EC:2.5.1.18 - FACTA Search

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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)

Glutathione transferase P (GST-P) is expressed at high levels in precancerous lesions and hepatocellular carcinomas from a very early stage of chemically-induced hepatocarcinogenesis in the rat. To explore the molecular mechanisms of its specific activation, we are investigating the regulation mechanisms of the GST-P gene expression. By using gene technology, we have identified a strong enhancer, GPEI, at 2.5 Kb and a silencer region at about 400 bp upstream from the transcription start site. GPEI has a palindromic structure composed of two TPA-responsive element (TRE)-like sequences and binds at least three proteins including AP-1 (c-jun/c-fos). The silencer is composed of several sequences resembling each other and binds at least three proteins including SF-B/LAP/LIP. To determine whether the GST-P gene is activated together with a putative hepato-oncogene because they are located close to each other (cis-mechanism), or because they share a trans-acting factor that can activate both genes simultaneously (trans-mechanism), transgenic rats were produced with GST-P control region connected to the CAT reporter. The results unequivocally demonstrate that GST-P gene is activated position-independently by a trans-mechanism.
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PMID:Complex regulation of a tumor marker expression. Enhancer and silencer of the GST-P gene. 130 2

Glutathione transferase P (GST-P) gene is specifically and highly activated during rat chemical hepatocarcinogenesis. We have previously cloned the GST-P gene and have identified putative regulatory regions. To further explore regulatory mechanisms, deletion constructs of the GST-P gene fused to the chloramphenicol acetyltransferase (CAT) structural gene were introduced into primary cultured rat hepatocytes by electroporation, and their activity was determined. The expression of the GST-P-CAT fusion gene is quite low in these cells as compared to that in both a rat fibroblast cell line, 3Y1 cells, and a rat hepatoma cell line, dRLh84. The presence of the strong enhancer GPEI did not elicit any enhancing activity at its original position, or when it was located 3' of the CAT gene, although this element does enhance CAT activity significantly when located adjacent to the promoter. Cotransfection of neither c-jun nor c-fos expression vector, nor both vectors, could enhance the CAT activity, even though GPEI consists of two phorbol ester response element-like sites. Furthermore, the expression of jun family gene was not correlated with GST-P gene expression either in primary cultured hepatocytes or in hepatoma cell lines.
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PMID:Analysis of glutathione transferase P gene regulation with liver cells in primary culture. 144 99

The differentiation status in cultures of primary rat liver parenchymal cells was determined by measuring the activities of various xenobiotic metabolizing enzymes. Most enzyme activities dropped rather rapidly in monocultures of parenchymal cells. The protein content and the activities of cytosolic epoxide hydrolase, glutathione S-transferase, and alpha-naphthol UDP-glucuronosyl transferase were, however, well stabilized in 7-day-old co-cultures of parenchymal cells with two different lines of rat liver nonparenchymal epithelial cells (NEC1 and NEC2). Phenol sulfotransferase and microsomal epoxide hydrolase activity were reduced in this coculture system after 7 days to about 30 and 20% of the initial activity. Generally, higher enzyme activities were measured in co-cultures with one specific epithelial cell line (NEC2) as compared to those with the other line (NEC1). C3H 10T1/2 mouse embryo fibroblasts supported the parenchymal cells even better than the two epithelial lines, because the activity of microsomal epoxide hydrolase was also stabilized. Glutathione transferase activity was increased over time in this co-culture system. Our results show that the differentiation status of liver parenchymal cells was much better stabilized in co-cultures than in monocultures but that, depending on the type of cells used for co-culture, great quantitative differences existed. The entire pattern of xenobiotic metabolizing enzyme activities could not be stabilized at the kind of levels found in freshly isolated parenchymal cells.
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PMID:Dependency of the in vitro stabilization of differentiated functions in liver parenchymal cells on the type of cell line used for co-culture. 158 94

Glutathione transferase mu activity, a marker for susceptibility to lung cancer and chemically induced cytogenetic damage, is not a predictive index for the predisposition to sulphonamide hypersensitivity reactions. However, considering the functional diversity and broad, overlapping substrate specificity of GSH-dependent enzymes, it is conceivable that an as yet unidentified deficiency in another GST isozyme or GSH-related enzyme may be a marker for sulphonamide toxicity. In addition, heterogeneity in cellular repair mechanisms and the diversity of the human immune response [22] may also contribute to the manifestation of the toxic effects of sulphonamides. Experiments are currently in progress to determine which of this myriad of variables is predominantly responsible for inter-individual susceptibility to the idiosyncratic reactions produced by these antibacterial agents.
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PMID:Glutathione transferase mu deficiency is not a marker for predisposition to sulphonamide toxicity. 185 71

Glutathione transferase (GST) activity in the cytosolic fractions of renal cortex tumour was found to be significantly lower (215 +/- 156 mU/mg) than that present in the corresponding non-tumour (466 +/- 278 mU/mg) tissues. Using the immunoblotting technique, glutathione transferase isoenzymes expression in both tumour and non-tumour kidney was investigated. Alpha and pi class glutathione transferases were the most abundant enzymes in non-tumour kidney and were expressed by all samples investigated. Immunofluorescence analysis indicated that the pi class enzymes are localized mainly in the distal convoluted tubules, whereas alpha class enzymes are localized in the proximal tubules. In the tumour moiety the alpha class GST appears to be absent or expressed at low level as compared with non-tumour samples. On the contrary, no significant differences in the expression of pi class GST were found in tumour as compared with non-tumour tissues. Mu class GST protein was detected in 12 of 26 samples tested. When present, mu class GST constitutes a few per cent of total GST protein. Immunofluorescence studies indicate that mu class GSTs are localized within the distal convoluted tubules. According to the electrophoretic mobility at least two different mu GST subunits (26.5 and 27.5 kd) were found. In one sample only the faster mu class GST subunit was present, two samples expressed both types of GST subunits, whereas nine samples expressed only the slower GST subunit. With the exception of one sample, a reduction of mu class GST expression was seen in tumour as compared with non-tumour tissues. The decrease of activity seen in the cytosolic fraction of tumour kidney must be ascribed mainly to a reduction or to a lack of expression of alpha class GST and to a lesser extent of mu class GST.
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PMID:Glutathione transferase isoenzymes in normal and neoplastic human kidney tissue. 186 Jan 68

Glutathione transferase (GST) epsilon (also known as GST2 or GST B1B1), the major Class Alpha GST in human liver has been subjected to oligonucleotide-directed site-specific mutagenesis. Four arginine residues, R13, R20, R69 and R187, of which all but R69 are strictly conserved through GST Classes Alpha, Mu and Pi have been replaced by Ala. The mutant enzymes have been expressed in Escherichia coli, purified by affinity chromatography and characterised. Compared with the wild-type enzyme, all mutant GSTs had altered catalytic properties. All mutants had decreased specific activity with 1-chloro-2,4-dinitrobenzene (CDNB). Mutants R13A, R69A and R187A also showed decreased activities with other substrates such as cumene hydroperoxide (CuOOH) and androstenedione. In contrast, mutant R20A had an increased peroxidase activity and an isomerase activity essentially the same as that of the wild-type GST. With the substrates used, kcat./Km values were decreased for all mutant GSTs. Increases in the [S0.5] values were most significant for glutathione (GSH), while values for CDNB and CuOOH were less markedly affected. Thus, various kinetic data indicate that the GSH affinity has been reduced by the mutations and that this loss of affinity is linked to the decreased specific activities. Inhibition studies showed an increased sensitivity towards S-hexyl-GSH; this was particularly marked for mutant R69A. Mutant R20A had a lowered [I50] value but, in contrast, also the highest [I80] value as compared with the wild-type enzyme. Towards bromosulphophthalein, mutants R20A and R69A had a markedly increased sensitivity, about 35-fold in comparison with the wild-type. The inhibition properties of mutant R187A were similar to those of the wild-type enzyme and the properties of mutant R13A were in between. The increased sensitivity to S-hexyl-GSH, in contrast with the decreased affinity for GSH, was suggested to be due to an altered distribution between conformational states of the enzyme induced by the mutations. The arginine residues in positions 13, 20 and 69 all seem to be important for the catalytic properties of GST. Further, the inhibition studies indicate a role of arginine residues in the stabilisation of conformational states of the enzyme.
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PMID:Effects of directed mutagenesis on conserved arginine residues in a human Class Alpha glutathione transferase. 200 17

Glutathione transferase (GST) enzymes are toxicologically important from many points of view. Nine protozoans were investigated here for their GST content. Six aerobic amoebae had very different specific GST activities, but an anaerobic amoeba and two anaerobic flagellates did not have any GST activity, suggesting that the peroxidase activity of GST is an evolutionarily important property for aerobic organisms. The soluble GST isoenzymes of Acanthamoeba culbertsoni and A. polyphaga were purified and partially characterized. The same two cationic and one anionic GST isoenzyme were found in both Acanthamoeba ssp., while A. culbertsoni had one more cationic isoenzyme. It is concluded that GST in aerobic amoebae can play an important role in detoxication.
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PMID:Glutathione transferase activity in some flagellates and amoebae, and purification of the soluble glutathione transferases from Acanthamoeba. 207 88

The effect of hypophysectomy and subsequent treatment with adrenocorticotropic hormone (adrenocorticotropin, ACTH) on the isoenzymes of glutathione transferase in the rat adrenal gland was investigated. A large increase (approx. 11-fold) in the level of transferase subunit 4 was observed in hypophysectomized animals by immunoblotting. When the activity of glutathione transferase 4-4 was measured in adrenal cytosol using trans-stilbene oxide as a selective substrate, a 15-fold increase was noted. Lack of the pituitary hormone ACTH is apparently related to this increase, since treatment of hypophysectomized animals with ACTH for 2 weeks partially down-regulated subunit 4. Glutathione transferase subunits 3 and 8 in the adrenal were also increased in amount by hypophysectomy, but not at all to the same extent. The activity of glutathione transferase 4-4 was elevated also in the liver and ovary (5 and 1.5 times respectively) after hypophysectomy. These elevated enzyme levels were, however, not affected by ACTH treatment. This down-regulation of glutathione transferases in the rat adrenal by ACTH may be related to the fact that, under normal conditions, this organ is highly susceptible to the toxic effects of various polycyclic hydrocarbons, whereas under circumstances where there is no ACTH production, as in hypophysectomized rats, the adrenal is resistant to these same hydrocarbons.
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PMID:Increase in the amount of glutathione transferase 4-4 in the rat adrenal gland after hypophysectomy and down-regulation by subsequent treatment with adrenocorticotrophic hormone. 215 79

1. The activities of microsomal glucuronyltransferase and thiomethyltransferase, and those of cytosolic sulphotransferase, acetyltransferase, glutathione transferase and thiomethyltransferase were measured in abnormal (cirrhosis and chronic hepatitis) and normal livers. 2. Glucuronyltransferase and sulphotransferase were investigated with 2-naphthol and ethinyloestradiol as substrates. p-Aminobenzoic acid, benzo(a)pyrene-4,5-epoxide and 2-mercaptoethanol were the substrates of acetyltransferase, glutathione transferase and thiomethyltransferase, respectively. 3. Enzyme activities are expressed as nmol min-1 incubation mg-1 protein and the averages (+/- s.d.) are given. With 2-naphthol as substrate, the glucuronyltransferase activity was 6.55 +/- 4.10 (abnormal liver, n = 33) and 7.81 +/- 4.02 (normal liver, n = 26) (NS); whereas sulphotransferase activity was 0.28 +/- 0.18 (abnormal liver, n = 35) and 0.68 +/- 0.43 (normal liver, n = 26) (P less than 0.01). Glucuronyltransferase activity towards ethinyloestradiol was 102.5 +/- 56.9 (abnormal liver, n = 30) and 107 +/- 59.9 (normal liver, n = 26) (NS), whereas sulphotransferase activity was 57.2 +/- 36.0 (abnormal liver, n = 35) and 122 +/- 67.6 (normal liver, n = 28) (P less than 0.01). Acetyltransferase activity was 0.84 +/- 0.83 (abnormal liver, n = 35) and 3.84 +/- 1.65 (normal liver, n = 26) (P less than 0.01). Glutathione transferase activity was 0.83 +/- 0.68 (abnormal liver, n = 35) and 2.90 +/- 1.59 (normal liver, n = 25) (P less than 0.01) and thiomethyltransferase activity was 1.00 +/- 0.69 (abnormal liver, n = 34) and 3.99 +/- 1.49 (normal liver, n = 25) (P less than 0.01). 4. Liver disease lowers the activities towards the substrates studied of sulphotransferase, acetyltransferase, glutathionetransferase and thiomethyltransferase but not that of glucuronyltransferase.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Conjugation pathways in liver disease. 222 21

Glutathione transferase, glyoxalase I and glyoxalase II activities were not evenly distributed among the major helminth groups. Intestinal cestodes and digeneans had higher glutathione transferase activity than parasitic nematodes. High glyoxalase II activity was found in cestodes and digeneans but no glyoxalase I was detectable. Glyoxalase I and II were both detected in nematodes. These results are discussed in relation to the enzymes' suggested role in protection against secondary lipid peroxidation products.
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PMID:Relative distribution of glutathione transferase, glyoxalase I and glyoxalase II in helminths. 233 83

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