Decreased glutathione S-transferase activity in mice livers by acute treatment with lead, independent of alteration in glutathione content

Glutathione S-transferase (GST) activity and glutathione content in livers of male mice were assayed after acute administration of lead acetate (100 mg/kg i.p.). Fall in GST activity of lead-treated mice followed the decrease in glutathione content with a delay of more than 1 day. In addition, L-methionine (250 mg/kg i.p.) pretreatment did not antagonize the fall in GST activity induced by lead. In contrast, diethyl maleate, a potent glutathione depletor, increased GST activity. Thus, lead administration reduced the ability of the phase II reaction of drug metabolism, although glutathione depletion was not necessarily a critical factor for impairmen of GST per se.     

Papaverine, an opium alkaloid influences hepatic and pulmonary glutathione S-transferase activity and glutathione content in rats.

The present study evaluates the effect of oral administration of papaverine at differential dosing regimens (100 mg/kg bw and 200 mg/kg bw) on the hepatic and pulmonary glutathione S-transferase (GST) activity and glutathione content (GSH) in male Wistar rats. Papaverine treatment caused a pronounced increase in GST activity and GSH content at the higher dosing level in the rat liver and lung. We conclude that papaverine, can possibly act as a chemopreventive agent against chemical carcinogenesis.     

Anti-genotoxicity and glutathione S-transferase activity in mice pretreated with caffeinated and decaffeinated coffee.

In vivo anti-genotoxic effects of caffeinated and decaffeinated instant coffee were compared in mice after pretreatment either by gavage for 10 consecutive days or in the drinking water for 2 weeks. Changes in hepatic sulfhydryl (-SH) content and glutathione S-transferase (GST) activity were evaluated in pretreated animals. Both caffeinated and decaffeinated instant coffee induced a moderate increase in -SH content and GST activity following pretreatment (with 70, 140 and 280 mg/kg body weight) by gavage for 10 days. This enhancement was not always dose dependent. The maximum effect on GST activity was observed at a dose of 140 mg/kg body weight/day. However, such an effect was not observed after administration of drinking water containing 2% caffeinated/decaffeinated instant coffee for 2 weeks. Results of the bone marrow micronucleus test for evaluating genotoxic effects revealed that both caffeinated and decaffeinated instant coffee (140 mg/kg body weight/day) could exert significant anti-genotoxic effects against ip injected benzo[a]pyrene (BP), cyclophosphamide (CPH), 7,12-dimethylbenz[a]anthracene (DMBA), mitomycin C (MMC) and procarbazine (PCB) in animals pretreated by gavage. Anti-genotoxic effects against BP, DMBA and urethane (URE) were evaluated in animals that received drinking water containing 2% caffeinated/decaffeinated instant coffee for 2 weeks. With the exception of the anti-genotoxic effect of decaffeinated coffee against DMBA, there was no significant change in genotoxicity after the above pretreatment. From this work, there is no evidence for any significant difference in the in vivo anti-genotoxicity of caffeinated and decaffeinated instant coffee.     

Nitroglycerin relaxes coronary artery of the pig with no change in glutathione content or glutathione S-transferase activity.

1. The role of glutathione content and glutathione S-transferase activity in vascular relaxant responses to nitroglycerin was evaluated in potassium (30 mM)-contracted coronary artery strips of the pig by measuring changes in tension, glutathione content and glutathione S-transferase activity. 2. Prior exposure of coronary artery strips to nitroglycerin (10(-5)M or 10(-4)M for 20 min) resulted in tachyphylaxis to subsequent relaxation to nitroglycerin (10(-8)-10(-5)M). 3. The glutathione content and glutathione S-transferase activity of the arterial strips rendered tachyphylactic by prior exposure to nitroglycerin (10(-5)M for 20 min or 10(-3)M for 120 min) were not significantly different from those of control strips. 4. Treatment with diethyl maleate (10(-4)M or 10(-3)M for 60 min) markedly depleted arterial glutathione content in a concentration-dependent manner with no change in glutathione S-transferase activity. 5. The relaxant response of coronary artery strips to nitroglycerin (10(-8)-10(-5)M) was completely unaffected following treatment with diethyl maleate (10(-4)M or 10(-3)M for 60 min). 6. The results suggest that vascular glutathione content does not play an important role in vascular relaxation or tolerance development to nitroglycerin, at least in pig isolated coronary artery.     

Different effects of nine clausenamide ennatiomers on liver glutathione biosynthesis and glutathione S-transferase activity in mice

AIM: To study the effects of nine synthetic clausenamide with different stereo structures on liver glutathione (GSH) biosynthesis and glutathione S-transferase (GST) activity in mice. METHODS: The nine test compounds were racemic mixtures and their ennatiomers of clausenamide, neoclausenamide and epineoclausenamide. Mice were administered clausenamide 250 mg/kg once daily for 3 consecutive days, ig, and were killed 24 h after the last dosing. The mouse liver cytosol GSH and GST were determined with related biochemical methods. RESULTS: Nine clausenamides exhibited different effects on liver GSH and GST. Of nine clausenamides, only (+) and (+/-)clausenamide markedly increased liver cytosol GSH content. The mechanism of increasing liver GSH content of (+)clausenamide is mainly due to stimulating the key limiting enzyme gamma-glutamylcysteine synthetase (gamma-GCS) activity for GSH biosynthesis. The other test clausenamides had no such effect on liver GSH. All of the nine clausenamides induced a significant increase of GST activity. CONCLUSION: The effects of clausenamide ennatiomers on liver GST and GSH varied with the alterations of their spatial structures. (+)Clausenamide stimulated liver GSH biosynthesis through enhancing gamma-GCS activity.     

Chloroform-induced alteration of glutathione S-transferase activity

The effect of chloroform treatment on the hepatic glutathione S-transferases was studied in phenobarbital-treated rats. The apparent isozymic composition of glutathione S-transferases in hepatic cytosol was changed after chloroform treatment. Glutathione S-transferases AA, A, B, C, and D + E were observed in hepatic cytosol from untreated rats; in contrast, the catalytic activity associated with basic glutathione S-transferases, such as AA, A, B, and C, decreased with time after chloroform treatment. Glutathione S-transferase B was not detectable 2 hr after chloroform treatment, and glutathione S-transferases AA and C were scarcely detectable after 5 hr. Twenty-four hours after chloroform treatment, glutathione S-transferases A and C were clearly detectable as was D + E and a small amount of B. Hepatic cytosolic glutathione S-transferase activity was decreased by chloroform treatment, and reached a minimum at 5 hr after treatment. Corresponding to the decrease of hepatic cytosol glutathione S-transferase activity, serum glutathione S-transferase activity was elevated maximally 5 hr after chloroform treatment and returned to almost normal by 24 hr. Treatment of rats with SKF 525-A or cysteine inhibited the chloroform-induced elevation of serum glutathione S-transferase activity. The chromatographic properties of the glutathione S-transferases present in serum were similar to glutathione S-transferase D + E. Furthermore, after incubation of partially purified cytosolic glutathione S-transferases with chloroform in the presence of hepatic microsomes and NADPH, only transferase D + E was detected. The addition of bilirubin to partially purified cytosolic glutathione S-transferase decreased the basic character of glutathione S-transferases B and C. In conclusion, chloroform caused a release of hepatic cytosolic glutathione S-transferases into serum. Both the active metabolite of chloroform, which was produced by the microsomal cytochrome P-450 system, and bilirubin, which was increased by chloroform treatment, played roles in altering the properties of the glutathione S-transferases.     

Hepatic mixed function oxygenase activity and glutathione S-transferase activity in mice following ethanol consumption and withdrawal

The effect of an 8 day liquid diet containing 7% v/v ethanol and the effect of ethanol withdrawal on several drug metabolizing enzyme activities, cytochrome P-450 content and glutathione S-transferase activity (GST) has been studied in male C57/BL mice. After treatment, hepatic microsomal activities toward benzphetamine (BNZ), biphenyl (BPH) and dimethylnitrosamine (DMN) and cytosolic GST activity towards 1-chloro-2,4-dinitrobenzene (CDNB) were determined. Ethanol treatment caused a differential time dependent increase in the metabolism of the 4 xenobiotics. Increased BPH-4-hydroxylase activity correlated most closely with that of the increased concentration of hepatic P-450. That is, both values were increased (5.8-fold) over controls after 8 days of ethanol treatment. Ethanol withdrawal (24 h) resulted in a 46% reduction in the P-450 content and a 26% reduction in BPH-4-hydroxylase activity compared to the elevated values at day 8. By 48 h, the values were no different from controls. DNA-N-demethylase, BNZ-N-demethylase and GST activities all increased after 4 days of ethanol treatment and remained the same at 8 days. However, ethanol withdrawal resulted in differential time dependent changes in the activities towards BNZ, DMN, and CDNB. While DMN-N-demethylase activity returned to control activity within 24 h, BNZ-N-demethylase activity did not change for the first 24 h of withdrawal, but returned to control activity by 48 h. GST activity had not decreased by 48 h of withdrawal. These data suggest that ethanol induces several cytochrome P-450 isozymes that have a time difference in induction by ethanol and reduction following ethanol withdrawal. Furthermore, ethanol induction of GSTs occurs quickly (4 days) and remains elevated at least 48 h after ethanol withdrawal.     

Effects of derivatives of kahweol and cafestol on the activity of glutathione S-transferase in mice

The coffee constituents cafestol and kahweol are inducers of the activity of the detoxifying enzyme, glutathione S-transferase in laboratory animals. The two active functional groups, furan and glycol, on opposite ends of the diterpene nucleus of these two compounds have been modified. The resulting derivatives were evaluated for their ability to induce glutathione S-transferase activity in different tissues of the ICR/Ha mice. Derivatives of both cafestol and kahweol, which were the products of the modifications on the glycol function, retained much of the inducing properties of the parent compounds in the liver and mucosa of the small bowel. The effects of these compounds on the tissue acid-soluble sulfhydryl level, in general, were similar to those of the parent compounds. Some derivatives of kahweol, however, appeared to have lost their ability to induce increased levels of sulfhydryls in the liver. Catalytic hydrogenation of the furan moiety gave two products, the dihydro and tetrahydro derivatives. Both compounds and their corresponding acetates lost their effectiveness as inducers of glutathione S-transferase activity. In contrast, these compounds still retained their ability to induce increased levels of acid-soluble sulfhydryls in both the liver and the mucosa of the small bowel. These findings indicate that the furan moiety of cafestol and kahweol is vital to their biological activity as inducers of increased glutathione S-transferase activity.     

Up-regulation of glutathione S-transferase activity in enterocytes of young children.

The relationship between age and busulfan apparent oral clearance (Cl/F) expressed relative to adjusted ideal body weight and body surface area (bsa) was evaluated in 135 children aged 0 to 16 years undergoing hematopoietic stem cell transplantation for various disorders. Busulfan plasma levels were measured by gas chromatography-mass spectrometry after the first daily dose of the 4-day dosing regimen. Cl/F expressed relative to adjusted ideal body weight (ml/min/kg) and bsa (ml/min/m(2)) was lower in 9- to 16-year-old (y.o.) compared with 0- to 4-y.o. children (49 and 30%; p<.001). We hypothesized that the greater busulfan Cl/F observed in young children was in part due to enhanced (first-pass intestinal) metabolism. Busulfan conjugation rate was compared in incubations with human small intestinal biopsy specimens from healthy young (1- to 3-y.o.) and older (9- to 17-y.o.) children. Villin content in biopsy specimens was determined by Western blot and busulfan conjugation rate was expressed relative to villin content to control for differences in epithelial cell content in pinch biopsies. Intestinal biopsy specimens from young children had a 77% higher busulfan conjugation rate (p =.037) compared with older children. We have previously shown that glutathione-S-transferase (GST) A1-1 is the major isoform involved in busulfan conjugation, and that this enzyme is expressed uniformly along the length of adult small intestine. Thus, the greater busulfan conjugation activity in intestinal biopsies of the young children was most likely due to enhanced GSTA1-1 expression. We conclude that age dependence in busulfan Cl/F appears to result at least in part from enhanced intestinal GSTA1-1 expression in young children.     

Induction of CYP1A2 by phenobarbital in the livers of aryl hydrocarbon-responsive and -nonresponsive mice.

The effects of phenobarbital treatment on the expression of the cytochrome P-450 (CYP or P-450) enzyme CYP1A2 in the livers of mice of various strains were examined. Phenobarbital induced the expression of CYP1A2 at the levels of mRNA, protein, and enzyme activity (methoxyresorufin O-demethylation and metabolic activation of 2-amino-3-methylimidazo[4,5-f]quinoline) in both aryl hydrocarbon-responsive [C57BL/6NCrj (C57BL/6), C3H/HeJSlc] and -nonresponsive (DBA/2NCrj, AKR/JSea, NZB/NSlc) mouse strains. The induction of CYP2B10, which is known as a phenobarbital-inducible P-450 in mice, was prominent in the livers of all five strains examined, whereas clear inductive effects on the P-450 CYP2B9 were not observed in female C57BL/6 and female DBA/2NCrj mice. These results indicate that CYP1A2 is a member of the family of phenobarbital-inducible genes in mice and suggest that the aryl hydrocarbon receptor-dependent induction pathway is not involved in the induction of CYP1A2. This concept is in accordance with those proposed by other laboratories recently using the AhR knockout mice. The following are new observations of this report. The magnitude of the increases in the CYP1A2 mRNA, protein, and enzyme activities were comparable among these three levels (ranging from 1.4- to 3. 1-fold), suggesting that the induction of CYP1A2 by phenobarbital is mainly determined at a pretranslational level. Cyclobarbital, pentobarbital, and secobarbital also induced CYP1A2 mRNA in primary culture hepatocytes from C57BL/6 mice. Barbital, in contrast, did not show any clear inductive effect on CYP1A2 mRNA.     

Role of glutathione and glutathione S-transferase in chlorambucil resistance.

A chlorambucil (CLB)-resistant cell line, N50-4, was developed from the established mouse fibroblast cell line NIH 3T3, by multistep drug selection. The mutant cells exhibited greater than 10-fold resistance to CLB. Alterations in GSH and glutathione S-transferase (GST) were found in CLB-resistant variants. A 7-10-fold increase in cellular GSH content and a 3-fold increase in GST activity were detected in N50-4 cells, compared with parental cells, as determined by enzymatic assays. An increase in steady state levels of the GST-alpha isozyme mRNA was found in the CLB-resistant cells, as analyzed by Northern blotting. No GST gene amplification or rearrangement was shown by Southern blot analysis. To test the relative roles of GSH and GST in CLB resistance, a number of GSH- and GST-blocking agents were used. The CLB toxicity was significantly enhanced in N50-4 cells by administration of either the GSH-depleting agent buthionine sulfoximine or the GST inhibitors ethacrynic acid or indomethacin. The resistance to CLB cytotoxicity in N50-4 cells, however, was still significantly higher than that of parental cells. The resistance of N50-4 cells to CLB was almost completely abolished by combination pretreatment yielding both GSH depletion and GST inhibition. The results indicate that both increased cellular GSH content and increased GST activity play major roles in CLB resistance in N50-4 mutant cells.     

Differential induction of rat hepatic glutathione S-transferase isoenzymes by hexachlorobenzene and benzyl isothiocyanate. Comparison with induction by phenobarbital and 3-methylcholanthrene

Male Wistar rats were treated with hexachlorobenzene, benzyl isothiocyanate, phenobarbital or 3-methylcholanthrene. Hepatic cytosolic glutathione S-transferase (GST) activity was determined with the substrates 1-chloro-2,4-dinitrobenzene, 1,2-dichloro-4-nitrobenzene, ethacrynic acid and trans-4-phenyl-3-buten-2-one. Cytosolic glutathione peroxidase activity was measured with cumene hydroperoxide. GST activity toward 1-chloro-2,4-dinitrobenzene, 1,2-dichloro-4-nitrobenzene and ethacrynic acid was enhanced by all compounds, hexachlorobenzene and 3-methylcholanthrene causing the largest and the smallest increase respectively. Trans-4-phenyl-3-buten-2-one-conjugating activity exhibited only small changes, while peroxidase activity with cumeme hydroperoxide was not changed by any of the inducing agents. GST isoenzymes were purified on S-hexylglutathione Sepharose 6B and separated by means of FPLC-chromatofocusing, to evaluate effects on the GST isoenzyme pattern. Hexachlorobenzene and phenobarbital both caused an increase in the relative amounts of subunits 1 and 3 when compared with subunits 2 and 4 respectively. For 3-methylcholanthrene only induction of subunit 1 was observed, possibly due to the relatively low induction levels of total GST activity. In benzyl isothiocyanate-treated animals, an induction of subunit 3 was found as well as an increase in the relative amount of subunit 2. Thus, benzyl isothiocyanate behaves differently from hexachlorobenzene, phenobarbital and 3-methylcholanthrene as an inducing agent of rat hepatic glutathione S-transferases.     

Antagonism of glycerol trinitrate activity by an inhibitor of glutathione S-transferase

The in vitro spasmolytic activity of glycerol trinitrate was measured on the KCl-contraction of aorta strips from the rabbit. In the presence of sulphobromophthalein, a known inhibitor of glutathione S-transferase, the dose-activity curve for the nitrate was displaced to the right. Much smaller displacements were obtained with the control spasmolytic substances--papaverine and S-nitroso-N-acetylpenicillamine. It was confirmed that sulphobromophthalein inhibits glutathione S-transferase activity in aorta homogenates. Aorta extracts did not detectably catalyze the reaction between glutathione and sulphobromophthalein and the glutathione level was not decreased by treating the intact aorta with sulphobromophthalein. It is concluded that sulphobromophthalein acts as a specific antagonist of the spasmolytic activity of glycerol trinitrate, probably as a result of its inhibition of glutathione S-transferase. It thus seems probable that glutathione and glutathione S-transferase are involved in the pharmacological activation of the organic nitrates.     

Metabolism of nitroglycerin by smooth muscle cells. Involvement of glutathione and glutathione S-transferase.

Metabolism of nitroglycerin (GTN) in the vascular smooth muscle is required for the drug to be effective in the treatment of angina pectoris and congestive heart failure. The usefulness of GTN is limited by the development of tolerance to the drug. The metabolism of GTN was studied in its target tissue, vascular smooth muscle. Inorganic nitrite was produced by cultured smooth muscle cells when GTN was added to the culture dish. Nitrite production increased with increasing GTN concentration and with incubation time. The enzymatic nature of GTN metabolism to nitrite was assessed by enzyme inhibition studies. Indocyanine green, a non-substrate inhibitor of glutathione S-transferase, inhibited GTN metabolism by smooth muscle cells. Cellular glutathione is also involved in GTN metabolism by the smooth muscle cell. Pretreatment with phorone, a glutathione S-transferase substrate, depleted cellular glutathione and decreased nitrite production from GTN. Pretreatment with buthionine sulfoximine, inhibitor of gamma-glutamylcysteine synthetase, decreased intracellular glutathione and caused decreased GTN metabolism in smooth muscle cells. Removal of cysteine from the smooth muscle cell incubation medium in combination with buthionine sulfoximine pretreatment decreased GTN metabolism to a lower level than buthionine sulfoximine pretreatment alone. This study shows that glutathione S-transferase and glutathione are involved in GTN metabolism by cultured smooth muscle cells.     

Effect of garlic on the hepatic glutathione S-transferase and glutathione peroxidase activity in rat

It was attempted to observe the effect of garlic on the hepatic glutathione s-transferase and glutathione peroxidase activity in this study. Glutathione s-transferase (EC 2.5.1.18) are thought to play a physiological role in initiating the detoxication of potential alkylating agents, inclnding pharmacologically active compounds. Glutathione peroxidase (EC 1.11.1.9) might play an important role in the protection of cellular structures against oxidative challenge. The activities of glutathione s-transferase and glutathione peroxidase in rat liver were increased by the treatment of garlic juice. Allicin fraction, heat-treated allicin fraction and garlic butanol fraction markedly inhibited glutathione s-transferase activityin vitro, whereas glutathione peroxidase activity was significantly increased in heat-treated allicin fraction and garlic butanol fraction.