Polymorphisms in genes encoding polycyclic aromatic hydrocarbon (PAH) metabolizing enzymes may alter metabolism of these carcinogens and contribute to inter-individual difference in urine concentrations. We investigated the influence of genetic polymorphism on PAH metabolism in urine from 199 healthy subjects from Southern Brazil. We measured urine 1-hydroxypyrene glucuronide (1-OHPG) concentrations using immunoaffinity chromatography and synchronous fluorescence spectroscopy and genotyped subjects using standard methods. Genetic variants in CYP1B1 (rs1056827, rs1800440, rs10012) were strongly associated with urine 1-OHPG with P-values < 0.010. Variants in aryl hydrocarbon receptor (Ahr) (rs4986826), CYP1A1 (rs1799814) and CYP1A2 (rs2069514) were also, although less strongly, associated with changes in urine 1-OHPG concentrations. These variants had P-values of 0.074, 0.040 and 0.025, respectively. The median urine 1-OHPG concentrations (pmol/ml) in the homozygous wild-type and homozygous variants for CYP1B1 (rs10012) and the Ahr, CYP1A1 and CYP1A2 variants listed above were 2.16 and 0.10, 2.16 and 0.41, 2.03 and 0.46, 2.19 and 2.79, respectively. We found no effect of deletions in GST M1 or GST T1, or different alleles of UGT1A1*28. Adjusting for age, sex, place of residence, tobacco smoke exposure, maté drinking, cachaça and barbeque preparation had only a minor impact on the associations. A model containing just exposure variables had an r2 of 0.21; a model with single genotypes for Ahr, CYP1A1, CYP1A2 and CYP1B1 had an r2 of 0.10; and a model combining both exposure and genotype information had a total r2 of 0.33. Our results suggest that CYP1B1 genotypes are strongly associated with urine 1-OHPG concentrations in this population.

There is increasing evidence that catecholestrogens may contribute to the development of breast cancer. Specifically, inactivation of catecholestrogens may prevent the genesis and arrest the progression of the disease. Catechol-O-methyltransferase (COMT), Glutathione S-transferase (GST) M1 and GSTP1 are responsible for the detoxification of catecholestrogens, and are polymorphic in the human population. In this study, a PCR-based restriction fragment length polymorphism analysis was performed to determine genotypes of the COMT, GSTM1 and GSTP1 genes. We investigated the relationship between the germline polymorphism of these genes and clinico-pathological characteristics in 140 patients with breast cancer. Among 73 patients with the low activity COMT allele, 49 (67%) had regional lymph node metastasis. On the other hand, only 27 (40%) of 67 patients without the low activity allele had lymph node metastasis. The COMT genotype was significantly associated with clinical stage and the extent of regional lymph node metastasis of breast cancer (P<0.05). However, polymorphisms of the GSTM1 and GSTP1 gene were not associated with clinico-pathological factors. Our findings suggest that the allele encoding for low activity COMT may contribute to the progression of breast cancer.

Hepatic iron overload has been associated classically with the genetic disorder hereditary hemochromatosis. More recently, it has become apparent that mild-to-moderate degrees of elevated hepatic iron stores observed in other liver diseases also have clinical relevance. The goal was to use a mouse model of dietary hepatic iron overload and isobaric tag for relative and absolute quantitation proteomics to identify, at a global level, differentially expressed proteins in livers from mice fed a control or 3,5,5-trimethyl-hexanoyl-ferrocene (TMHF) supplemented diet for 4 weeks. The expression of 74 proteins was altered by ≥ ±1.5-fold, showing that the effects of iron on the liver proteome were extensive. The top canonical pathway altered by TMHF treatment was the NF-E2-related factor 2 (NRF2-)-mediated oxidative stress response. Because of the long-standing association of elevated hepatic iron with oxidative stress, the remainder of the study was focused on NRF2. TMHF treatment upregulated 25 phase I/II and antioxidant proteins previously categorized as NRF2 target gene products. Immunoblot analyses showed that TMHF treatment increased the levels of glutathione S-transferase (GST) M1, GSTM4, glutamate-cysteine ligase (GCL) catalytic subunit, GCL modifier subunit, glutathione synthetase, glutathione reductase, heme oxygenase 1, epoxide hydrolase 1, and NAD(P)H dehydrogenase quinone 1. Immunofluorescence, carried out to determine the cellular localization of NRF2, showed that NRF2 was detected in the nucleus of hepatocytes from TMHF-treated mice and not from control mice. We conclude that elevated hepatic iron in a mouse model activates NRF2, a key regulator of the cellular response to oxidative stress.

The present study was conducted to investigate possible association between the occurrence of glutathione-S-transferase GST M1 "null" genotype and alcoholic liver disease (ALD). The"null" genotype indicating absent activity of class mu glutathione transferase was assessed in 33 abstainers, 43 moderate alcohol consumers, and 313 heavy alcohol consumers by polymerase chain reaction. The genotypes were compared with occurrence of alcoholic fatty liver, alcoholic hepatitis, and alcoholic liver fibrosis. The "null" genotype was found among 44.7% of patients in the series, with no significant differences between different consumption groups: controls, 36.4%; moderate consumers, 39.5%; and heavy consumers, 46.3%. Occurrence of GST M1 "null" genotype was not associated with occurrence ALD among moderate alcohol consumers. Frequency of the "null" genotype was, however, statistically nearly significantly [p = 0.07, odds ratio (OR) = 1.75] lower among heavy consumers with normal liver histology than in alcoholics with ALD. Furthermore, when compared with heavy consumers without ALD, the "null" genotype was nearly significantly more frequent among heavy consumers with at least slight liver fibrosis (p = 0.05, OR = 1.8) and statistically significantly more frequent among among alcoholics with advanced liver fibrosis (p < 0.025, OR = 2.3). Results of the present Finnish association study suggest that homozygous deletion of the GST M1 gene may indicate increased susceptibility to develop irreversible liver damage in response to the toxic effects of ethanol. Significant association was found between the occurrence of the "null" genotype and the occurrence of alcoholic liver cirrhosis.

Glutathione S-transferase M1 (GSTM1), one member of the GST family, is responsible for metabolism of xenobiotics and carcinogens. Myeloperoxidase (MPO) plays an important role in the oxidation and activation of carcinogens and nitric oxide. Allelic variants of GSTM1 and MPO gene polymorphisms might impair detoxification function and increase the susceptibility to endometriosis. We aimed to investigate if these polymorphisms are useful markers for predicting endometriosis susceptibility. Women were divided into two groups: (i) endometriosis (n=150); (ii) non-endometriosis (n=159). Polymorphisms for GSTM1 and MPO were amplified by polymerase chain reaction and detected by electrophoresis after restriction digestion. The relative frequencies of the GSTM1*wild (+/+,+/0)/null (0/0) genotypes and MPO-463*G/A gene polymorphisms between both groups were compared. The distribution of GSTM1 polymorphisms was significantly different between the two groups. Proportions of GSTM1*wild/null alleles in both groups were: (i) 36.7/63.3%; (ii) 95/5% (P=0.001). In contrast, MPO-463 genotypes were not significantly different between the two groups. Proportions of MPO*A homozygote/heterozygote/G homozygote in both groups were: (i) 2.7/17.4/79.9% and (ii) 1.9/17/81.1% (P> 0.05). We conclude that the GSTM1*null genotype is associated with a higher risk of endometriosis development. MPO-463*G/A gene polymorphism is not related to the susceptibility of endometriosis.

Diabetes Mellitus is characterized by chronic hyperglycemia and associated with an increased production of reactive oxygen species (ROS). Oxidative stress is the result of accumulation of free radicals in tissues which specially affects beta cells in pancreas. Glutathione S-transferases (GSTs) are a family of antioxidant enzymes that include several classes of GSTs. These enzymes have important roles in decreasing of ROS species and act as a kind of antioxidant defense. To investigate the association between GSTs polymorphism with type 2 diabetes mellitus (T2DM), we investigated the frequency of GSTM1, T1 and P1 genotypes in patients with T2DM and controls. The genotypes of GSTT1, M1 and P1 were determined in 171 clinically documented T2DM patients and 169 normal cases (as controls) by multiplex polymerase chain reaction and PCR-RFLP. In diabetic patients, the frequency of GSTM1-null genotype was significantly (OR = 1.74; 95 % CI = 1.13-2.69, P = 0.016) higher than that in control. However, the frequency of GSTT1 (OR = 1.29; 95 % CI = 0.07-2.14, P = 0.367) and GSTP1 (OR = 0.83; 95 % CI = 0.53-1.30, P = 0.389) genotypes were not significantly different comparing both groups. Also, the frequency of both GSTT1-null and GSTM1-null genotypes in patients (19.88 %) was significantly higher compared to controls with the same genotypes (11.83 %, P = 0.022). Our results indicated that GSTM1 and GSTT1 genotypes might be involved in the pathogenesis of T2DM in south Iranian population.

Oxidative stress due to increased epidermal levels of H(2)O(2) with consequent inhibition of catalase activity is generally accepted as a leading cytotoxic mechanism of melanocyte loss in vitiligo. Keratinocyte-derived cytokines are considered key factors in the maintenance of melanocyte structure and functions. We hypothesized that abnormal redox control may lead to impaired cytokine production by keratinocytes, thus causing noncytotoxic defects in melanocyte proliferation and melanogenesis. We found significantly suppressed mRNA and protein expression of glutathione-S-transferase (GST) M1 isoform, and higher-than-normal levels of both 4-hydroxy-2-nonenal (HNE)-protein adducts and H(2)O(2) in the cultures of keratinocytes derived from unaffected and affected skin of vitiligo patients, and in their co-cultures with allogeneic melanocytes. GST and catalase activities, as well as glutathione levels, were dramatically low in erythrocytes, whilst HNE-protein adducts were high in the plasma of vitiligo patients. The broad spectrum of major cytokines, chemokines, and growth factors was dysregulated in both blood plasma and cultured keratinocytes of vitiligo patients, when compared to normal subjects. Exogenous HNE added to normal keratinocytes induced a vitiligo-like cytokine pattern, and H(2)O(2) overproduction accompanied by adaptive upregulation of catalase and GSTM1 genes, and transient inhibition of Erk1/2 and Akt phosphorylation. Based on these results, we suggest a novel GST-HNE-H(2)O(2)-based mechanism of dysregulation of cytokine-mediated keratinocyte-melanocyte interaction in vitiligo.

The objective of the paper was to study the association of polymorphisms of phases I and II xenobiotic metabolizing enzyme genes cytochrome P450 (CYP-4501A1*2A, *2B, *2C and *4 alleles, CYP-4502D6*4 allele), glutathione-S-transferase (<em>GST</em><em>M1</em> and <em>GST</em>T1 null genotypes) and N-acetyl transferase 2 (NAT2*6B and *7A alleles) with the incidence of acute myeloid leukemia (AML) in an eastern Indian population. Polymerase chain reaction and restriction fragment length polymorphism of genomic DNA from peripheral blood cells were used to detect CYP-450 and NAT2 gene polymorphisms in 110 AML patients and 144 racially and geographically matched normal controls. Polymerase chain reaction was also applied to detect <em>GST</em> gene polymorphisms in both groups. A statistically significant difference between the AML group and the normal group was observed in the case of glutathione-S-transferase <em>M1</em> null (odds ratio 3.25, 95% confidence interval 1.9-5.58, P<0.001) and N-acetyl transferase 2*6B (odds ratio 3.04, 95% confidence interval 1.79-5.16, P<0.001) genotypes. Combined deficiency of N-acetyl transferase 2 and glutathione-S-transferase <em>M1</em> genes produced an odds ratio of 11.91 (95% confidence interval 4.06-34.96, P<0.001). The effect of N-acetyl transferase 2*6B (P<0.001) is significant only at ages <or=40. In the population studied, persons with glutathione-S-transferase <em>M1</em> null genotype and N-acetyl transferase 2*6B allele are at increased risk of developing AML, and the risk is considerably enhanced in persons with both glutathione-S-transferase <em>M1</em> and N-acetyl transferase 2 deficiency.

BACKGROUND

The glutathione S-transferases (GST) can metabolise endogenous and exogenous toxins and carcinogens by catalysing the conjugation of diverse electrophiles with reduced glutathione (GSH). Variations of GST enzyme activity could influence the susceptibility of developing cancers in certain areas of the gastrointestinal tract.

OBJECTIVE

The expression of the components of the glutathione system in the colon was investigated with respect to age, gender and localisation.

METHODS

Biopsies of macroscopically normal mucosa from both proximal and distal colon were collected from 208 patients (106 females, 102 males; mean age 61 years), who underwent colonoscopy for various clinical reasons. GSH content, total GST enzyme activity and the levels of the GST isoenzymes glutathione S-transferase P1 (GSTP1) and glutathione S-transferase M1 (GSTM1) were determined.

RESULTS

GST enzyme activity, GSH and GSTP1 levels decreased significantly from proximal to distal colon (GST activity: 264 vs. 244 nmol/min/mg protein, p < 0.001, GSH content: 32 vs. 30 nmol/mg protein, p = 0.022 and GSTP1 levels: 2.25 vs. 2.10 mug/mg protein, p < 0.001). In female patients there was a significant stepwise increase of GST-activities and GSTP1 levels from the age of under 50 years to over 70 years. Oral sex hormone substitution among female patients between 50 and 70 years suppressed GST-activities and GSTP1 content.

CONCLUSIONS

The GSH-system in the colonic mucosa is expressed at a lower level in the distal colon (sigma) than in the colon transversum; whether this small difference translates into variations of incidence of colorectal cancer remains to be seen. Females express higher enzyme levels as they grow older, while in males no significant age effects were found. Elderly females might be better equipped with protective GSH-enzymes in the colon than males and this could contribute to the lower incidence of colorectal carcinomas in females.

Transgenic cell lines were constructed to study the dynamics of competition between activation versus detoxification of benzo[a]pyrene (B[a]P) or B[a]P-7,8-dihydrodiol metabolites. Stably transfected V79MZ cells expressing human cytochrome P4501A1 (hCYP1A1) alone or in combination with human glutathione-S-transferase M1 (hGSTM1) were used to determine how effectively this GST isozyme protects against cytotoxic, genotoxic, and mutagenic effects of B[a]P or the enantiomeric dihydrodiol metabolites (+)-benzo[a]pyrene-7,8-dihydrodiol ((+)-B[a]P-7,8-diol) and (-)-benzo[a]pyrene-7,8-dihydrodiol ((-)-B[a]P-7,8-diol). Expression of hGSTM1 in the presence of hCYP1A1 conferred significant 8.5-fold protection against B[a]P-induced cytotoxicity, but protection against cytotoxicity of either B[a]P-7,8-diol enantiomer was not significant. Mutagenicity of B[a]P at the hprt locus was dose and time dependent in cells that expressed hCYP1A1. Mutagenicity of B[a]P was reduced by 21-32% and mutagenicity induced by the B[a]P-7,8-diols was reduced 20-58% in cells further modified to coexpress hGSTM1-1 compared to cells expressing hCYP1A1 alone. Expression of hGSTM1-1 reduced adducts in total cellular macromolecules by twofold, in good correlation with the reduction in B[a]P mutagenicity. These results indicate that while hGSTM1-1 effectively protects against hCYP1A1-mediated cytotoxicity of B[a]P, a significant fraction of the mutagenicity that results from activation of B[a]P and its 7,8-dihydrodiol metabolites by hCYP1A1 is derived from B[a]P metabolites that are not detoxified by hGSTM1.

In this article, we introduce a rapid, protein sequence database-driven approach to characterize all contacting residue pairs present in protein hybrids for inconsistency with protein family structural features. This approach is based on examining contacting residue pairs with different parental origins for different types of potentially unfavorable interactions (i.e. electrostatic repulsion, steric hindrance, cavity formation and hydrogen bond disruption). The identified clashing residue pairs between members of a protein family are then contrasted against functionally characterized hybrid libraries. Comparisons for five different protein recombination studies available in the literature: (i) glycinamide ribonucleotide transformylase (GART) from Escherichia coli (purN) and human (hGART), (ii) human Mu class glutathione S-transferase (GST) M1-1 and M2-2, (iii) beta-lactamase TEM-1 and PSE-4, (iv) catechol-2,3-oxygenase xylE and nahH, and (v) dioxygenases (toluene dioxygenase, tetrachlorobenzene dioxygenase and biphenyl dioxygenase) reveal that the patterns of identified clashing residue pairs are remarkably consistent with experimentally found patterns of functional crossover profiles. Specifically, we show that the proposed residue clash maps are on average 5.0 times more effective than randomly generated clashes and 1.6 times more effective than residue contact maps at explaining the observed crossover distributions among functional members of hybrid libraries. This suggests that residue clash maps can provide quantitative guidelines for the placement of crossovers in the design of protein recombination experiments.

OBJECTIVE

Deletion polymorphisms of Glutathione-S-transferase (GST) M1 and T1 are considered risk factors for various diseases. However, most previous studies only distinguished "null" and "non-null" genotypes. Our aim was to develop a reliable, high-throughput GSTM1/T1 genotyping method able to determine allele copy numbers.

METHODS

We developed a multiplex real time PCR method to distinguish between heterozygous (1/0) and homozygous (1/1) GSTM1 and GSTT1 genotypes. The principle of relative quantification was applied and an expectation-maximisation (EM) algorithm was developed to assign one of 3 possible genotypes: 1/1, 1/0 or 0/0 for each of the two genes.

RESULTS

1320 Caucasians were genotyped using the newly developed method. The observed genotype distributions did not deviate from the expected and were in Hardy-Weinberg equilibrium. GSTM1 duplication was detected in one sample.

CONCLUSIONS

This new semiquantitative genotyping method is a sensitive and promising tool for large-scale molecular epidemiological and clinical studies.

Qualitative and quantitative analyses of glutathione, glutathione transferases (GSTs) and other glutathione-linked enzymes in HeLa cells have been made in order to study their significance in cellular resistance to electrophilic cytotoxic agents. The cytosolic concentrations of three GSTs, GST M1-1 (53 +/- 9 ng/mg of cytosolic protein), GST P1-1 (11 +/- 3 ng/mg) and GST A1-1 (1.1 +/- 0.4 ng/mg) were quantified by isoenzyme-specific enzyme-linked immunoassays. Electrophoretic analysis and immunoblotting demonstrated another component, GST M3-3, which was identified by amino acid sequence analysis. GST M3-3 was quantified (1550 +/- 250 ng/mg) by slot-blot immunoanalysis and was the most abundant GST in HeLa cells. An additional cytosolic 13 kDa protein with high affinity for immobilized glutathione or S-hexyglutathione was found to be identical with a macrophage migration-inhibitory factor, previously identified as a lymphokine. Cells grown in roller bottles (HR) rather than in ordinary culture flasks contain a significantly lower concentration of all the GSTs and were found to be more sensitive to the cytostatic agents doxorubicin (2.3-fold), cisplatin (1.7-fold) and melphalan (1.4-fold). The cytosolic concentrations of glutathione reductase and glyoxalase I were also lower in HR cells, whereas the total glutathione concentration was unchanged and the glutathione peroxidase activity was increased. The results indicate that GSTs contribute to the cellular resistance phenotype.

The naturally occurring organosulfur compounds (OSCs) diallyl sulfide (DAS), diallyl disulfide (DADS), dipropyl sulfide (DPS), and dipropyl disulfide (DPDS) were studied with respect to their effects on hepatic, intestinal, renal, and pulmonary phase II drug metabolizing enzymes, i.e., glutathione S-transferase (GST), microsomal epoxide hydrolase (mEH), quinone reductase (QR), and UDP-glucuronosyltransferase (UGT). OSCs were administered po to male SPF Wistar rats. In addition to assays of total enzyme activity, the ability of OSCs to modify the levels of mEH and rGSTA1/A2, A3/A5, M1, M2, and P1 was assessed by Western blotting. Remarkably, DADS significantly increased all Phase II enzyme activities, except the pulmonary mEH. It was noteworthy that only DADS induced QR activity. DAS, DPS, and DPDS induced mEH, GST, and UGT activities in the liver. Interestingly, DAS, DPS, and DPDS significantly decreased renal GST activity. In the same manner, DAS, DPS, and DPDS decreased rGSTA1/A2 and A3/A5 levels in the kidney. Conversely, all OSCs were able to induce GST of alpha and mu classes in the liver. In the intestine, DADS and DAS increased rGSTA1/A2, M2, and P1, while rGSTA3/A5 and M2 were only increased by DADS. In addition, DADS induced rGSTP1 dramatically in the four tissues analyzed. DADS also increased the mEH levels in the liver, intestine, and kidney, while DAS and DPS moderately induced mEH level in the liver. This study brings additional insights into the effects of OSCs on Phase II enzymes and suggests that DADS could be a promising chemopreventive agent considering its pleiotropic capacity of induction.

Glutathione S-transferases (GSTs) play a primary role in cellular defense against electrophilic chemical species and radical oxygen species. Because free radical attack is one mechanism of UV irradiation-caused skin damage, we investigated whether genetic variation at the GST loci GST T1 and GST M1 influences individual UVB sensitivity. In a double-blind clinical trial, 50 healthy volunteers were evaluated for minimal erythema dose of UVB irradiation, MED (J/cm2), skin types were assigned, and internal standard-controlled polymerase chain reaction (PCR) was used to identify their GST T1 and GST M1 genotypes. The five homozygous carriers of the GST T1 deletion (GST T1*0/0) presented with the most intensive inflammatory reactions after irradiation; they were significantly overrepresented among the highly UVB-sensitive subgroups (p = 0.006). Lack of GST M1 (GST M1*0/0, n = 27) tended to be more frequent only in UVB-sensitive subjects, and the proportion of the active GST M1 allelic variants *A and *B was similar in all UVB sensitivity subgroups. Three subjects with deficiencies in GST T1 and GST M1 had the most intense inflammatory responses. No effect of gender or genetic variations at the MC1R gene locus was established. Thus, heritable GST T1 deficiency may be a genetic determinant of individual skin sensitivity toward UV irradiation.

Numerous epidemiologic studies have indicated that there is a genetic basis to COPD. This result suggests that COPD develops in genetically susceptible individuals after sufficient exposure to cigarette smoke. At present, most of the genes that contribute to the genetic component to COPD are unknown. alpha 1-Antitrypsin deficiency is clearly a risk factor for COPD, but the other genetic associations with this disease must be considered as tentative. The key to establishing that a gene modifies the risk for a disease is replication of the association in different populations. This is a difficult task, however, because different genetic risk factors may be present in different populations. In addition, these genetic factors may interact with each other and with environmental risk factors, obscuring the effect of the gene on the phenotype. Apart from alpha 1-AT only the GST-M1, VDBP and CFTR genes have been implicated as risk factors in more than one population. Identification of other candidate genes awaits further understanding of the pathogenesis of COPD at the molecular level. There is good evidence that the propensity to smoke cigarettes and the likelihood of quitting smoking are influenced by genetic factors. This information may be useful in efforts directed toward cessation; however, most of the genetic studies so far have shown a rather small effect. The responses to hypoxia and hypercapnia also seem to be influenced by genetic factors. Identification of the genes involved could yield important insights into the pathogenesis of COPD and may highlight new targets for therapeutic intervention for this debilitating disease.

Comprehensive mechanistic studies suggest that oltipraz exerts cancer chemopreventive effects through the induction of glutathione S-transferase (GST). Previously, we have shown that the activation of CCAAT/enhancer binding protein-beta (C/EBPbeta), promoted by oltipraz, contributes to the transcriptional induction of the GSTA2 gene. Studies also indicated that exposure of animals to oltipraz triggers nuclear accumulation of NF-E2-related factor-2 (Nrf2) with an increase in Nrf2's antioxidant response element (ARE) binding activity. Given the previous reports that C/EBPbeta activation contributes to oltipraz's induction of the GSTA2 gene and that Nrf2 activation by oltipraz was variable depending on the concentrations, this study investigated whether the major oxidized metabolites of oltipraz induce GSTA2 through the activation of C/EBPbeta and/or Nrf2. Immunoblot analysis revealed that M1 [4-methyl-5-(pyrazin-2-yl)-3H-1,2-dithiol-3-one] and M2 (7-methyl-6,8-bis(methylthio)H-pyrrolo[1,2-a]pyrazine), but not M3 (7-methyl-8-(methylsulfinyl)-6-(methylthio)H-pyrrolo[1,2-a]pyrazine) and M4 (7-methyl-6,8-bis(methylsulfinyl)H-pyrrolo[1,2-a]pyrazine), induced GSTA2 in H4IIE cells. M1 and M2 also increased the luciferase activity from pGL-1651, which contained the luciferase structural gene downstream of the -1.65-kilobase GSTA2 promoter region. Nuclear C/EBPbeta levels were enhanced by the metabolites but not by M3 or M4. Among the oxidized metabolites examined, only M2, which elicited cell death at a relatively high concentration, activated Nrf2, as indicated by nuclear accumulation of Nrf2 and its ARE binding activity. The present study provides evidence that M1 and M2, but not M3 and M4, induce GSTA2 and that M1 induces GSTA2 only via C/EBPbeta activation, whereas M2 does so by activating Nrf2 as well as C/EBPbeta. These results substantiate the differential effects of oltipraz's metabolites on C/EBPbeta- and/or Nrf2-mediated GSTA2 induction.

The Mu-Class glutathione S-transferases (GSTs) are subject to marked inter-individual variation in man, owing to the fact that 40-50% of the population fail to express M1 subunits. Mu-Class GST from two lymphoblastoid cell lines (expressing M1 subunits and the other 'nulled' for M1) have been studied. Both cell lines were found to express a Mu-Class GST that has not been described previously. The cDNA encoding this novel transferase, designated 'GSTM4' has been isolated and the enzyme shown to be comprised of 218 amino acids (including the initiator methionine residue) with an M(r) of approx. 25.5 kDa. Molecular cloning demonstrated that the lymphoblastoid cell line which expressed GSTM1 possessed the b allelic variant (i.e. that with an asparagine residue at position 173). The genes for GSTM4 and GSTM1b have been cloned and found to contain seven introns and eight exons. The coding region of the GSTM4 gene, including the seven introns, encompasses 5.0 kb, whereas the same region of GSTM1b is 5.5 kb; the difference in the size of the two genes is due to the length of intron 7. DNA sequencing allowed a GSTM4-gene-specific oligo-primer to be designed which has been utilized in a PCR-based assay to determine that the GSTM4 gene is located on chromosome 1.

Cytosolic glutathione (GSH) transferases (GSTs) exist as stable homo- and heterodimers. Interactions at the subunit interface serve an important role in stabilizing the subunit tertiary structures of all GSH transferases. In addition, the dimer is required to maintain functional conformations at the active site on each subunit and the nonsubstrate ligand binding site at the dimer interface [Dirr, H. W. (2001) Chem.-Biol. Interact. 133, 19-23]. In this study, we report on the contribution of a specific intersubunit hydrophobic motif in rGSTM1-1 to dimer stability and protein function. The motif consists of the side chain of F56 from one subunit intercalated between helices 4 and 5 of the second subunit. Replacement of F56 with the hydrophilic side chains of serine, arginine, and glutamate results in a change in the structure of the active site, a marked diminution in catalytic efficiency, and alterations in the ability to bind nonsubstrate ligands. The mutations also affect the ability of the enzyme to bind GSH and the substrate analogue glutathione sulfonate. The functionality of rGSTM1-1 was disrupted to the greatest extent for the F56E mutant. Though mutations at this position do not alter the three-state equilibrium folding process for rGSTM1-1 (i.e., N(2) <->> 2I <->> 2U), destabilizing mutations at position 56 shift the equilibrium between the folded dimer (N(2)) and the monomeric intermediate (I) toward the latter conformational state. The transition to the unfolded state (U) is not significantly affected. The folded monomeric intermediate is also observed by electrospray ionization mass spectrometry. The amount of the intermediate is dependent on protein concentration and the residue at position 56. Mutations at position 56 have little impact on the secondary structure and stability of the monomeric folding intermediate. The dimerization process is proposed to induce a conformational change in the loop containing F56, resulting in improved stability and increased affinity between the M1 subunits.

OBJECTIVE

Characteristic for the genes encoding glutathione S-transferase (GST) M1 and GSTT1 is a null allele, suggested to increase susceptibility to chronic diseases. We report an optimized method for the determination of copy number variation (CNV) in GST genes.

METHODS

Real-time multiplex PCR reactions were optimized for quantification of GSTM1 and GSTT1 CNV using the DeltaCt method, a fixed volume of diluted DNA, a total volume of 10 microL, 384-well formats, and single determinations of each sample.

RESULTS

Consistent genotyping was obtained using DNA in a range of 0.41 ng to 100 ng. In a general population sample of 20,687 individuals the genotype frequencies were concordant with other methods used as standards. Throughput was 4600 genotypes per day at a reagent price of 0.5 euros per sample.

CONCLUSIONS

This high-throughput, low cost method accurately determines CNV in the GST genes enabling reliable estimates of disease prediction in large epidemiological samples.

Oxidative stress, mediated partly by lipid peroxidation products, may lead to increased collagen synthesis by hepatic stellate cells (HSC). Stellate cells are protected from oxidative stress by enzymes of detoxication such as the glutathione S-transferases (GSTs), which form glutathione conjugates with lipid peroxidation products (e.g., 4-hydroxy-2-nonenal [HNE]). To better understand the role of GSTs in stellate cell biology, we examined the expression and enzymatic activity of GSTs in normal and activated (both culture- and in vivo-activated) stellate cells. Normal stellate cells contained numerous isoforms of GST including those that detoxify HNE. High levels of enzymatic activity toward 1-chloro-2,4-dinitrobenzene (CDNB) and HNE were present in normal stellate cells and were similar to levels present in whole liver. Following activation by growth in culture, the expression of several GSTs (rGSTA1/A2, A3, and M1) was lost. Also, enzymatic activities toward CDNB and HNE fell approximately 90%. However, expression of rGSTP1 was maintained. A similar loss of rGSTA1/A2, A3, and M1 with persistent expression of rGSTP1 was present after activation in vivo. Furthermore, we identified 2 subpopulations of activated stellate cells with different GST phenotypes from injured livers. In summary, activated stellate cells lose most forms of GST and associated enzymatic activities that are present in normal stellate cells. The findings raise the possibility that activated stellate cells have less ability to detoxify lipid peroxidation products and may be susceptible to oxidative stress. Additionally, we propose that the phenotypic change in GSTs is a sensitive marker of stellate cell activation.

The organo(thio)phosphate esters are one of the most widely used classes of insecticides. Worldwide, organophosphate insecticides (OPs) result in numerous poisonings each year. In insects, glutathione S-transferases (GSTs) play an important role in OP resistance; limited data suggest that GST-mediated O-dealkylation occurs in humans as well. To characterize the capacity of mammalian GSTs to detoxify OPs, we investigated mammalian GST biotransformation of the widely used OP, methyl parathion (MeP). Cytosolic fractions isolated from rat, mouse, and ten individual adult human livers biotransformed 300 microM MeP at rates of 2.36, 1.76, and 0.70 (mean rate) nmol desmethyl parathion/min/mg, respectively. Our study focused on human GSTs; in particular, we investigated hGSTs M1-1 and T1-1, since deletion polymorphisms occur commonly in these genes. However, we found no correlation between hGSTM1/T1 genotypes and MeP O-dealkylation activities of the ten human liver cytosolic samples. We also measured MeP O-dealkylation activities of several purified recombinant GSTs belonging to the alpha (human GSTs A1-1 and A2-2, mouse GSTA3-3, rat GSTA5-5), mu (human GSTs M1a-1a, M2-2, M3-3, M4-4), pi (human GSTP1-1, mouse GSTs P1-1, P2-2), and theta (human GSTT1-1) classes. At 1 mM glutathione and 300 microM MeP concentrations, hGSTT1-1 and hGSTA1-1 exhibited the highest O-dealkylation activities: 545.8 and 65.0 nmol/min/mg, respectively. When expression level and enzymatic activity are considered, we estimate that hGSTA1-1 is responsible for the majority of MeP O-dealkylation in human hepatic cytosol. In target organs such as brain and skeletal muscle, where hGSTT1-1 is expressed, hGSTT1-1-mediated biotransformation of MeP may be important.

Several lines of evidence suggest that increased generation of auto-oxidized dopamine (DA) o-quinone is associated with the neurotoxicity of methamphetamine (MAP) in the brain, and that, as a cellular defenses against DA-derived quinines, glutathione S-transferase (GST) detoxifies auto-oxidized DA o-quinone in the brain. Glutathione S-transferase M1 (GSTM1) of the mu-class of GSTs catalyzes reaction between glutathione and catecholamine o-quinones under physiological conditions. This study was undertaken to investigate the role of the GSTM1 gene deletion polymorphism in the neuropathology of MAP abuse. One hundred fifty-seven MAP abusers and 200 healthy comparison subjects were tested for a genetic polymorphism of GSTM1. The difference in the frequency of deletion (D)/non-deletion (N) alleles between the female abusers and female controls was close to statistical significance (P = 0.071), although there was no statistical difference (P = 0.651) between male abusers and male controls. Furthermore, the number of female abusers with deletion alleles was significantly (P = 0.007, odds ratio: 2.77, 95% CI 1.30-5.89) higher than that of male abusers with deletion alleles. These findings suggest that GSTM1 gene deletion may contribute to a vulnerability to MAP abuse in female subjects, but not in male subjects.

Aflatoxin B1 (AFB1) widely contaminates staple food and feed crops and is well-known as the most potent natural hepatocarcinogen in humans and domesticated animals. This review highlights significant advances in our understanding of the pivotal role of phase I and II metabolizing enzymes in the bioactivation and detoxification of AFB1 and its metabolites across species. In humans, cytochrome P450 (CYP) 1A2, CYP3A4, CYP3A5, and CYP3A7 in liver and CYP2A13 in lung are essential for the bioactivation of AFB1 to the extremely toxic exo-AFB1-8,9-epoxide (AFBO), whereas CYP1A1, CYP1A2, CYP2A6, and CYP3A4 are important in the turkey and duck, CYP1A1 and CYP2A6 are important in the chicken and quail, CYP3A11 and CYP3A13 are important in mice, and CYP2A5 are important in the hamster. In contrast, glutathione-S-transferase (GST) M1 and GSTT1 are primary responsible for detoxification of the AFB1 by catalyzing the conjugation of GSH to AFBO in humans, whereas GSTM2 in a nonhuman primate, GSTA3 in mice, GSTA5 in rats, and GSTA1, GSTA2, GSTA3 and GSTA4 in the turkey are important. Additionally, microsomal epoxide hydrolase (mEH) and aflatoxin-aldehyde reductase (AFAR) have also been shown to play key roles in AFB1 detoxification in the human, rat, and pig. Moreover, an overview of the chemoprotective agents, including synthetic compounds and naturally occurring plant compounds, which can be used to reduce aflatoxicosis is provided based on their ability to regulate these key enzymes. Collectively, this review summarizes the pivotal enzymes in the metabolism of AFB1 among humans, experimental and farm animals, as well as the chemoprotective agents that can be used to minimize risk of aflatoxicosis.