Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.5.1.18 (glutathione S-transferase)
 22,582 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Ellagic acid (EA), a naturally occurring plant polyphenol possesses broad chemoprotective properties. Dietary EA has been shown to reduce the incidence of N-2-fluorenylacetamide-induced hepatocarcinogenesis in rats and N-nitrosomethylbenzylamine (NMBA)-induced rat esophageal tumors. In this study changes in the expression and activities of specific rat hepatic and esophageal mucosal cytochromes P450 (P450) and phase II enzymes following dietary EA treatment were investigated. Liver and esophageal mucosal microsomes and cytosol were prepared from three groups of Fisher 344 rats which were fed an AIN-76 diet containing no EA or 0.4 or 4.0 g/kg EA for 23 days. In the liver total P450 content decreased by up to 25% and P450 2E1-catalyzed p-nitrophenol hydroxylation decreased by 15%. No changes were observed in P450 1A1, 2B1 or 3A1/2 expression or activities or cytochrome b5 activity. P450 reductase activity decreased by up to 28%. Microsomal epoxide hydrolase (mEH) expression decreased by up to 85% after EA treatment, but mEH activities did not change. The hepatic phase II enzymes glutathione S-transferase (GST), NAD(P)H:quinone reductase [NAD-(P)H:QR] and UDP glucuronosyltransferase (UDPGT) activities increased by up to 26, 17 and 75% respectively. Assays for specific forms of GST indicated marked increases in the activities of isozymes 2-2 (190%), 4-4 (150%) and 5-5 (82%). In the rat esophageal mucosa only P450 1A1 could be detected by Western blot analysis and androstendione was the only P450 metabolite of testosterone detectable. However, there were no differences in the expression of P450 1A1, the formation of androstendione or NAD(P)H:QR activities between control and EA-fed rats in the esophagus. Although there was no significant decrease in overall GST activity, as measured with 1-chloro-2,4-dinitrobenzene (CDNB), there was a significant decrease in the activity of the 2-2 isozyme (66% of control). In vitro incubations showed that EA at a concentration of 100 microM inhibited P450 2E1, 1A1 and 2B1 activities by 87, 55 and 18% respectively, but did not affect 3A1/2 activity. Using standard steady-state kinetic analyses, EA was shown to be a potent non-competitive inhibitor of both liver microsomal ethoxyresorufin O-deethylase and p-nitrophenol hydroxylase activities, with apparent Ki values of approximately 55 and 14 microM respectively. In conclusion, these results demonstrate that EA causes a decrease in total hepatic P450 with a significant effect on hepatic P450 2E1, increases some hepatic phase II enzyme activities [GST, NAD-(P)H:QR and UDPGT] and decreases hepatic mEH expression. It also inhibits the catalytic activity of some P450 isozymes in vitro. Thus the chemoprotective effect of EA against various chemically induced cancers may involve decreases in the rates of metabolism of these carcinogens by phase I enzymes, due to both direct inhibition of catalytic activity and modulation of gene expression, in addition to effects on the expression of phase II enzymes, thereby enhancing the ability of the target tissues to detoxify the reactive intermediates.
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PMID:The effects of dietary ellagic acid on rat hepatic and esophageal mucosal cytochromes P450 and phase II enzymes. 862 97

The modulation of CCl4-induced hepatotoxicity in response to alkyl sulfides and alkyl ethers including allyl disulfide (ADS), allyl sulfide (AS), allyl ether (AE), propyl disulfide (PDS), propyl sulfide (PS), propyl ether (PE) and butyl sulfide (BS) was studied. Whereas pretreatment of rats with either ADS or AS (50 mg/kg, 7 days) blocked a CCl4-induced increase in plasma alanine aminotransferase (ALT) activity by 91 and 56%, respectively, AE, PDS, PS, PE or BS treatment enhanced CCl4-induced ALT activity by 52, 55, 238, 25 or 86%, respectively. Histochemical examinations supported the results of plasma ALT activity. Injection of GdCl3 to PS-pretreated rats failed to block the potentiated ALT increase, whereas GdCl3 completely prevented vitamin A-enhanced elevation of ALT activity. AS treatment completely blocked PS-potentiated CCl4 intoxication. Concomitant treatment of animals with both PS and vitamin A followed by a CCl4 insult resulted in super-potentiation of CCl4-induced hepatotoxicity, suggesting that the mechanism of PS-enhanced hepatotoxicity differs from that caused by vitamin A. Pyridine or phenobarbital potentiation of CCl4-induced increases in ALT activity implys that cytochrome P450 2E1 (P450 2E1) and P450 2B expression may be associated with the increased toxicity. P450 2E1 expression appeared to be associated with the alkyl sulfide-modulated hepatotoxicity, as evidenced by both immunoblot analyses and metabolic activity. P450 2B immunoblot analysis revealed that either AS or PS substantially induced hepatic P450 2B1/2 levels. Thus, PS-enhanced CCL4 hepatotoxicity may be related in part with P450 2B induction. ADS, AS or PS treatment caused increases in the glutathione S-transferase (GST) conjugating activity toward 1-chloro-2,4-dinitro-benzene. ADS, AS or PS induced Ya and Yb1 subunits by 2- to 3-fold. ADS or AS treatment also significantly elevated the levels of Yc subunits. PS failed to induce Yc expression, although this agent effectively increased Yb2 expression. Northern blot analyses revealed that ADS and AS concomitantly stimulated GST Ya, Yb1 and Yc2 gene expression, whereas PS increased the levels of Ya, Yb1, and Yb2 mRNA, but not Yc2 mRNA levels. The expression of GST subunit Yc2 in response to these compounds might be associated with hepatoprotective effects. These results demonstrate that ADS and AS have distinct capability of blocking CCl4-induced hepatotoxicity, whereas certain saturated alkyl sulfides rather potentiate CCl4-induced hepatotoxicity and that the underlying mechanism is associated with P450 2E1 and P450 2B expression, and possibly with certain GST expression.
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PMID:Molecular mechanism for alkyl sulfide-modulated carbon tetrachloride-induced hepatotoxicity: the role of cytochrome P450 2E1, P450 2B and glutathione S-transferase expression. 862 17

A growing number of human genetic polymorphisms in drug-metabolizing enzymes (DMEs) are being characterized. Some of these have been shown, quite convincingly, to be correlated with risk of toxicity or cancer, whereas others presently remain equivocal. There is good evidence that the correlation is stronger in populations exposed to a variety of environmental procarcinogens; perhaps 30% of DME substrates are able to be metabolically potentiated. Phase I DMEs, most of which represent cytochromes P450, metabolically activate procarcinogens to genotoxic electrophilic intermediates, and Phase II DMEs conjugate the intermediates to water-soluble derivatives, completing the detoxification cycle. It follows that genetic differences in the regulation, expression and activity of genes coding for Phase I and Phase II DMEs would be crucial factors in defining cancer susceptibility and the toxic or carcinogenic power of environmental chemicals. Not all Phase I and Phase II DMEs are implicated in detoxification; previous work from this and from other laboratories has identified candidate Phase I and Phase II genes in which certain alleles are more likely to be associated with cancer susceptibility. In some cases, the allelic frequencies vary dramatically between ethnic groups. In this review, our current knowledge about polymorphisms in the following genes are updated: the aromatic hydrocarbon receptor (AHR), the CYP1A1 structural gene (which encodes aryl hydrocarbon hydroxylase activity), the CYP1A2 structural gene (arylamine oxidations), the CYP2C19 gene (S-mephenytoin 4'-hydroxylase), the CYP2D6 gene (debrisoquine hydroxylase), the CYP2E1 gene (N,N-dimethylnitrosamine N-demethylase), the null mutant for the GSTM1 gene (glutathione transferase mu), and the NAT2 gene (arylamine N-acetyltransferase). If unequivocal biomarkers of genetic susceptibility to cancer and toxicity can be developed successfully, then identification of individuals at increased risk would be very helpful in the fields of public health and preventive medicine.
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PMID:Human drug-metabolizing enzyme polymorphisms: effects on risk of toxicity and cancer. 863 63

The effects of chronic administration of aflatoxin B1 (AFB1) on liver drug metabolism enzymes were measured in New Zealand rabbits divided into three groups of 5 animals, each receiving over 5 days either arabic gum or AFB1 in arabic gum at a daily oral dose of 0.05 or 0.10 mg/kg. These treatments did not lead to any lethality in any of the treated groups, but the body weight gain was altered. Biochemical exploration of plasma components revealed a dose-dependent hepatotoxicity characterized by cytolysis and cholestasis. At 0.10 mg/kd/day of AFB1, significant decreases were observed in total liver microsomal cytochrome P450, several P450-dependent monooxygenase activities, all individual P450 isoenzymes levels analysed by Western-blotting and glutathione S-transferase activities. By contrast, at 0.05 mg/kg/day of AFB1, even though total cytochrome P450 was decreased by 30%, only P450 1A1 and 3A6 isoenzymes, and aniline hydroxylation, pentoxyresorufin O-depentylation, aminopyrine, erythromycin, ethylmorphine and dimethylnitrosamine N-demethylations were affected. In the same animal group, the only glutathione S-transferase accepting CDNB (1-chloro-2,4-dinitrobenzene) as substrate was decreased by 22%. UDP-glucuronyltransferase accepting p-nitrophenol as substrate was increased in both groups of animals (33-62%). The mechanisms that could contribute to the observed changes in drug metabolizing enzymes are discussed.
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PMID:Dose-related effect of aflatoxin B1 on liver drug metabolizing enzymes in rabbit. 864 16

Statistically significant charge clusters (basic, acidic, or of mixed charge) in tertiary protein structures are identified by new methods from a large representative collection of protein structures. About 10% of protein structures show at least one charge cluster, mostly of mixed type involving about equally anionic and cationic residues. Positive charge clusters are very rare. Negative (or histidine-acidic) charge clusters often coordinate calcium, or magnesium or zinc ions [e.g., thermolysin (PDB code: 3tln), mannose-binding protein (2msb), aminopeptidase (1amp)]. Mixed-charge clusters are prominent at interchain contacts where they stabilize quaternary protein formation [e.g., glutathione S-transferase (2gst), catalase (8act), and fructose-1,6-bisphosphate aldolase (1fba)]. They are also involved in protein-protein interaction and in substrate binding. For example, the mixed-charge cluster of aspartate carbamoyl-transferase (8atc) envelops the aspartate carbonyl substrate in a flexible manner (alternating tense and relaxed states) where charge associations can vary from weak to strong. Other proteins with charge clusters include the P450 cytochrome family (BM-3, Terp, Cam), several flavocytochromes, neuraminidase, hemagglutinin, the photosynthetic reaction center, and annexin. In each case in Table 2 we discuss the possible role of the charge clusters with respect to protein structure and function.
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PMID:Clusters of charged residues in protein three-dimensional structures. 871 Aug 74

The vast majority of cancers arise as a consequence of exposure to environmental agents that are toxic or mutagenic. In response to this, all higher organisms have evolved complex mechanisms by which they can protect themselves from environmental challenge. In many cases, this involves an adaptive response in which the levels of expression of enzymes active in the metabolism and detoxification of the foreign chemical are induced. The best characterized of these enzyme systems are the cytochrome P450s, the GSTs and the NATs. An unfortunate consequence of many of these reactions, however, is the creation of a toxic or mutagenic reaction product from chemicals that require metabolic activation before realizing their full carcinogenic potential. Altered expression of one or more of these drug metabolizing enzymes can therefore be predicted to have profound toxicological consequences. Genetic polymorphisms with well defined associated phenotypes have now been characterized in P450, GST and NAT genes. Indeed, many of these polymorphisms have been associated with decreased or increased metabolism of many tumour promoters and chemical carcinogens and hence offer protection against or increased susceptibility to many distinct tumour types.
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PMID:Metabolic polymorphisms and cancer susceptibility. 871 12

Progress over the past 30 years has revealed many strengths of the rainbow trout as an alternative model for environmental carcinogenesis research. These include low rearing costs, an early life-stage ultrasensitive bioassay, sensitivity to many classes of carcinogen, a well-described tumor pathology, responsiveness to tumor promoters and inhibitors, and a mechanistically informative nonmammalian comparative status. Low-cost husbandry, for example, has permitted statistically challenging tumor study designs with up to 10,000 trout to investigate the quantitative interrelationships among carcinogen dose, anticarcinogen dose, DNA adduct formation, and final tumor outcome. The basic elements of the trout carcinogen bioassay include multiple exposure routes, carcinogen response, husbandry requirements, and pathology. The principal known neoplasms occur in liver (mixed hepatocellular/cholangiocellular adenoma and carcinoma, hepatocellular carcinoma), kidney (nephroblastoma), swim bladder (adenopapilloma), and stomach (adenopapilloma). Trout possess a complex but incompletely characterized array of cytochromes P450, transferases, and other enzymic systems for phase I and phase II procarcinogen metabolism. In general, trout exhibit only limited capacity for DNA repair, especially for removal of bulky DNA adducts. This factor, together with a high capacity for P450 bioactivation and negligible glutathione transferase-mediated detoxication of the epoxide, accounts for the exceptional sensitivity of trout to aflatoxin B1 carcinogenesis. At the gene level, all trout tumors except nephroblastoma exhibit variable and often high incidences of oncogenic Ki-ras gene mutations. Mutations in the trout p53 tumor suppressor gene have yet to be described. There are many aspects of the trout model, especially the lack of complete organ homology, that limit its application as a surrogate for human cancer research. Within these limitations, however, it is apparent that trout and other fish models can serve as highly useful adjuncts to conventional rodent models in the study of environmental carcinogenesis and its modulation. For some problems, fish models can provide wholly unique approaches.
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PMID:Fish models for environmental carcinogenesis: the rainbow trout. 872 7

Genetic polymorphisms with functional effects occur in many of the genes encoding drug metabolizing enzymes and are an important cause of adverse drug reaction. Recent advances in the understanding of the molecular genetics of drug-metabolizing enzymes, particularly the cytochromes P450, has enabled the molecular basis of several polymorphisms to be elucidated and genotyping assays using the polymerase chain reaction to be developed. Polymorphisms in this category include those in the cytochrome P450 genes CYP2D6, CYP2C19, CYP2A6, CYP2C9 and CYP2E1, the glutathione S-transferase genes GSTM1 and GSTT1 and the N-acetyltransferase gene NAT2. The molecular basis and importance to drug metabolism of the various polymorphisms as well as evidence for the existence of polymorphisms in other genes encoding drug-metabolizing enzymes such as the UDP-glucuronosyltransferases, the sulphotransferases and the methyltransferases are discussed.
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PMID:Molecular basis of polymorphic drug metabolism. 875 Nov 38

The objective of this work is to examine the possible modulation of carcinogen metabolism (activation by cytochrome P450s and detoxification by conjugation via glutathione S-transferases [GST]) in relation to hepatitis B virus (HBV)-associated liver injury. In HBV transgenic mouse lineage 107.5, the hepatitis B surface antigen (HBsAg) is expressed at noncytopathic concentrations but after injection of an HBsAg-specific, major histocompatibility complex (MHC) class I restricted cytotoxic T-lymphocyte (CTL) clone, the mice develop a severe acute necroinflammatory liver disease that reaches maximum severity within 3 days and gradually subsides during the next 2 to 3 weeks. In this model, using immunohistochemical analysis, we observed an increase of P450s (CYP1A and 2A5), both involved in aflatoxin B1, metabolism, but minor changes or no changes for others (2B, 2C, 2E, 3A). There was a fivefold decrease in the total liver P450 microsomal content 3 days' post-CTL injection with the result that the relative proportion of CYP2A5 and 1A compared with other P450s is increased. Individual microsomal P450 enzyme contents estimated by Western blotting; Northern blot analysis of liver CYP messenger RNA (mRNA) levels as well as in vitro metabolism of specific substrates for different P450 isoenzymes were consistent with the immunohistochemical data. Immunohistochemical staining with antibodies to cytosolic pi class GST was increased 1 and 3 days postinjection followed by a progressive decrease at later time points (the same phenomenon was observed to a lesser extent for GST alpha). The activity of hepatic cytosols toward substrates specific for different subclasses of GST (mu, pi, alpha) showed that while GST mu was not changed in the CTL-injected HBV transgenic mice, GST pi and, to a lesser extent, alpha were increased as compared with controls. These results suggest that liver cell injury induced by a process of acute fulminant-like hepatitis can lead to the induction of some carcinogen metabolizing enzymes notably, Cyp 1A, 2A5 and GST pi in the mouse.
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PMID:Differential induction of carcinogen metabolizing enzymes in a transgenic mouse model of fulminant hepatitis. 878 38

In recent years there has been considerable interest in the effect of variations in activities of xenobiotic-metabolizing enzymes on cancer incidence. This interest has accelerated with the development of methods for analyzing genetic polymorphisms. However, progress in epidemiology has been slow and the contributions of polymorphisms to risks from individual chemicals and mixtures are often controversial. A series of studies is presented to show the complexities encountered with a single chemical, aflatoxin B1 (AFB1). AFB1 is oxidized by human cytochrome P450 enzymes to several products. Only one of these, the 8,9-exo-epoxide, appears to be mutagenic and the others are detoxication products. P450 3A4, which can both activate and detoxicate AFB1, is found in the liver and the small intestine. In the small intestine, the first contact after oral exposure, epoxidation would not lead to liver cancer. The (nonenzymatic) half-life of the epoxide has been determined to be approximately 1 sec at 23 degrees C and neutral pH. Although the half-life is short, AFB1-8,9-exo-epoxide does react with DNA and glutathione S-transferase. Levels of these conjugates have been measured and combined with the rate of hydrolysis in a kinetic model to predict constants for binding of the epoxide with DNA and glutathione S-transferase. A role for epoxide hydrolase in alteration of AFB1 hepatocarcinogenesis has been proposed, although experimental evidence is lacking. Some inhibition of microsome-generated genotoxicity was observed with rat epoxide hydrolase; further information on the extent of contribution of this enzyme to AFB1 metabolism is not yet available.
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PMID:Involvement of cytochrome P450, glutathione S-transferase, and epoxide hydrolase in the metabolism of aflatoxin B1 and relevance to risk of human liver cancer. 878 83


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