been shown to be stable when the cytosolic fraction is incubated alone at 37 degrees C, although there is a very rapid and drastic loss of activity after addition of microsomes to the incubation medium. The present paper is concerned with the behaviour of ornithine decarboxylase induced in rat liver by a growth stimulus (partial hepatectomy); comparative studies have been carried out on the enzyme induced by sham operation, or by hydrocortisone. Results show that ornithine decarboxylase from regenerating liver is more stable when incubated with microsomes (from the same source); this higher stability depends both on a lower microsome-bound inactivating capacity and a limited susceptibility of the enzyme to the inactivation. A critical role in modulating the microsome-dependent inactivation appears to be played by low molecular weight cytosolic factors, whose greater content in regenerating liver is likely to be included with the factors above in determining the relative stability of ornithine decarboxylase.

Liver glutathione depletion induced by bromobenzene, iodobenzene, and diethylmaleate poisoning and its relation to lipid peroxidation and necrosis

The mechanisms of bromobenzene and iodobenzene hepatotoxicity in vivo were studied in mice. Both the intoxications caused a progressive decrease in hepatic glutathione content. In both instances liver necrosis was evident only when the hepatic glutathione depletion reached a threshold value (3.5-2.5 nmol/mg protein). The same threshold value was evident for the occurrence of lipid peroxidation. Similar results were obtained in a group of mice sacrificed 15-20 hours after the administration of diethylmaleate, a drug which is mainly conjugated with hepatic glutathione without previous metabolism. The correlation between lipid peroxidation and liver necrosis was much more significant than that between covalent binding and liver necrosis. This fact supports the view that lipid peroxidation is the major candidate for the liver cell death produced by bromobenzene intoxication. Moreover, a dissociation of liver necrosis from covalent binding was observed in experiments in which Trolox C (a lower homolog of vitamin E) was administered after bromobenzene poisoning. The treatment with Trolox C, in fact, almost completely prevented both liver necrosis and lipid peroxidation, while not changing at all the extent of the covalent binding of bromobenzene metabolites to liver protein.

Glutathione status in primary cultures of rat hepatocytes and its role in cell attachment to collagen

In primary cultures of rat hepatocytes the intracellular level of reduced glutathione (GSH) declines to approx. 50% of that observed in freshly isolated cells within 1 h of culture. Pretreatment of freshly isolated hepatocytes with diethylmaleate (DEM) to deplete GSH and inhibition of glutathione synthesis by buthionine sulfoximine (BSO) markedly decrease the proportion of cells attaching to the collagen coated culture dishes. A positive correlation between the intracellular content of GSH and the ability of hepatocytes to attach to collagen is observed. Presence of dithiothreitol (DTT) in the culture medium efficiently prevents hepatocyte attachment. A net increase in hepatocyte disulfides is also observed after the first hours of culture. The formation of disulfides seems to be essential for the attachment of hepatocytes to collagen. The depletion of GSH in the early period of culture is probably due to its regulatory function of thiol/disulfide groups in proteins and/or its involvement in the synthesis of essential cytoskeletal proteins.

Alterations in intracellular thiol homeostasis during the metabolism of menadione by isolated rat hepatocytes

The effects of menadione (2-methyl-1,4-naphthoquinone) metabolism on intracellular soluble and protein-bound thiols were investigated in freshly isolated rat hepatocytes. Menadione was found to cause a dose-dependent decrease in intracellular glutathione (GSH) level by three different mechanisms: (a) Oxidation of GSH to glutathione disulfide (GSSG) accounted for 75% of the total GSH loss; (b) About 15% of the cellular GSH reacted directly with menadione to produce a GSH-menadione conjugate which, once formed, was excreted by the cells into the medium; (c) A small amount of GSH (approximately 10%) was recovered by reductive treatment of cell protein with NaBH4, indicating that GSH-protein mixed disulfides were also formed as a result of menadione metabolism. Incubation of hepatocytes with high concentrations of menadione (greater than 200 microM) also induced a marked decrease in protein sulfhydryl groups; this was due to arylation as well as oxidation. Binding of menadione represented, however, a relatively small fraction of the total loss of cellular sulfhydryl groups, since it was possible to recover about 80% of the protein thiols by reductive treatments which did not affect protein binding. This suggests that the loss of protein sulfhydryl groups, like that of GSH, was mainly a result of oxidative processes occurring within the cell during the metabolism of menadione.

The occurrence, metabolism and toxicity of cinnamic acid and related compounds

Cinnamic acid is a compound of low toxicity, but its molecular structure and the known toxicity of similar molecules, such as styrene, have brought it to the toxicologist's attention. Commercially, its use is permitted as flavouring and it is ubiquitous in products containing cinnamon oil and to a lesser extent in all plants. The related aldehyde, alcohol and esters are all more toxic than cinnamic acid. Certain substituted cinnamates containing cyano and fluoro moieties are of particular interest because they inhibit mitochondrial pyruvate transport. The literature about this whole group of commercially important compounds is diverse and many key studies are in languages other than English. This review looks at the history and legal constraints, as well as the results of metabolism and toxicology studies.