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)

In 6 normal rabbits, the aortic arch, the descending thoracic and the abdominal aorta were tested for non proteic thiol compounds, selenium-dependent and selenium-independent glutatione peroxidase, glutatione reductase, glutatione transferase and thiobarbituric acid reactive substances. The aortic arch showed the greatest content of non proteic thiol compounds and thiobarbituric acid reactive substances, associated to the highest activities of glutathione-related enzymes. However, not significant differences were detectable between aortic arch and descending thoracic aorta, except for the glutathione transferase activity (0.395 +/- 0.031 vs 0.330 +/- 0.053 U/mg protein, p less than 0.05). Furthermore, both aortic arch and descending thoracic aorta showed significantly higher values of non proteic thiol compounds (46.05 +/- 10.15% and 33 +/- 13.5%, p less than 0.05), selenium-dependent glutathione peroxidase activity (70.35 +/- 26% and 54.3 +/- 9.5%, p less than 0.05), glutathione reductase activity (25.4 +/- 7% and 18.4 +/- 4.5%, p less than 0.05) and thiobarbituric acid reactive substances (65.8 +/- 18% and 47.2 +/- 17%, p less than 0.05) with respect to the abdominal aorta. The selenium-independent glutathione peroxidase activity was not detectable. In conclusion, a biochemical gradient in glutathione-related antioxidant defences and thiobarbituric acid reactive substances proceeding from the proximal to the distal segments seems to exist in the normal rabbit aorta. These results could contribute to explain the non homogeneous distribution of experimental atherosclerosis in the rabbit aorta.
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PMID:Regional distribution of glutathione-related antioxidant defences in the normal rabbit aorta. 204 54

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

Immunohistochemical localization of glutathione S-transferase (GST) and enzyme cytochemical staining for endogenous peroxidase (Px) activity were studied in rat uteri. Both enzymes were clearly detected in the endometrium of the uterus taken from proestrus to estrus during the estrous cycle. Based on our data, the biological significance of GST in endometrium was discussed.
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PMID:Immunolocalization of glutathione S-transferase in the rat uterus. 208 2

The antioxidant enzymatic defense of insects for the regulation of oxygen toxicity was investigated. Insect species examined were lepidopterous larvae of the cabbage looper (Trichoplusia ni), southern armyworm (Spodoptera eridania), and black swallowtail (Papilio polyxenes). These phytophagous species are subject to both endogenous and exogenous sources of oxidative stress from toxic oxygen radicals, hydrogen peroxide (H2O2) and lipid peroxides (LOOH). In general, the constitutive levels of the enzymes superoxide dismutase (SOD), catalase (CAT), glutathione transferase (GT), and its peroxidase activity (GTpx), and glutathione reductase (GR), correlate well with natural feeding habits of these insects and their relative susceptibility to prooxidant plant allelochemicals, quercetin (a flavonoid), and xanthotoxin (a photoactive furanocoumarin). Induction of SOD activity which rapidly destroys superoxide radicals, appears to be the main response to dietary prooxidant exposure. A unique observation includes high constitutive activity of CAT and a broader subcellular distribution in all three insects than observed in most mammalian species. These attributes of CAT appear to be important in the prevention of excessive accumulation of cytotoxic H2O2. Unlike mammalian species, insects possess very low levels of a GPOX-like activity toward H2O2. Irrefutable proof that this activity is due to a selenium-dependent GPOX found in mammals, is lacking at this time. However, the activity of selenium-independent GTpx is unusually high in insects, suggesting that GTpx and not GPOX plays a prominent role in scavenging deleterious LOOHs. The GSSG generated from the GPOX and GTpx reactions may be reduced to GSH by GR activity. A key role of SOD in protecting insects from prooxidant toxicity was evident when its inhibition resulted in enhanced toxicity towards prooxidants. The role of antioxidant compounds in protecting these insects from toxic forms of oxygen has not been explored in depth. A major finding, however, is that these insects are lutein accumulators. Lutein is a dihydroxy (diol) derivative of beta-carotene, and it is a good quencher of activated forms of oxygen and free radicals. Levels of lutein are highest in P. polyxenes which specializes in feeding on prooxidant-containing plants.
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PMID:Mechanisms for regulating oxygen toxicity in phytophagous insects. 219 43

After twenty years, understanding the mechanisms of tumor cells kill by anthracyclines still remains an active area of research. Of many mechanisms described for this class of drugs, efforts in the last year have focused on defining the role of free radical formation, topoisomerase II-induced DNA breakage, and P-170-dependent cellular accumulation of anthracyclines in tumor cell kill and resistance. First, in a number of tumor cell lines, the formation of free radical species from anthracyclines has been implicated in the cell killing. Modulation of detoxification pathways in a drug-resistant cell line e.g depletion of GSH, a substrate for peroxidase and transferase, enhanced both the formation of oxy-radicals and adriamycin cytotoxicity. It should be noted, however, that these findings are not true for every cell line examined, and free radical-mediated tumor kill may be cell- or tissue-specific. Second, anthracyclines-mediated topo II-dependent DNA cleavage was observed in most cell lines and reduced breaks were found in resistant cells. The decrease in single-strand breaks, however, neither correlated with the degree of resistance nor with differences in the relative topo II activity, which was in most cases only two-fold less in resistant cells than in sensitive cells. Finally, the reduced accumulation of the drug does not appear to be the only contributing factor in multidrug resistant cells and P-170 is not the only protein overexpressed in certain cells, e.g., an 85,000 Da protein may also be linked to adriamycin resistance. Although GST protein is overexpressed in most adriamycin resistant cells along with mdr1 gene, current evidence suggests that this protein may not be directly involved in adriamycin resistance. Taken together, both the mechanism of action and resistance to this class of drug likely vary among cell lines. Clinical studies in the past year have brought about interesting refinements in anthracycline-containing chemotherapy; ICRF-187 (by itself also cytotoxic) seems to offer protection against cardiac toxicity, while implicating iron in the mediation of cardiac damage. Out of a large number of newer anthracycline derivatives, clinical evidence indicates only a modest increase in therapeutic index with a few analogs, perhaps idarubicin and epirubicin. It is not yet clear that being able to receive more milligrams (or more cycles) of anthracycline eventually translates into a significantly better response rate or in a survival advantage. Much less clear is whether patients refractory to adriamycin may derive any benefit from newer anthracyclines.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Anthracyclines. 222 2

We have previously described a colorimetric test, designated an amplified DNA assay (ADA), for specific segments of DNA amplified by polymerase chain reactions (PCRs), suited to diagnostic applications. This relied on binding the amplified DNA via a sequence in one oligodeoxyribonucleotide (oligo) to the DNA-binding protein GCN4 coated on the wells of a microtiter dish. Avidin-peroxidase was then bound to biotin at the 5' end of the other oligo and detected colorimetrically. Two successive PCRs with nested oligos were utilized. We describe here several modifications that greatly simplify the ADA. First, we bind the DNA to a glutathione S-transferase-GCN4 fused polypeptide (GST-GCN4) and avidin-peroxidase simultaneously, rather than successively. Second, we carry out the two successive PCRs in the one reaction mixture, using the thermal stabilities of oligos of differing lengths to separate the two reactions. Third, PCRs can be performed in the wells of a microtiter dish and the amplified DNA captured and detected via GST-GCN4 immobilized on beads attached to the lid of the microtiter dish. Hence it is only necessary to pipette the DNA sample once, and up to 96 samples can then be handled simultaneously.
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PMID:Simplified colorimetric analysis of polymerase chain reactions: detection of HIV sequences in AIDS patients. 225 54

Glutathione S-transferases play a central role in drug detoxification and have been implicated in the sensitivity of tumour cells to anticancer drugs. In this study, glutathione S-transferase (GST) isozyme expression in normal and tumour tissue from human lung, colon, stomach, breast, kidney and liver tissue has been quantified using sensitive and subunit specific radioimmunoassays (RIA), together with Western blot analysis and measurement of substrate metabolism. Glutathione S-transferase pi was the predominant GST in the majority of the tumours examined. The concentration of this enzyme was increased significantly in tumour tissue relative to normal lung, colon, and stomach tissue. A strong correlation was observed (r = 0.77, P less than 0.01) between GST activity and GST pi levels in those tumour samples. The concentrations of the alpha class GST, the predominant isoenzymes in normal stomach, kidney and liver, decreased dramatically in tumour tissue from these organs. Western blot analysis revealed the presence of novel polypeptides that cross-reacted with antisera raised against alpha and mu class GST. Our data demonstrates that although GST pi is the predominant GST isoenzyme in many tumours, significant levels of the other GST subunits are also present and collectively can represent a significant proportion of the GST content. Therefore the properties of all the GST isoenzymes need consideration when assessing the role of these proteins in drug resistance. Selenium-dependent glutathione peroxidase, an enzyme activity also implicated in the mode of action of certain antitumour agents, was also studied and shown to be the predominant glutathione-dependent peroxidase in all tumours except the hepatoma.
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PMID:Glutathione S-transferase and glutathione peroxidase expression in normal and tumour human tissues. 231 Nov 89

Perfusion of the bovine eye with a buffer solution containing t-butyl hydroperoxide and the glutathione reductase inhibitor nitrofurantoin caused significant decreases in reduced glutathione level in ciliary body and iris. The result was interpreted to suggest that the organic hydroperoxide was decomposed by the glutathione peroxidase-reductase system. The glutathione reductase reaction requires NADPH. Since the level of NADPH is maintained by the hexose monophosphate shunt in many tissues, we investigated whether this is also the case with bovine uveal tissues. CO2 formation from [1-14C]glucose but not from [6-14C]glucose was markedly stimulated by t-butyl hydroperoxide and was inhibited by the glutathione reductase inhibitor 1,3-bis(2-chloroethyl)-1-nitrosourea, thus supporting the importance of the hexose monophosphate shunt for hydroperoxide decomposition through the glutathione peroxidase-reductase system. The peroxidase-reductase activity was found both in non-pigmented and pigmented ciliary epithelial cells in culture. Purification studies isolated two forms of glutathione reductase [GR I (140 kDa) with subunit Mr of 70 kDa and GR II (greater than 670 kDa) with subunit Mr of 45 kDa] and a novel glutathione peroxidase (112 kDa with subunit Mr of 29 kDa). The peroxidase is active both with H2O2 and organic hydroperoxides, does not contain selenium and shows no glutathione S-transferase activity.
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PMID:Glutathione-dependent detoxification of peroxide in bovine ciliary body. 237 73

A simple and sensitive method for the simultaneous visualization of glutathione peroxidase and catalase on polyacrylamide gels is described. The procedure included: (1) running samples on a 7.5% polyacrylamide gel, (2) soaking the gel in a certain concentration of reduced glutathione (0.25-2.0 mM), (3) soaking the gel in GSH plus H2O2 or cumene hydroperoxide, (4) finally staining with a 1% ferric chloride 1% potassium ferricyanide solution. The best concentration of glutathione for simultaneous visualization of glutathione peroxidase in mouse liver homogenates and also it is specific for glutathione peroxidase since other peroxidases such as lactoperoxidase, horseradish peroxidase and glutathione S-transferase cannot be visualized. Using this method, it was found that unlike catalase, glutathione peroxidase is heat resistant (68 degrees C, 1 min), but sensitive to 10 mM sodium iodoacetate.
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PMID:A simultaneous visualization of the antioxidant enzymes glutathione peroxidase and catalase on polyacrylamide gels. 246 58

Glutathione peroxidase and glutathione S-transferase both utilize glutathione (GSH) to destroy organic hydroperoxides, and these enzymes are thought to serve an antioxidant function in mammalian cells by catalyzing the destruction of lipid hydroperoxides. Only two groups of procaryotes, the purple bacteria and the cyanobacteria, produce GSH, and we show in the present work that representatives from these two groups (Escherichia coli, Beneckea alginolytica, Rhodospirillum rubrum, Chromatium vinosum, and Anabaena sp. strain 7119) lack significant glutathione peroxidase and glutathione S-transferase activities. This finding, coupled with the general absence of polyunsaturated fatty acids in procaryotes, suggests that GSH-dependent peroxidases evolved in eucaryotes in response to the need to protect against polyunsaturated fatty acid oxidation. A second antioxidant function of GSH is mediated by glutathione thioltransferase, which catalyzes the reduction of various cellular disulfides by GSH. Two of the five GSH-producing bacteria studied (E. coli and B. alginolytica) produced higher levels of glutathione thioltransferase than found in rat liver, whereas the activity was absent in the other three species studied. The halobacteria produce gamma-glutamylcysteine rather than GSH, and assays for gamma-glutamylcysteine-dependent enzymes demonstrated an absence of peroxidase and S-transferase activities but the presence of significant thioltransferase activity. Based upon these results it appears that GSH and gamma-glutamylcysteine do not function in bacteria as antioxidants directed against organic hydroperoxides but do play a significant, although not universal, role in maintaining disulfides in a reduced state.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Evolution of antioxidant mechanisms: thiol-dependent peroxidases and thioltransferase among procaryotes. 251 92


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