UMLS:C1260386 - FACTA Search

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Query: UMLS:C1260386 (GSH)
38,102 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The hepatotoxicity of CCl4 is mediated through its initial reduction by cytochrome P-450 to the CCl3.radical. This radical then damages important metabolic systems such as the ATP-dependent microsomal Ca2+ pump. Previous studies from our laboratory on isolated microsomes have shown that NADPH in the absence of toxic agents inhibits this pump. We have now found in in vitro incubations that CCl4 (0.5-2.5 mM) enhanced the NADPH-dependent inhibition of Ca2+ uptake from 28% without CCl4 to a maximum of 68%. These concentrations are in the range found in the livers and blood of lethally intoxicated animals (Dambrauskas, T., and Cornish, H. H. (1970) Toxicol. Appl. Pharmacol. 17, 83-97; Long, R.M., and Moore, L. (1988) Toxicol. Appl. Pharmacol. 92, 295-306) and are toxic to cultured hepatocytes (Long, R. M., and Moore, L. (1988) Toxicol. Appl. Pharmacol. 92, 295-306). The inhibition of Ca2+ uptake was due both to a decrease in the Ca2(+)-dependent ATPase and to an enhanced release of Ca2+ from the microsomes. The NADPH-dependent CCl4 inhibition was greater under N2 and was totally prevented by CO. GSH (1-10 mM) added during the incubation with CCl4 prevented the inhibition. This protection was also seen when the incubations were performed under nitrogen. When samples were preincubated with CCl4, the CCl4 metabolism was stopped, and then the Ca2+ uptake was determined; GSH reversed the CCl4 inhibition of Ca2+ uptake. This reversal showed saturation kinetics for GSH with two Km values of 0.315 and 93 microM when both the preincubation and the Ca2+ uptake were performed under air, and 0.512 and 31 microM when both were performed under nitrogen. Cysteine did not prevent the NADPH-dependent CCl4 inhibition of Ca2+ uptake. CCl4 increased lipid peroxidation in air, but no lipid peroxidation was seen under nitrogen. Lipid peroxidation was only modestly reversed by GSH. GSH did not remove 14C bound to samples preincubated with the 14CCl4. Although EDTA (100 microM) decreased the CCl4 inhibition, the metal-complexing agents deferoxamine (100 microM) and diethyldithiocarbamate (100 microM) had no effect on the inhibition of the pump. Similarly, the reactive oxygen scavengers catalase (65 micrograms/ml), superoxide dismutase (15 micrograms/ml), mannitol (10 mM), and dimethyl sulfoxide (50 mM) also had no effect. Our results suggest that the initial toxicity of CCl4 for the Ca2+ pump results from the metabolism of CCl4 to the CCl3. radical. This radical then directly oxidizes the Ca2+ pump, leading to decreased Ca2+ uptake.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:The in vitro NADPH-dependent inhibition by CCl4 of the ATP-dependent calcium uptake of hepatic microsomes from male rats. Studies on the mechanism of the inactivation of the hepatic microsomal calcium pump by the CCl3.radical. 214 Mar 58

In a panel of 10 human tumour cell lines with no prior exposure to drugs in vitro, resistance to cisplatin correlated with resistance to the nitrogen mustard derivatives Asta Z-7557 (mafosfamide, an activated form of cyclophosphamide), melphalan and chlorambucil. Simultaneous treatment with DL-buthionine-S,R-sulfoximine did not enhance the toxicity of cisplatin or Asta Z-7557, and no correlation was found between drug resistance and cellular levels of metallothioneins (as judged by sensitivity to cadmium chloride), glutathione (GSH), GSH reductase, GSH transferase, or gamma-glutamyltranspeptidase. The two cell lines most resistant to Asta Z-7557 expressed aldehyde dehydrogenase cytosolic isozyme 1, found also in normal ovary, but not isozyme 3. Treatment of resistant cells with cisplatin or Asta Z-7557 inhibited cellular DNA synthesis and replication of adenovirus 5 to a lesser extent than in sensitive cells. The virus could be directly inactivated by both drugs prior to infection, subsequent replication being inhibited to the same extent in sensitive and resistant cells. In contrast to Asta Z-7557 and other DNA damaging agents, cisplatin was much more toxic to adenovirus (D37 0.022-0.048 microM) than to cells (D37 0.25-2.5 microM). The adenovirus 5 mutant Ad5ts125 having a G----A substitution was even more sensitive to cisplatin (D37 7-8 nM) than wild type virus and another mutant. Cisplatin was detoxified less by sonicated resistant resistant cells than sensitive cells, as judged by inactivation of Ad5ts125 added to the reaction mixture. It can be inferred that (i) the major differences in cellular resistance to cisplatin and Asta Z-7557 in the present material did not involve enhanced DNA repair or protection by metallothioneins or GSH, but were associated with the ability to continue cellular and viral DNA synthesis during treatment, (ii) resistance was not associated with less template damage, and (iii) the adenovirus genome may be a suitable probe for predicting tumour resistance to cisplatin and for elucidating the DNA sequence dependence of cisplatin toxicity.
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PMID:Relationships between resistance to cross-linking agents and glutathione metabolism, aldehyde dehydrogenase isozymes and adenovirus replication in human tumour cell lines. 226 Sep 88

Chemical reactions between the isothiazolone biocides, N-methylisothiazol-3-one (MIT), benzisothiazol-3-one (BIT) and 5-chloro-N-methylisothiazol-3-one (CMIT) with cysteine have been investigated by u.v. and NMR spectroscopy. At physiological pH all three agents interacted oxidatively with thiols to form disulphides. Further interaction with thiols caused the release of cystine and formation of a reduced, ring-opened form of the biocide (mercaptoacrylamide). In an analogous fashion to the initial reaction the mercaptoacrylamide reacted with another molecule of biocide to give biocide dimers. NMR spectral studies indicated that for CMIT the mercaptoacrylamide form is capable of tautomerization to a highly reactive thio-acyl chloride. Formation of mercaptoacrylamide was in all cases highly pH-dependent. Alcohol dehydrogenase was insensitive to all three agents but was highly sensitive to CMIT when co-administered with dithiothreitol. Capacity to form a thioacyl chloride from the mercaptoacrylamide is suggested to account for much of this enhanced activity. Stopped-flow spectroscopic studies showed rates of reaction with glutathione (GSH) to directly parallel antimicrobial activity. Additionally, CMIT was able to react directly with both ionization states of GSH (pH 7-10) whilst BIT and MIT appeared only to interact when the glutamyl-nitrogen of GSH was charged (pH 8.5).
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PMID:Chemical reactivity of some isothiazolone biocides. 229 21

Rats orally given radioactive Clebopride [[14C]CP; N-(1'-benzyl-4'-piperidyl)-2-[14C]methoxy-4-amino-5-chlorobenzamide++ +], an antiulcer agent, excreted a novel type of ornithine (Orn)-GSH double conjugate in the bile as a major metabolite [( 14C]BMCP), corresponding to 18% of the dose. The present study provides the first evidence for Orn conjugation of a xenobiotic in mammals and demonstrates that the structure of the radioactive conjugate differs fundamentally from those known in birds and reptiles. The structure of the biliary metabolite, [14C]BMCP, purified to homogeneity by silica gel thin layer and reverse phase high pressure liquid chromatography, was elucidated as S-[2-ornithylamino-4-[14C]methoxy-5-(1'-methyl-4'-piperidylamin o) carboxyphenyl]glutathione, based mainly on the following facts: 1) BMCP showed a protonated molecular ion (M + H)+ peak at m/z 683 in the secondary ion mass spectrum and 2) [14C]BMCP afforded Orn, glutamic acid, glycine, S-(2-amino-4-[14C]methoxy-5-carboxyphenyl)cysteine [( 14C]AMCC), and 1-methyl-4-aminopiperidine (MAP) quantitatively, in an equal molar ratio, by complete hydrolysis with peptidase. Thus, BMCP was a metabolite with three enzymatically hydrolyzable amide bonds in addition to the one existing originally in the parent structure of the drug, which produces MAP by peptic digestion. Of the three additional amide bonds of BMCP, one was a novel type of bond formed by condensation of the alpha-carboxylic acid group of Orn with the primary aromatic amino group of the drug and the other two were in the S-glutathionyl residue, substituted for the chlorine atom vicinal to the Orn-conjugating primary amino group in the aromatic ring and affording glutamic acid, glycine, and the S-cysteine conjugate AMCC by hydrolysis of BMCP with the peptidase. Substitution of a methyl group for the benzyl group at the piperidine ring nitrogen atom, leading to the formation of MAP by peptic digestion, also occurred during metabolism of CP to BMCP.
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PMID:Novel type of ornithine-glutathione double conjugate excreted as a major metabolite into the bile of rats administered clebopride. 235 8

Nitrogen dioxide (NO2), a major oxidant constituent of vehicle emissions, is toxic to lung cells including endothelial cells. Since NO2 is a reactive free radical, one of the postulated mechanisms of NO2-induced pulmonary injury involves the peroxidation of membrane lipids. Therefore, this study evaluated the dose- and time-dependent effects of nitrogen dioxide exposure by measuring the biochemical and biophysical parameters, as well as the metabolic function, in porcine pulmonary artery and aortic endothelial cells in monolayer cultures. To evaluate the biochemical changes, the antioxidant enzyme GSH-reductase (GSH-red), GSH-peroxidase (GSH-per), and glucose-6-phosphate dehydrogenase (G6PDH) activities, as well as the lipid peroxide formation, glutathione (GSH) content, and lactate dehydrogenase (LDH) release were measured. Biophysical changes were measured by monitoring lipid fluidity in both the hydrophobic and hydrophilic regions of the plasma membrane. The uptake of 5-hydroxytryptamine (5-HT) was measured as a metabolic function of endothelial cells. Confluent porcine pulmonary artery and aortic endothelial cells were exposed to 3 or 5 ppm NO2 or air (control) for 3-24 hours. After 3-, 6-, or 12-hour exposures to 3 or 5 ppm NO2, the GSH-red and G6PDH activities, as well as the lipid peroxide formation and LDH release, were not different from those of controls in both pulmonary artery and aortic endothelial cells. Exposure of the cells to 3 or 5 ppm NO2 for 24 hours resulted in significant increases in GSH-red (p less than 0.05) and G6PDH (p less than 0.001) activities in both cell types. Exposure to 5 ppm NO2 for 24 hours significantly (p less than 0.05) increased lipid peroxide formation and increased (p less than 0.01) LDH release in both the pulmonary artery and aortic endothelial cells. GSH-per activity and GSH content in NO2-exposed pulmonary artery and aortic endothelial cells were not different from those of controls, irrespective of NO2 concentration and exposure time. Fluorescence spectroscopy was used to measure the membrane lipid fluidity. Membrane fluidity in the hydrophobic region was measured by 1,6-diphenyl-1, 3, 5-hexatriene (DPH), an aromatic hydrocarbon that partitions into the hydrophobic interior of the lipid bilayer.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Biochemical and metabolic response to nitrogen dioxide-induced endothelial injury. 247 62

The purpose of this study was to investigate whether lipid peroxidation plays a role in (TCE) trichloroethylene-induced nephrotoxicity in mice at different oxygen concentrations. Male NMRI mice (25-30 g) were treated i.p. with TCE in a dosage of 125-1000 mg/kg in sesame oil. To determine the TCE-induced depletion of reduced glutathione (GSH) in the kidney cortex and liver tissue, mice were given 1000 mg/kg TCE i.p., then killed between 0 and 6 h after TCE administration and GSH was measured was non-protein sulfhydryls. In another series of experiments, mice were administered 125 to 1000 mg/kg TCE i.p. with or without a 2 h i.p. pretreatment with 1500 mg/kg L-buthionine-S-R-sulfoximine (BSO). Mice were then exposed to a 10, 15, 20 or 100% oxygen atmosphere for 3 h and lipid peroxidation in vivo was measured as exhalation of ethane. Subsequently, mice were killed and malondialdehyde (MDA) generation was measured in the liver and kidney cortex. Ethane evolution was estimated by gas chromatography and MDA was determined as thiobarbituric acid reactive substances. In a further series of experiments mice were treated in the same manner as for ethane and MDA determination and the changes in blood urea nitrogen (BUN) and accumulation of the organic ion p-aminohippurate (PAH) were determined. PAH accumulation by renal cortical slices were measured as the slice to medium (S/M) ratio. Six hours after administration of 1000 mg/kg TCE to mice, GSH was significantly depleted to about 60% of control in the kidney cortex but not in the liver. Three hours after TCE administration, MDA content in the kidney cortex and ethane exhalation increased in a dose-dependent manner only under a 10% oxygen atmosphere. Under the same experimental conditions, MDA content remained unchanged in the liver. BSO depletion of GSH prior TCE administration induced an increase of the MDA content in the kidney cortex and an increase of the ethane exhalation in vivo. At 10% oxygen concentration, TCE induced a dose-dependent increase in BUN and a dose-dependent decrease of PAH accumulation by the renal cortical slices. Thus, the results of the present study suggest that, under hypoxic conditions, lipid peroxidation plays a role in TCE nephrotoxicity.
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PMID:Lipid peroxidation: a possible mechanism of trichloroethylene-induced nephrotoxicity. 271 99

Male NMRI mice were treated i.p. with dichlorovinylcysteine (DCVC) in a dosage of 2.5-500 mg/kg-1 and renal cortical slices from naive mice were incubated with 0-125 micrograms/ml-1 DCVC. The effects of DCVC on blood urea nitrogen (BUN), reduced glutathione (GSH) content, malondialdehyde (MDA) production, p-aminohippuric acid (PAH)- and tetraethylammonium (TEA)-accumulation and glucose synthesis (gluconeogenesis) were measured. DCVC depleted GSH in a time- and dose-dependent manner. Depletion of renal cortical GSH by DCVC was more pronounced in the kidney cortex than in the liver. DCVC caused a dose-dependent increase of ethane exhalation and of MDA production in the renal cortex. When animals were kept in a closed system, decrease in oxygen concentration increased the peroxidative damage. No increase of MDA concentration was observed in the liver. Treatment of mice with DCVC induced a dose-dependent increase in BUN and decreased the accumulation of PAH and TEA in renal cortical slices. Pretreatment of mice with aminooxyacetic acid (AOAA) and (+) cyanidanol-3 (CY) caused a significant reduction in DCVC-induced lipid peroxidation and nephrotoxicity. In vitro incubation of renal cortical slices of naive mice with DCVC resulted in a concentration-dependent increase in MDA and a concentration-dependent decrease in the accumulations of PAH, TEA and of gluconeogenesis. In conclusion, the interaction of DCVC and/or its metabolites with membrane lipids may be responsible for lipid peroxidation and nephrotoxicity. The formation of lipid peroxidation products was greater under hypoxic conditions and appeared to be related to the DCVC-induced nephrotoxicity. This data suggests lipid peroxidation as a possible mechanism of DCVC-induced nephrotoxicity.
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PMID:Peroxidative damage and nephrotoxicity of dichlorovinylcysteine in mice. 274 25

Cysteine is required for the synthesis of cosubstrates for two pathways of acetaminophen metabolism: 3'-phosphoadenosine-5'-phosphosulfate (PAPS) for sulfation and glutathione (GSH) for detoxification of the reactive metabolite (N-acetyl-p-benzoquinoneimine, NAPQI). Dietary deficiency of cysteine may reduce hepatic production of PAPS and GSH and thereby reduce metabolism of the drug (by sulfation and detoxification of NAPQI) and hence lead to potentiation of acetaminophen liver injury. Conversely, limitation of sulfur-containing amino acids could result in depression of protein synthesis and hepatic cytochrome P450 levels, and hence in decreased reactive metabolite formation and decreased liver injury. To determine whether the potentiating effects exceed the protective effects, rats were fed isocaloric AIN-76 liquid diets containing various levels of methionine as the sole source of sulfur in the diet for 3 weeks prior to administration of acetaminophen. Sulfur deficiency was assessed by measuring urinary inorganic sulfate levels. Sulfur-deficient diets retarded growth but did not affect nitrogen balance. Sulfur-deficient animals had lower basal levels of hepatic GSH. Pharmacokinetic studies revealed that at low doses of acetaminophen (20 mg/kg), animals fed sulfur-deficient diets metabolized the drug more slowly due to a markedly reduced sulfation capacity, whereas at the high dose of acetaminophen (400 mg/kg), rats that were fed sulfur-deficient diets had a higher clearance of the drug than rats that were fed the complete diet. The increase in clearance was due largely to an enhanced glucuronidation capacity and an enhanced P450-dependent oxidation as indicated by mercapturate formation. Histologic studies revealed that rats fed sulfur-deficient diets showed increases in both incidence and severity of acetaminophen hepatic necrosis. Thus, the potentiating effects exceeded the protective effects. These observations raise the possibility that nutritional inadequacy of sulfur-containing amino acids which could occur during protein malnutrition may similarly enhance susceptibility to acetaminophen liver injury in humans.
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PMID:Effects of sulfur-amino acid-deficient diets on acetaminophen metabolism and hepatotoxicity in rats. 281 88

Isolated haemosiderin contained iron and nitrogen in a weight ratio of 6.75, with phosphorus and no detectable haem. Considerably more iron was released from haemosiderin under acidic conditions than under neutral conditions in the presence of ascorbate, nitrilotriacetate or dithionite. Unlike the situation with ascorbate, chelators such as citrate, ADP or succinate induced the release of only some iron, with almost no pH-dependence. Dehydroascorbate (the oxidized form of ascorbate with no reducing capacity) behaved like citrate, ADP, succinate or desferal, rather than like ascorbate itself, in releasing iron. GSH had less effect on the release of iron than these chelators, but in the presence of a small amount of chelator the release of iron increased, especially under acidic conditions. Thus reduction, chelation and pH were all found to be important factors involved in the release of iron from haemosiderin. Investigation by e.p.r. of hydroxyl-radical production by the released iron showed high radical productivity at an acidic pH. However, at a physiological pH, almost no radical formation was detected, except in the presence of nitrilotriacetate. These findings suggested that, under physiological conditions, haemosiderin was not an effective iron donor and was almost not involved in radical production. Under acidic conditions, however, such as in inflammation, hypoxia and in a lysosomal milieu, it could possibly be an iron donor and is thought to be implicated in radical production and tissue damage in iron-overloaded conditions.
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PMID:Iron release from haemosiderin and production of iron-catalysed hydroxyl radicals in vitro. 283 49

Oxidation of diethyldithiocarbamate (DTC) to disulfiram (DS) by liver microsomes was tested in vitro by using a copper-DTC chelate formation reaction after the conversion of DS to DTC by glutathione (GSH). In the presence of NADPH, microsomes produced DS from DTC in both the free and microsome-bound forms, the former being greater than the latter. DS production was dependent on NADPH and DTC concentrations, and incubation time. Increases in microsomal concentrations, up to a certain level, also increased the free and total DS production. NADH was only somewhat effective, both the exposure to a nitrogen atmosphere and heat-denaturation of the microsomes suppressed the reaction. Preincubation of microsomes with both DTC and NADPH markedly decreased aniline hydroxylase, p-nitroanisole O-demethylase and glucose-6-phosphatase activities, and moderately decreased NADH-ferricyanide and NADH-cytochrome c reductase, but NADPH-cytochrome c reductase was minimally affected. DTC alone had only slight effects on the activities. DS also decreased these enzyme activities, particularly glucose-6-phosphatase; the loss of NADPH-cytochrome c reductase activity being protected in the presence of NADPH. GSH almost completely prevented the loss of microsomal enzyme activities induced by DTC and NADPH except for the drug metabolizing activities, in which protection was incomplete. The microsomal oxidation of DTC to DS could play a role in the action of DS in the liver, since DS is rapidly degradated to DTC in vivo.
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PMID:Oxidation of diethyldithiocarbamate to disulfiram by liver microsomes in the presence of NADPH and subsequent loss of microsomal enzyme activity in vitro. 285 81

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