Relation between glutathione and cytoplasmic protein sulfhydryl groups in the rat: a rapid procedure for analytical determination

A simple rapid determination of glutathione (GSH) and cytoplasmic protein bound SH groups (PBSH), appropriate to study their relationship in tissues, in rat liver, kidney and testis was developed. Hepatic GSH and PBSH were measured after treatment with methyl iodide (400, 800 mg/kg, after 0.5 h), diethyl maleate (2 ml/kg, after 1h), carbon tetrachloride (1.2 ml/kg, after 3 h), phenobarbital (80 mg/kg for 3 days). Methyl iodide and diethyl maleate showed a decrease of GSH and PBSH; after treatment with phenobarbital an increase of GSH and PBSH was observed; no decrease of GSH and PBSH was found after carbon tetrachloride intoxication.     

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.     

Indomethacin attenuation of hepatic perfusion and plasma 6-ketoPGF1 alpha elevations following glutathione depletion in rabbits

Glutathione (GSH) is important in detoxification and regulating cyclooxygenase activity. Since the liver has high levels of GSH, xenobiotic-induced changes in hepatic GSH could affect hepatic tissue blood perfusion (HP) via alterations in prostaglandin synthesis. In anesthetized male New Zealand rabbits, elevating GSH with GSH monoethyl ester had no affect on HP. Treatment of rabbits with diethyl maleate to deplete GSH also had no affect on HP in animals previously given GSH monoethyl ester. However, HP increased within 20 min in rabbits treated with diethyl maleate prior to GSH monoethyl ester. In another experiment, a similar rise in HP following GSH depletion was accompanied by arterial plasma 6-ketoPGF1 alpha (the stable metabolite of prostacyclin) levels that were 4-times higher than in the controls. Plasma TxB2 (the stable metabolite of thromboxane) also increased following diethyl maleate, but only to levels that were 25-times lower than for 6-ketoPGF1 alpha. Since indomethacin blocked the rise in HP, as well as the increases in 6-ketoPGF1 alpha and TxB2, these results indicate changes in HP may occur following GSH depletion as a result of increased synthesis of one or more arachidonic acid metabolites and implicate prostacyclin as a possible mediator of this phenomenon.     

Differential lipid peroxidative response of rat liver and lung tissues to glutathione depletion induced in vivo by diethyl maleate: effect of the antioxidant flavonoid (+)-cyanidanol-3

The administration of a single dose of diethyl maleate (DEM) to fed rats elicited a drastic decrease in the content of reduced glutathione (GSH) both in liver and lung tissues after 6 h of treatment. Cellular GSH depletion induced by DEM was accompanied by a marked increase in pulmonary lipid peroxidation which was completely abolished by (+)-cyanidanol-3, without changes in the liver. Superoxide dismutase (SOD) activity remained unchanged in both tissues in this situation. Hepatic and pulmonary GSH depletion induced by a second dose of DEM given 24 h later produced a further increase in lung lipid peroxidation and a diminution of pulmonary SOD activity. In this condition, hepatic lipid peroxidation and SOD activity were not altered. These results indicate that lung and liver tissues exhibit a different lipid peroxidative response to chemically-induced GSH depletion.     

Relationships between formaldehyde metabolism and toxicity and glutathione concentrations in isolated rat hepatocytes

The metabolism and toxicity of formaldehyde (CH2O) in isolated rat hepatocytes was found to be dependent upon the intracellular concentration of glutathione (GSH). Using hepatocytes depleted of GSH by treatment with diethyl maleate (DEM), the rate of CH2O (5.0 mM) disappearance was significantly decreased. Formaldehyde decreased the concentration of GSH in hepatocytes, probably by the extrusion of the CH2O-GSH adduct, S-hydroxymethylglutathione. Formaldehyde toxicity was potentiated in cells pretreated with 1.0 mM DEM as measured by the loss of membrane integrity (NADH stimulation of lactate dehydrogenase (LDH) activity) and an increase in lipid peroxidation (formation of thiobarbituric acid-reactive compounds). This potentiation of toxicity was both CH2O concentration-dependent and time-dependent. There was an excellent correlation between the increase in lipid peroxidation and the decrease in cell viability. L-Methionine (1.0 mM) both protected the cells from toxicity caused by the combination of 8.0 mM CH2O and 1.0 mM DEM and increased the cellular GSH concentration. The antioxidants, ascorbate, butylated hydroxytoluene (BHT) and alpha-tocopherol (10, 25 and 125 microM), all exhibited dose-dependent protection against toxicity produced by 8.0 mM CH2O and 1.0 mM DEM. At toxic concentrations of CH2O (10.0-13.0 mM), administered by itself, lipid peroxidation did not increase concomitantly with the decrease in cell viability and the addition of antioxidants (125 microM) did not influence CH2O toxicity. These results suggest that CH2O toxicity in GSH-depleted hepatocytes may be mediated by free radicals as a result of the effect of CH2O on a critical cellular pool of GSH. However, cells with normal concentrations of GSH are damaged by CH2O by a different mechanism.     

Potential Role of Cerebral Glutathione in the Maintenance of Blood-Brain Barrier Integrity in Rat

Using the model of glutathione (GSH) depletion, possible role of GSH in the maintenance of blood-brain barrier (BBB) integrity was evaluated in rats. Administration (ip) of GSH depletors, diethyl maleate (DEM, 1–4 mmol/kg), phorone (2–3 mmol/kg) and 2-cyclohexene-1-one (CHX, 1 mmol/kg), to male adults was found to deplete brain and liver GSH and increase the BBB permeability to micromolecular tracers (sodium fluorescein and [¹⁴C]sucrose) in a dose-dependent manner at 2h. However, BBB permeability to macromolecular tracers such as horseradish peroxidase and Evan's blue remained unaltered. It was also shown that observed BBB permeability dysfunction was associated with brain GSH depletion. A lower magnitude of BBB increase in rat neonates, as compared to adults, indicated a possible bigger role of GSH in the BBB function of mature brain. The treatment with N-acetylcysteine, methionine and GSH provided a partial to full protection against DEM-induced brain (microvessel) GSH depletion and BBB dysfunction; however, the treatment with -tocopherol, ascorbic acid and turmeric were not effective. Our studies showed that cerebral GSH plays an important role in maintaining the functional BBB integrity.     

Glutathione and glutathione S-transferases in the salmonella mammalian-microsome mutagenicity test

Levels of the tripeptide glutathione (GSH) and the activity of glutathione S-transferases were investigated in S9 fractions of rats and mice and in Salmonella typhymurium tester strains TA1535, TA100, TA1538 and TA98. The S9 and Salmonella typhimurium tester strains had high levels of glutathione. Compared with S9, the activity of GSH S-transferases was lower in the bacteria. However, electrophiles such as 1-chloro-2,4-dinitrobenzene (CDNB), diethyl maleate and styrene oxide were effectively bound to bacterial GSH.

The mutagenicity of the direct mutagen CDNB was drastically lowered in presence of S9 fractions but not in presence of microsomes. A comparable decrease was obtained when microsomal supernatant, which contains GSH and GSH S-transferases, was added to the microsomes. Addition of GSH in excess completely abolished mutagenicity of CDNB. These results demonstrate that the conjugation of electrophiles with GSH mediated by the S9 fraction or the bacterial tester strains represents an important detoxication mechanism which may influence the results obtained with the Salmonella typhimurium mammalian-microsome mutagenicity test.     

Renal and hepatic glutathione pool modifications in response to depletion treatments

In this study we examined the response of the renal and hepatic glutathione (GSH) pool in rats to drastic GSH depletion treatments. For this purpose, we used a protein-free diet, starvation, and the injection of varying doses of diethyl maleate as depleting agents. We analysed GSH levels in both kidney and liver tissue homogenates after rats were fed a protein-free diet for 2 or 7 days or starved for 1, 2, or 3 days, as well as after diethyl maleate administration in a single maximal dose or in varying doses. The results indicated that the liver GSH pool was always more labile than the kidney GSH pool. Moreover, kidney GSH levels were almost unchanged after 7 days on a protein-free diet or after 2 days of starvation, while liver showed significant changes in GSH levels. When we analysed the repletion rate, kidney had higher kinetic parameters (k = 0.148 h-1) than liver (0.097 h-1). We conclude that efficient mechanisms of maintaining GSH levels exist in the kidney and these may serve to avoid GSH diminution and hence preserve renal function during states of GSH depletion.     

Intrabiliary glutathione hydrolysis. A source of glutamate in bile

High concentrations of glutathione (GSH) and two of its constituent amino acids, glutamate and glycine, are normally found in rat bile. To examine the role of intrabiliary GSH hydrolysis as a source of these amino acids, as well as of cystine in bile, the biliary excretion of GSH and free amino acids was measured in normal male Sprague-Dawley rats; in animals given either phenol 3,6-dibromphthalein disulfonate or diethyl maleate, inhibitors of GSH secretion into bile; and after a retrograde intrabiliary infusion of (alpha S, 5S)-alpha-amino-3-chloro-4,5-dihydro-5-isoxazoleacetic acid (AT-125), an irreversible inhibitor of gamma-glutamyl transferase activity. Total concentration of amino acids in normal rat bile ranged from 4 to 7 mM and was more than double the concentration in plasma (2-3 mM). Although most amino acids were detected in bile, glutamate and glycine were the most prevalent (1.2 and 1.0 mM, respectively), followed by the branched chain amino acids valine and leucine. The administration of phenol 3,6-dibromphthalein disulfonate (180 mumol/kg, intravenous), or of diethyl maleate (1 mmol/kg, intraperitoneal), resulted in a marked decrease in the biliary excretion of GSH, as well as a decrease in the excretion of glutamate, cystine, and glycine; however, the effects of these agents were not specific for the amino acid constituents of GSH. Following retrograde intrabiliary infusion of AT-125 (10 mumol/kg), there was an immediate and sustained doubling in the rate of biliary excretion of both GSH and glutathione disulfide and a marked decrease in the rate of excretion of glutamate. Varying the dose of AT-125 (0-20 mumol/kg) resulted in an inverse linear relation between hepatic gamma-glutamyl transferase activity and the biliary excretion of intact GSH. These findings suggest that most, if not all, of the free glutamate in excreted bile is formed from the intrabiliary hydrolysis of GSH. Prior to hydrolysis within the biliary tree, substantial concentrations of GSH must be transported from liver cells into bile; minimal canalicular concentrations of this tripeptide are estimated at 5 mM.     

Induction of gamma-glutamyltransferase in cultured brain cells

gamma-Glutamyltransferase is a membrane-bound enzyme widely distributed in animal tissues. This enzyme is involved in glutathione metabolism, but its exact biological function is still an open question. In rat brain cells in culture a depletion of L-cystine and L-glutamine or the addition of diethyl maleate to the culture medium leads to a decrease of intracellular glutathione concentration and to an increase of the specific activity of gamma-glutamyltransferase. The induction of the enzyme is inhibited by the addition of cycloheximide or actinomycin D to the culture medium.     

Effect ofN-acetylcysteine administration on cysteine and glutathione contents in liver and kidney and in perfused liver of intact and diethyl maleate-treated rats

Summary Effect ofN-acetyl-l-cysteine (NAC) administration on cysteine and glutathione (GSH) contents in rat liver and kidney was studied using intact and diethyl maleate (DEM)-treated rats and perfused rat liver. Cysteine contents increased rapidly, reaching peak at 10 min after intraperitoneal NAC administration. In liver mitochondria it increased slowly, reaching peak at 60 min. GSH content did not change significantly in these tissues. However, in liver and kidney depleted of GSH with DEM, NAC administration restored GSH contents in 60 and 120 min, respectively. Perfusion with 10 mM NAC resulted in 76% increase in liver cysteine content, but not in GSH content. Liver perfusion of DEM-injected rats with 10 mM NAC restored GSH content by 15%. Present findings indicate that NAC is an effective precursor of cysteine in the intact liver and kidney and in the perfused rat liver, and that NAC stimulated GSH synthesis in GSH-depleted tissues.     

Culture duration alters the glutathione content and sensitivity to ethacrynic acid of rat hepatocyte monolayer cultures

Many of the differentiated functions of hepatocytes are lost in culture, yet addition of certain medium supplements can aid in the retention of differentiated character. Therefore, the effect of time in monolayer culture on rat hepatocyte glutathione (GSH) synthesis and sensitivity to the GSH detoxicated xenobiotic ethacrynic acid was examined in cultures with and without medium supplementation by transferrin and sodium selenite. GSH content was found to be about 12 nmol/µg DNA at 4 hr in culture and to approximately triple by 24 hr. Intracellular GSH levels continued to increase in transferrin/sodium selenite-supplemented cultures, from 32 to 41.6 nmol/µg DNA, while GSH levels in unsupplemented cultures declined to 18 nmol/µg DNA. However, the rate of GSH synthesis after diethylmaleate depletion was found to decrease from 4.2 to 2.8 nmol/hr/µg DNA at 4 and 24 hr after inoculation, respectively. GSH repletion rate increased to 3.9 nmol/hr/µg DNA at 48 hr. The GSH accumulation rate after depletion in supplemented cultures did not vary significantly over the initial 48 hr. Incubation for 3 hr with 100 µM ethacrynic acid (EA) did not elicit an increase in LDH leakage in hepatocyte monolayers after 4 or 48 hr in culture or in cultures with supplemented medium at any time point tested. Cultures 24 hr in medium without transferrin/sodium selenite supplementation exhibited significant LDH leakage after 3 hr of EA treatment. Over the 3 hr EA treatment, intracellular GSH content was decreased in all cultures. Only in the 24 hr unsupplemented cultures did GSH depletion exceed the 90% level previously associated with depletion of the mitochondrial pool of GSH and EA toxicity in hepatocytes. The experiments show that during the redifferentiation of hepatocytes in culture, a transient period occurs when apparent GSH synthesis is depressed and enhanced sensitivity to GSH-detoxicated compounds is observed. This period of increased sensitivity is prevented or at least delayed by inclusion of supplemental transferrin and sodium selenite, suggesting that redifferentiation can be regulated by extracellular influences.Abbreviations CYSSG cysteine-glutathione mixed disulfide - DEM diethyl maleate - EA ethacrynic acid - GSH reduced glutathione - GSSG oxidized glutathione - HBS HEPES buffered saline - HWME hepatocyte Williams' Medium E (WME with insulin, corticosterone and 0.5 mM methionine) - LDH lactate dehydrogenase - TS-HWME transferrin/sodium selenite-supplemented HWME - WME Williams' Medium E     

Protective effect of glucose-cysteine adduct on thein situ perfused rat liver

Summary Insitu perfusion of rat liver was performed with a medium containing glucose-cysteine adduct [2-(D-gluco-pentahydroxypentyl) thiazolidine-4-carboxylic acid, glc-cys] and its effect on glutathione (GSH) and ATP levels and bile production was examined. The GSH content in the liver was maintained at the original level during perfusion with 1 mM glc-cys for 2h, while it decreased significantly in the absence of glc-cys. After 4h of perfusion without glc-cys, ATP content and bile production decreased significantly besides the decrease in GSH content, but they were maintained at the original levels with glc-cys. When the perfusion was performed with the liver of rats injected with diethyl maleate (DEM), the GSH level, which was decreased to 6.0% of the control by DEM injection, was restored to 22.6% of the original level by perfusion with 2mM glc-cys for 30 min. Data indicate that glccys is a cysteine prodrug with protective action on the liver.     

Effect of allylisopropylacetamide on glutathione metabolism in the rat liver. The possible role of glutathione in the induction of 5-aminolaevulinate synthase

Administration of allylisopropylacetamide to rats caused a marked decline in the concentrations of reduced and oxidized glutathione in the liver. However, this decrease occurred in the presence of uninhibited activities of gamma-glutamylcysteine synthase and glutathione reductase, and unaltered activities of glutathione transferases A, B and C. The administration of cysteine, the rate-limiting precursor of glutathione formation, to rats treated with allylisopropylacetamide potentiated the inductive effects of the agent on 5-aminolaevulinate synthase, and markedly decreased the extent of decrease in glutathione concentrations by the agent. Conversely, the administration of diethyl maleate, which depletes the hepatic glutathione concentrations, to allylisopropylacetamide-pretreated rats (1h) diminished the extent of 5-aminolaevulinate synthase induction and the production of porphyrins by nearly 50%, when measured at 16h. This treatment did not alter the extent of non-enzymic degradation of liver haem by allylisopropylacetamide. When diethyl maleate was administered to the animals possessing high 5-aminolaevulinate synthase activity (at 3, 7 and 15h after allylisopropylacetamide), in 1h the enzyme activity was markedly decreased. Diethyl maleate had no effect on induction of 5-aminolaevulinate synthase by 3,5-diethoxycarbonyl-1,4-dihydrocollidine, also a potent porphyrinogenic agent. Diethyl maleate alone neither inhibited 5-aminolaevulinate synthase activity nor decreased the cellular content of porphyrins and haem. The data suggest that the decreases observed in the glutathione concentrations after allylisopropylacetamide administration are not the result of decreased production of the tripeptide. Rather, they most likely reflect the increased utilization of glutathione. The findings further suggest that the inhibition by diethyl maleate of allylisopropylacetamide-stimulated 5-aminolaevulinate synthase involves the inhibition of induction processes.     

Inhibition of the low-Km mitochondrial aldehyde dehydrogenase by diethyl maleate and phorone in vivo and in vitro. Implications for formaldehyde metabolism.

Formaldehyde can be oxidized primarily by two different enzymes, the low-Km mitochondrial aldehyde dehydrogenase and the cytosolic GSH-dependent formaldehyde dehydrogenase. Experiments were carried out to evaluate the effects of diethyl maleate or phorone, agents that deplete GSH from the liver, on the oxidation of formaldehyde. The addition of diethyl maleate or phorone to intact mitochondria or to disrupted mitochondrial fractions produced inhibition of formaldehyde oxidation. The kinetics of inhibition of the low-Km mitochondrial aldehyde dehydrogenase were mixed. Mitochondria isolated from rats treated in vivo with diethyl maleate or phorone had a decreased capacity to oxidize either formaldehyde or acetaldehyde. The activity of the low-Km, but not the high-Km, mitochondrial aldehyde dehydrogenase was also inhibited. The production of CO2 plus formate from 0.2 mM-[14C]formaldehyde by isolated hepatocytes was only slightly inhibited (15-30%) by incubation with diethyl maleate or addition of cyanamide, suggesting oxidation primarily via formaldehyde dehydrogenase. However, the production of CO2 plus formate was increased 2.5-fold when the concentration of [14C]formaldehyde was raised to 1 mM. This increase in product formation at higher formaldehyde concentrations was much more sensitive to inhibition by diethyl maleate or cyanamide, suggesting an important contribution by mitochondrial aldehyde dehydrogenase. Thus diethyl maleate and phorone, besides depleting GSH, can also serve as effective inhibitors in vivo or in vitro of the low-Km mitochondrial aldehyde dehydrogenase. Inhibition of formaldehyde oxidation by these agents could be due to impairment of both enzyme systems known to be capable of oxidizing formaldehyde. It would appear that a critical amount of GSH, e.g. 90%, must be depleted before the activity of formaldehyde dehydrogenase becomes impaired.     

Influence of Complete and Pronounced Incomplete Cerebral Ischemia and Subsequent Recirculation on Cortical Concentrations of Oxidized and Reduced Glutathione in the Rat

Abstract: The influence of complete and pronounced incomplete cerebral ischemia on cortical concentrations of reduced (GSH) and oxidized (GSSG) glutathione was studied in lightly anaesthetized (70% N₂ O) rats. GSH was extracted with HCl-methanol-perchloric acid and GSSG with trichloroacetic acid in the presence of N-ethylmaleimide and measured fluorometrically, giving normal concentrations in cortical tissue of about 2 and 0.01 μmol.g^?1 respectively. Reversible complete ischemia was induced by increasing the intracranial pressure to above the systolic blood pressure by infusing mock CSF into the cisterna magna. Reversible pronounced incomplete ischemia was induced by bilateral carotid artery clamping combined with hypovolemic hypotension. Whether complete or incomplete, a 30-min ischemic period caused a similar decrease in cortical GSH concentration (to about 90% of control) without any concomitant accumulation of GSSG in the tissue (or in CSF). Prolongation of the ischemic period (complete ischemia) to maximally 120 min caused an almost linear decrease of the tissue glutathione concentration to 45% of the preischemic value. During subsequent recirculation following a 30 min period of either complete or pronounced incomplete ischemia, there was a further decrease in cortical GSH concentrations without a reciprocal increase in GSSG concentrations. Lipid peroxidation (verified by determination of malondialdehyde production) induced in brain cortical tissue in vitro caused oxidation of tissue GSH with accumulation of GSSG. As the observed decrease in GSH during brain ischemia in vivo was not accompanied by any reciprocal increase in GSSG the results fail to support the hypothesis that peroxidative damage occurs during or following brain ischemia. The finding of an unchanged GSSG concentration does, however, not exclude the possibility of an increased turnover rate in the glutathione reductase reaction. It is concluded that the observed decrease in tissue GSH concentration mainly reflects a decrease in the glutathione pool size, due to an imbalance between breakdown and synthesis secondary to tissue energy failure.     

Lipid Peroxidation Scavengers Prevent the Carbonylation of Cytoskeletal Brain Proteins Induced by Glutathione Depletion

In this study, we investigated the possible link between lipid peroxidation (LPO) and the formation of protein carbonyls (PCOs) during depletion of brain glutathione (GSH). To this end, rat brain slices were incubated with the GSH depletor diethyl maleate (DEM) in the absence or presence of classical LPO scavengers: trolox, caffeic acid phenethyl ester (CAPE), and butylated hydroxytoluene (BHT). All three scavengers reduced DEM-induced lipid oxidation and protein carbonylation, suggesting that intermediates/products of the LPO pathway such as lipid hydroperoxides, 4-hydroxynonenal and/or malondialdehyde are involved in the process. Additional in vitro experiments revealed that, among these products, lipid hydroperoxides are most likely responsible for protein oxidation. Interestingly, BHT prevented the carbonylation of cytoskeletal proteins but not that of soluble proteins, suggesting the existence of different mechanisms of PCO formation during GSH depletion. In pull-down experiments, beta-actin and alpha/beta-tubulin were identified as major carbonylation targets during GSH depletion, although other cytoskeletal proteins such as neurofilament proteins and glial fibrillary acidic protein were also carbonylated. These findings may be important in the context of neurological disorders that exhibit decreased GSH levels and increased protein carbonylation such as Parkinson's disease, Alzheimer's disease, and multiple sclerosis.     

Fulminant Hepatic Failure in Rats Induces Oxidative Stress Differentially in Cerebral Cortex,Cerebellum and Pons Medulla

Hepatic Encephalopathy (HE) is one of the most common complications of acute liver diseases and is known to have profound influence on the brain. Most of the studies, available from the literature are pertaining to whole brain homogenates or mitochondria. Since brain is highly heterogeneous with functions localized in specific areas, the present study was aimed to assess the oxidative stress in different regions of brain-cerebral cortex, cerebellum and pons medulla during acute HE. Acute liver failure was induced in 3-month old adult male Wistar rats by intraperitoneal injection of thioacetamide (300 mg/kg body weight for two days), a well known hepatotoxin. Oxidative stress conditions were assessed by free radical production, lipid peroxidation, nitric oxide levels, GSH/GSSG ratio and antioxidant enzyme machinery in three distinct structures of rat brain-cerebral cortex, cerebellum and pons medulla. Results of the present study indicate a significant increase in malondialdehyde (MDA) levels, reactive oxygen species (ROS), total nitric oxide levels [(NO) estimated by measuring (nitrites + nitrates)] and a decrease in GSH/GSSG ratio in all the regions of brain. There was also a marked decrease in the activity of the antioxidant enzymes-glutathione peroxidase, glutathione reductase and catalase while the super oxide dismutase activity (SOD) increased. However, the present study also revealed that pons medulla and cerebral cortex were more susceptible to oxidative stress than cerebellum. The increased vulnerability to oxidative stress in pons medulla could be due to the increased NO levels and increased activity of SOD and decreased glutathione peroxidase and glutathione reductase activities. In summary, the present study revealed that oxidative stress prevails in different cerebral regions analyzed during thioacetamide-induced acute liver failure with more pronounced effects on pons medulla and cerebral cortex. Murthy Ch.R.K—Deceased while in service.     

Induction of cystine and glutamate transport activity in human fibroblasts by diethyl maleate and other electrophilic agents

The transport activity for cystine and glutamate in cultured human diploid fibroblasts is enhanced in response to diethyl maleate treatment. The enhancement is time- and dose-related, with a lag of about 3 h, and maximum enhancement (approximately 3-fold increase in the rate of uptake) is attained after 1 to 2 days of incubation of the cells with 0.1 mM diethyl maleate. The enhancement of the transport activity is accompanied by an increase in the Vmax and little change in the Km, and it requires RNA and protein synthesis. Other electrophilic agents, such as cyclohex-2-en-1-one, ethacrynic acid, 1,2-epoxy-3-(p-nitro-phenoxy)propane, and sulfobromophthalein, similarly enhance the transport activity. These electrophiles are known as agents that interact with glutathione. For example, diethyl maleate at high concentrations, i.e. 1 mM, depletes intracellular glutathione and injures the cells. However, at relatively low concentrations diethyl maleate and other electrophilic compounds do cause increases in the intracellular levels of glutathione which we attribute to the enhanced uptake of cystine. It is suggested that the transport system for cystine and glutamate is involved in a protective mechanism of cells against an electrophilic attack.     

Spindle disturbances in mammalian cells. IV. The action of some glutathione-specific agents in V79 Chinese hamster cells, changes in levels of free sulfhydryls and ATP, c-mitosis and effects on DNA metabolism

The glutathione-specific agents diamide, diethyl maleate and 1-chloro-2,4-dinitrobenzene were found to induce a low frequency of c-mitosis (15%) at non-toxic concentrations concomitant with a 30-40% decrease of non-protein sulfhydryls. The frequency of c-mitosis did not increase further with increased concentrations until non-protein sulfhydryl levels were obtained suggesting depletion of reduced glutathione. The observed shape of the concentration-response curve for c-mitosis is particular to these 3 agents and caffeine among 22 different compounds being tested under comparable conditions. This suggests a similar mechanism of action and from what is known about caffeine this mechanism probably involves an impaired control of cytoplasmic free Ca2+. It is speculated that this impairment with the glutathione-specific agents is primarily due to depletion of a particular pool of reduced glutathione. Tertiary butylhydroperoxide which is a substrate for glutathione peroxidase(s) also causes c-mitosis when there is no significant decrease of non-protein sulfhydryls. The c-mitotic response was found to be biphasic with maintained control levels at an intermediate concentration. The humps in the concentration-response curve for c-mitosis appeared coincident with a mitogenic response (G1----S). Since the latter type of effect most probably is Ca2+ dependent and since the spindle is sensitive to Ca2+ it is tentatively suggested that the c-mitotic effect of tertiary butylhydroperoxide is due to an increase of cytoplasmic Ca2+. Measurements performed imply that an increase of glutathione disulfide (diamide) is more inhibitory to uptake and incorporation of thymidine than a decrease of reduced glutathione per se (diethyl maleate). This difference is probably due to secondary effects on pertinent protein sulfhydryls with diamide, one possible target being the ribonucleotide reductase. All compounds were found to cause an increase of ATP with some of the applied concentrations. The results with diethyl maleate suggest that an increase of ATP is favored by an attack on mitochondrial reduced glutathione. The possible analogy between this effect and an increase of ATP and Ap4A in bacteria during oxidative stress is considered.