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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 the present study, the enzymatic conjugation of the isoprene monoepoxides 3,4 epoxy-3-methyl-1-butene (EPOX-I) and 3,4-epoxy-2-methyl-1-butene (EPOX-II) with glutathione was investigated, using purified glutathione S-transferases (GSTs) of the alpha, mu, pi and theta-class of rat and man. HPLC analysis of incubations of EPOX-I and EPOX-II with [35S]glutathione (GSH) showed the formation of two radioactive fractions for each isoprene monoepoxide. The structures of the EPOX-I and EPOX-II GSH conjugates were elucidated with 1H-NMR analysis. As expected, two sites of conjugation were found for both isoprene epoxides. EPOX-II was conjugated more efficiently than EPOX-I. In addition, the mu and theta class glutathione S-transferases were much more efficient than the alpha and pi class glutathione S-transferases, both for rat and man. Because the mu- and theta-class glutathione S-transferases are expressed in about 50 and 40-90% of the human population, respectively, this may have significant consequences for the detoxification of isoprene monoepoxides in individuals who lack these enzymes. Rat glutathione S-transferases were more efficient than human glu tathione S-transferases: rat
GST T1
-1 showed about 2.1-6.5-fold higher activities than human
GST T1
-1 for the conjugation of both EPOX-I and EPOX-II, while rat
GST
M1-1 and
GST
M2-2 showed about 5.2-14-fold higher activities than human
GST
M1a-1a. Most of the glutathione S-transferases showed first order kinetics at the concentration range used (50-2000 microM). In addition to differences in activities between
GST
-classes, differences between sites of conjugation were found. EPOX-I was almost exclusively conjugated with glutathione at the C4-position by all glutathione S-transferases, with exception of rat
GST
M1-1, which also showed significant conjugation at the C3-position. This selectivity was not observed for the conjugation of EPOX-II. Incubations with EPOX-I and EPOX-II and hepatic S9 fractions of mouse, rat and man, showed similar rates of GSH conjugation for mouse and rat. Compared to mouse and rat, human liver S9 showed a 25-50-fold lower rate of GSH conjugation.
...
PMID:Conjugation of isoprene monoepoxides with glutathione, catalyzed by alpha, mu, pi and theta-class glutathione S-transferases of rat and man. 1019 May 41
This study investigated whether or not the genotypes
glutathione S-transferase
theta (
GST T1
) and mu (
GST
M1) correlated with low white blood cell (WBC) count found in benzene exposed workers. We found that individuals with genotypes positive for both
GST T1
and
GST
M1 showed the highest prevalence of low WBC [odds ratio (OR) = 4.67, P = 0.046, 95% confidence interval (CI) = 1.02-24.15] when the benzene exposure was high. Multiple logistic regression showed that benzene exposure (OR = 2.81, P = 0.062, 95% CI = 0.96-8.30) was associated with increased OR on low WBC and interactions between the benzene exposure and the genotype of
GST T1
were also observed. These observations suggest that
GST T1
and
GST
M1 may play important roles in the biotransformation of benzene, the effect which leads to its hematotoxicity.
...
PMID:Glutathione S-transferase (GST) M1 and GST T1 genotypes and hematopoietic effects of benzene exposure. 1035 Jan 87
Workers in epoxy resin, synthetic leather, and printed circuit board manufacturing plants are exposed to epichlorohydrin (ECH), or dimethylformamide (DMF), or both. ECH, an alkylating agent, has been shown to cause malignancy in animals, but its genotoxicity in humans is unclear. DMF is a well-known hepatotoxic chemical, although evidence of its genotoxicity in humans is also limited. In this study, we examined the effects of exposure to ECH and DMF on sister chromatid exchange (SCE) in plant workers, in order to examine the genotoxicity of these two agents. Because the genotoxicity of certain agents can be modulated by metabolic traits, we also investigated influence of the
glutathione S-transferase
(
GST
) micro (
GST
M1) and
GST
theta (
GST T1
) genes on the genotoxicity of ECH and DMF. A total of 85 male plant workers were included in this study. The subjects were divided into five exposure groups, based on their job titles and the airborne ECH and DMF concentrations in their areas of work. A questionnaire was administered to obtain detailed occupational, smoking, alcohol consumption, and medication histories. Standardized cytogenetic methods were used to determine the frequency of sister chromatid exchange (SCE) in peripheral blood lymphocytes.
GST
M and
GST T1
genotypes were identified using polymerase chain reaction (PCR). In analysis, smoking was significantly associated with increased SCE frequency (P<0.01). Workers with high ECH exposure also had significantly higher SCE frequencies than those with low or no ECH exposure (P<0.05). However, DMF exposure was not associated with SCE frequency. The
GST
M1 null genotype was also found to be associated with an increased SCE frequency (P = 0.06). We conclude that ECH exposure may be associated with genetic toxicity and that DMF does not appear to be genotoxic.
...
PMID:Exposure to epichlorohydrin and dimethylformamide, glutathione S-transferases and sister chromatid exchange frequencies in peripheral lymphocytes. 1046 95
Polymorphisms within the phase II metabolizer enzymes
GST T1
,
GST
M1 and
GST
P1 affect the body's ability to detoxify a range of potential leukaemogens encountered in the environment. Using PCR,
GST T1
,
GST
M1 and
GST
P1 genotypes were determined in 557 adults with acute leukaemia and 952 age, sex and geographically matched controls. The strongest association with acute leukaemia was observed for the
GST T1
null genotype, which occurred among 19% of cases and 14% of controls [odds ratio (OR) 1.45, 95% confidence interval (CI) 1.09-1.93]. A slightly higher proportion of cases (53%) than controls (49%) displayed the
GST
M1 null genotype, although the difference was not statistically significant (OR 1.22, 95% CI 0.98-1.52). No effect was observed for the
GST
P1 genotype and no interaction between the
GST T1
and
GST
M1 genotypes was evident. Acute myeloid leukaemia (AML) was weakly associated with both
GST T1
null (OR 1.32, 95% CI 0.97-1.79) and
GST
M1 null (OR 1. 24, 95% CI 0.98-1.56), whereas acute lymphoblastic leukaemia (ALL) was associated with
GST T1
null (OR 3.28, 95% CI 1.31-8.26). No associations between smoking and disease risk in relation to
GST T1
and
GST
M1 polymorphic status were found.
...
PMID:Polymorphic variation within the glutathione S-transferase genes and risk of adult acute leukaemia. 1060 32
The aim of the present study was to investigate how the genetic polymorphism in
glutathione transferase T1
(GSTT1) affects the metabolism and disposition of methyl chloride in humans in vivo. The 24 volunteers (13 males and 11 females) who participated in the study were recruited from a group of 208 individuals previously phenotyped for GSTT1 by measuring the
glutathione transferase
activity with methyl chloride in lysed erythrocytes ex vivo. Eight individuals with high (+/+), eight with medium (+/0) and eight with no (0/0) GSTT1 activity were exposed to methyl chloride gas (10 p.p.m.) in an exposure chamber for 2 h. Uptake and disposition was studied by measuring the concentration of methyl chloride in inhaled air, exhaled air and blood. A two-compartment model with two elimination pathways corresponding to exhalation and metabolism was fitted to experimental data. The average net respiratory uptake of methyl chloride was 243, 158, and 44 micromol in individuals with high, intermediate and no GSTT1 activity, respectively. Metabolic clearance was high (4.6 l/min) in the +/+ group, intermediate (2.4 l/min) in the +/0 group, and close to zero in 0/0 individuals, while the exhalation clearance was similar in the three groups. No exposure related increase in urinary S-methyl cysteine was detected. However, gender and the GSTTl phenotype seemed to affect the background levels. In conclusion, GSTT1 appears to be the sole determinant of methyl chloride metabolism in humans. Thus, individuals with nonfunctional GSTT1 entirely lack the capacity to metabolize methyl chloride.
...
PMID:Glutathione transferase T1 phenotype affects the toxicokinetics of inhaled methyl chloride in human volunteers. 1103 5
The overall objective of this study was to evaluate a continuum of biomarkers in blood and urine for their sensitivities as indicators of low level occupational exposures to 1,3 butadiene (BD). The study design was largely cross-sectional, with biological samples collected within a short timeframe. Personal 8-h BD exposure measures were made on several occasions over a 60-day period for each potentially exposed worker in order provide maximum accuracy for this independent variable and to accommodate the different expression intervals of the several biomarkers. Co-exposures to styrene, toluene and benzene were also measured. The study included 24 BD monomer production workers (mean BD exposure=0.642 mg/m(3)), 34 polymerization workers (mean BD exposure=1.794 mg/m(3)) and 25 controls (mean BD exposure=0.023 mg/m(3)). The several biomarkers were measured by a consortium of investigators at different locations in the US and Europe. These biomarkers included: (1) metabolic genotypes (CYP2E1, EH,
GST
M1,
GST T1
, ADH2, ADH3), determined in Prague and Burlington, VT; (2) urinary M1 and M2 metabolites (1,2-dihydroxy-4-[N-acetylcysteinyl]-butane and 1-hydroxy-2-[N-acetylcysteinyl]-3-butene, respectively), determined in Albuquerque, NM and Leiden; (3) hemoglobin adducts (N-[2-dihydroxy-3-butenyl]valine=HBVal and N-[2,3,4-trihydroxybutyl]valine=THBVal), determined in Amsterdam and Chapel Hill, NC, respectively; (4) HPRT mutations determined by autoradiographic assay in Galveston, TX, with slides re-read in Burlington, VT; (6) hypoxanthine-guanine phosphoribosyltransferase (HPRT) mutations determined by cloning assay in Leiden with mutational spectra characterized in Burlington, VT; (7) sister chromatid exchanges and chromosome aberrations determined by standard methods and FISH analysis in Prague. Urinary M1 and M2 metabolites and HBVal and THBVal hemoglobin adducts were all significantly correlated with BD exposure levels, with adducts being the most highly associated. No significant relationships were observed between BD exposures and HPRT mutations or any of the cytogenetic endpoints, regardless of method of assay.
...
PMID:Biomarkers for assessing occupational exposures to 1,3-butadiene. 1139 5
In the inductive phase of contact allergic dermatitis, simple chemical compounds (haptens) produce together with epidermic proteins adducts presented by Langerhans cells to T lymphocytes. Binding to protein carrier is a necessary condition of transforming a low-molecular allergen into immunogenic one and evoking immunological reaction. The production of allergen adducts with proteins is conditioned by the presence of electrophilic groups in their molecules, or their acquiring during biotransformation phase I. Active allergen metabolites undergo further alterations during biotransformation phase II which leads most frequently to the decline in their chemical activity and more rapid excretion from the body. The number of reactive metabolites (reactive allergens) available for producing adducts with proteins keeps the balance between activation and deactivation reactions. Glutathione S-transferases play a particular role in the allergens (or their metabolites) deactivation process in biotransformation phase II. These enzymes catalyse reactions responsible for the declined electrophilic potential of allergens (or their metabolites), and thus for the decrease in the number of allergen molecules able to produce protein covalent bindings (adducts). Glutathione S-transferases, occurring in the human cellular cytoplasm belong to five classes: alpha(
GST
A), mu(
GST
M), theta(
GST
P), pi(
GST
T) and Z(
GST
Z), as well as to one class present in microsomes. The study indicated the presence of isoenzymes
GST T1
and
GST
M1 in the skin. Both isoforms participate in the process of low-molecular allergen biotransformation. Carriers of defective genes
GST T1
and/or
GST
M1 are more vulnerable to allergenic effect of some allergens, e.g. thimerosal, which is associated with the absence of or decrease in the activity of isoenzymes
GST T1
and
GST
M1.
...
PMID:[Genetic polymorphism of glutathione s-transferase as a factor predisposing to allergic dermatitis]. 1142 48
Methylobacterium dichloromethanicum DM4 is able to grow with dichloromethane as the sole carbon and energy source by using a dichloromethane dehalogenase/
glutathione S-transferase
(
GST
) for the conversion of dichloromethane to formaldehyde. Mammalian homologs of this bacterial enzyme are also known to catalyze this reaction. However, the dehalogenation of dichloromethane by
GST T1
-1 from rat was highly mutagenic and toxic to methylotrophic bacteria. Plasmid-driven expression of rat
GST T1
-1 in strain DM4-2cr, a mutant of strain DM4 lacking dichloromethane dehalogenase, reduced cell viability 10(5)-fold in the presence of dichloromethane. This effect was exploited to select dichloromethane-resistant transconjugants of strain DM4-2cr carrying a plasmid-encoded rGSTT1 gene. Transconjugants that still expressed the
GST T1
protein after dichloromethane treatment included rGSTT1 mutants encoding protein variants with sequence changes from the wild-type ranging from single residue exchanges to large insertions and deletions. A structural model of rat
GST T1
-1 suggested that sequence variation was clustered around the glutathione activation site and at the protein C-terminus believed to cap the active site. The enzymatic activity of purified His-tagged
GST T1
-1 variants expressed in Escherichia coli was markedly reduced with both dichloromethane and the alternative substrate 1,2-epoxy-3-(4'-nitrophenoxy)propane. These results provide the first experimental evidence for the involvement of Gln102 and Arg107 in catalysis, and illustrate the potential of in vivo approaches to identify catalytic residues in GSTs whose activity leads to toxic effects.
...
PMID:Dichloromethane mediated in vivo selection and functional characterization of rat glutathione S-transferase theta 1-1 variants. 1145 94
Glutathione (GSH) transferases are generally involved in the detoxication of xenobiotic chemicals. However, conjugation can also activate compounds and result in DNA modification. Activation of 1,2-dihaloethanes (BrCH(2)CH(2)Br, BrCH(2)CH(2)Cl, and ClCH(2)CH(2)Cl) was investigated using two mammalian theta class GSH transferases (rat
GST
5-5 and human
GST T1
) and a bacterial dichloromethane dehalogenase (DM11). Although the literature suggests that the bacterial dehalogenase does not catalyze reactions with CH(3)Cl, ClCH(2)CH(2)Cl, or CH(3)CHCl(2), we found a higher enzyme efficiency for DM11 than for the mammalian GSH transferases in conjugating CH(3)Cl, CH(3)CH(2)Cl, and CH(3)CH(2)Br. Enzymatic rates of activation of 1,2-dihaloethanes were determined in vitro by measuring S,S-ethylene-bis-GSH, the major product trapped by nonenzymatic reaction with the substrate GSH. Salmonella typhimurium TA 1535 systems expressing each of these GSH transferases were used to determine mutagenicity. Rates of formation of S,S-ethylene-bis-GSH by the GSH transferases correlated with the mutagenicity determined in the reversion assays for the three 1,2-dihaloethanes, consistent with the view that half-mustards are the mutagenic products of the GSH transferase reactions. Half-mustards [S-(2-haloethyl)GSH] containing either F, Cl, or Br (as the leaving group) were tested for their abilities to induce revertants in S. typhimurium, and rates of hydrolysis were also determined. GSH transferases do not appear to be involved in the breakdown of the half-mustard intermediates. A halide order (Br > Cl) was observed for both GSH transferase-catalyzed mutagenicity and S,S-ethylene-bis-GSH formation from 1,2-dihaloethanes, with the single exception (both assays) of BrCH(2)CH(2)Cl reaction with DM11, which was unexpectedly high. The lack of substrate saturation seen for conjugation of dihalomethanes with GSTs 5-5 and T1 was also observed with the mono- and 1,2-dihaloethanes [Wheeler, J. B., Stourman, N. V., Thier, R., Dommermuth, A., Vuilleumier, S., Rose, J. A., Armstrong, R. N., and Guengerich, F. P. (2001) Chem. Res. Toxicol. 14, 1118-1127], indicative of an inherent difference in the catalytic mechanisms of the bacterial and mammalian GSH transferases.
...
PMID:Conjugation of haloalkanes by bacterial and mammalian glutathione transferases: mono- and vicinal dihaloethanes. 1151 Nov 85
A primary route of metabolism of dihalomethanes occurs via glutathione (GSH) transferase-catalyzed conjugation. Mammalian theta class GSH transferases and a group of bacterial dichloromethane dehalogenases are able to catalyze the hydrolytic dehalogenation of dihalomethanes via GSH conjugation and subsequent formation of HCHO. Dihalomethanes have been shown to induce revertants in Salmonella typhimurium TA 1535 expressing theta class GSH transferases. Two mammalian theta class GSH transferases (rat
GST
5-5 and human
GST T1
) and the bacterial dehalogenase DM11 were compared in the in vitro conjugation of CH(3)Cl and using in vitro assays (HCHO formation) and the S. typhimurium mutagenesis assay with the dihalomethanes CH(2)Cl(2), CH(2)Br(2), CH(2)BrCl, CH(2)ICl, CH(2)I(2), and CH(2)ClF. GSTs 5-5 and T1 had similar characteristics and exhibited first-order rather than Michaelis-Menten kinetics for HCHO formation over the range of dihalomethane concentrations tested. In contrast, the DM11 enzyme displayed typical hyperbolic Michaelis-Menten kinetics for all of the compounds tested. A similar pattern was observed for the conjugation of CH(3)Cl. The reversion tests with S. typhimurium expressing DM11 or
GST
5-5 showed a concentration-dependent increase in revertants for most of the dihalomethanes, and DM11 produced revertants at dihalomethane concentrations lower than
GST
5-5. Collectively, the results indicate that rates of conversion of dihalomethanes to HCHO are not correlated with mutagenicity and that GSH conjugates are genotoxic. The results are compared with the conjugation and genotoxicity of haloethanes in the preceding paper in this issue [Wheeler, J. B., Stourman, N. V., Armstrong, R. N., and Guengerich, F. P. (2001) Chem. Res. Toxicol. 14, 1107-1117]. The halide order appears most important in the dihalomethane conjugation reactions catalyzed by
GST
5-5 and less so in
GST T1
and DM11, probably due to changes in the rate-limiting steps.
...
PMID:Conjugation of haloalkanes by bacterial and mammalian glutathione transferases: mono- and dihalomethanes. 1151 Nov 86
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