FosB, a cysteine-dependent fosfomycin resistance protein under the control of sigma(W), an extracytoplasmic-function sigma factor in Bacillus subtilis

We demonstrate that the Bacillus subtilis fosB(yndN) gene encodes a fosfomycin resistance protein. Expression of fosB requires sigma(W), and both fosB and sigW mutants are fosfomycin sensitive. FosB is a metallothiol transferase related to the FosA class of Mn(2+)-dependent glutathione transferases but with a preference for Mg(2+) and L-cysteine as cofactors.

Role of multidrug resistance protein 1 (MRP1) and glutathione S-transferase A1-1 in alkylating agent resistance. Kinetics of glutathione conjugate formation and efflux govern differential cellular sensitivity to chlorambucil versus melphalan toxicity

We investigated the role of phase II (conjugation) and phase III (efflux) detoxification of the anticancer drugs melphalan (MLP) and chlorambucil (CHB). Although both drugs are substrates of Alpha-class glutathione S-transferases (GST) and the monoglutathionyl conjugates formed in these enzymatic reactions are transported by MRP1, we found that GSTA1-1 and MRP1 acted in synergy to confer resistance to CHB but not to MLP (Morrow, C. S., Smitherman, P. K., Diah, S. K., Schneider, E., and Townsend, A. J. (1998) J. Biol. Chem. 273, 20114-20120). To explain this selectivity of MRP1/GST-mediated resistance, we report results of side-by-side experiments comparing the kinetics of MLP- versus CHB-glutathione conjugate: formation, product inhibition of GSTA1-1 catalysis, and transport by MRP1. The monoglutathionyl conjugate of CHB, CHB-SG, is a very strong competitive inhibitor of GSTA1-1 (K(i) 0.14 microM) that is >30-fold more potent than that of the corresponding conjugate of MLP, MLP-SG (K(i) 4.7 microM). The efficiency of GSTA1-1-mediated monoglutathionyl conjugate formation is more than 4-fold higher for CHB than MLP. Lastly, both CHB-SG and MLP-SG are efficiently transported by MRP1 with similar V(max) although the K(m) for CHB-SG (0.37 microm) is significantly lower than for MLP-SG (1.1 microM). These results indicate that MRP1 is required for GSTA1-1-mediated resistance to CHB in order to relieve potent product inhibition of the enzyme by intracellular CHB-SG formed. The kinetic properties of MRP1 are well suited to eliminate CHB-SG at pharmacologically relevant concentrations. For MLP detoxification, where product inhibition of GSTA1-1 is less important, GSTA1-1 does not confer resistance because of the relatively poorer catalytic efficiency of MLP-SG formation. Similar analyses can be useful for predicting the pharmacological and toxicological consequences of MRP and GST expression on cellular sensitivity to various other electrophilic xenobiotics.

Molecular genetics of prostate cancer

The molecular mechanisms underlying the development and progression of prostate cancer are poorly understood. Epidemiological studies have suggested that 5-10% of all prostate cancers are familial, and numerous chromosomal loci have been associated with prostate cancer in multicentre linkage studies. However, no putative susceptibility genes harboured in these chromosomal regions have thus far been identified. Several recurrent chromosomal alterations in prostate cancer have been detected in comparative genomic hybridization (CGH) and loss of heterozygosity (LOH) analysis. The target genes for many of these aberrations are still not known. It seems that the androgen receptor (AR) signalling pathway plays a crucial role in both early development as well as in late progression of the disease. Both germ-line and somatic genetic alterations in the AR gene have been demonstrated in prostate cancer patients. The intention of this review is to summarize the current knowledge of molecular mechanisms in the development of prostate cancer.

Estrogen metabolism by conjugation

The involvement of estrogens in carcinogenic processes within estrogen-responsive tissues has been recognized for a number of years. Classically, mitogenicity associated with estrogen receptor-mediated cellular events was believed to be the mechanism by which estrogens contributed to carcinogenesis. Recently, the possibility that estrogens might contribute directly to mutagenesis resulting from DNA damage has been investigated. That damage is apparently a result of the formation of catechol estrogens that can be further oxidized to semiquinones and quinones. Those molecules represent reactive oxygen species and electrophilic molecules that can form depurinating DNA adducts, thus having the potential to result in permanent nucleotide mutation. Conjugation of parent estrogens to sulfate and glucuronide moieties; of catechol estrogens to methyl, sulfate, and glucuronide conjugates; and of catechol estrogen quinones to glutathione conjugates all represent potential "detoxification" reactions that may protect the cell from estrogen-mediated mitogenicity and mutagenesis. In this chapter, the biochemistry and molecular genetics of those conjugative reaction pathways are discussed. When applicable, the involvement of specific enzymatic isoforms is presented. Finally, the activity of many of these conjugative biotransformation reactions is subject to large interindividual variation--often due to the presence of common nucleotide polymorphisms within the genes encoding those enzymes. Functionally significant genetic polymorphisms that might contribute to variable conjugation of estrogens and catechol estrogens are also discussed.

[Prevention of renal carcinoma: the nutri-genetic approach]

The development of renal cell carcinoma (RCC) has been associated with both genetic and environmental factors, with somatic and germline mutations in the von Hippel-Lindau (VHL) tumor suppressor gene and with tobacco smoking, obesity, long term exposure to some nutrients, pollutants, and industrial solvents such as trichloroethylene. Intra and interfamilial variability of expression of germline mutations in the VHL gene and variable susceptibility to carcinogens in the sporadic forms strongly suggest the involvement of conditional modifier genes. In order to identify sub groups of individuals at increased risk because of susceptibility genotypes, we have collected a series of 460 patients who developed an RCC and 79 families with the von Hippel Lindau disease. To collect clinical and mutational data for correlation analysis we have developed a unique tool the Universal Mutation Database. Comparison of the spectrum of germline and somatic mutations in the VHL gene showed that: 1) in sporadic RCC mutations lead more often to truncated proteins (83%), while the remaining mutations (17%), include 3/4 of transversions and 1/4 of transitions. This high proportion of transversions supports the involvement of carcinogens the impact of which is conditioned by the genetic variability of xenobiotic metabolizing enzymes; 2) whereas in familial cases missense mutations are more common; this difference allowed us to define a prognostic factor for the occurrence of RCC in a VHL context. In order to look for genotypes conferring a higher risk we genotyped the RCC patients for 8 different genes (50 genotypes). A significant relationship was observed for several combinations of alleles including CYP1A1 ("variant"), NAT2 and NAT1 (slow) and GSTM1 (null allele). Associations between specific mutational profiles and at risk genotypes at different tumoral stages should allow us to: 1) define more precisely the nature of specific patterns of mutations in relation with the deficiency or overexpression of such or such enzymes in presence of particular carcinogens; 2) demonstrate that certain combinations of genotypes confer a particular risk to develop a specific type of tumor in VHL patients. Thus tracking of potentially carcinogenic substances, through their footprints and through identification of conditionally detrimental genotypes of genes participating in their detoxification should permit a better prevention through an appropriate nutrition adapted to each individual.

Role of glutathione S-transferase mu (GSTM1) in styrene-7,8-oxide toxicity and mutagenicity

In the human glutathione S-transferase (GST) mu gene family, homozygous deletion of GSTM1 is the null phenotype (frequency of approximately 50% in Caucasians). In the current study, GSTM1 status was determined in human cell lines using reverse transcriptase, polymerase chain reaction, and immunochemistry. Cell lines were challenged with a range of doses of styrene-7,8-oxide (SO) and then toxicity and genotoxicity were monitored. Toxicity was determined by growth in flasks and genotoxicity by cloning in microplates in the presence/absence of 6-thioguanine, to detect mutations at the hypoxanthine phosphoribosyltransferase (hprt) locus. A SO concentration-dependent decrease in survival was observed for all cell lines, with GSTM1-deficient lines being more sensitive. The IC(50)s of deficient and proficient cell lines were 0.45 and 0.55 mM SO, respectively. The difference between survival of GSTM1-deficient and -proficient cell lines approached statistical significance. The background mutation frequency of GSTM1-deficient cell lines was 2 x 10(-5), and that of GSTM1-proficient cell lines was 3 x 10(-6). GSTM1-deficient cell lines were significantly more sensitive than GSTM1-proficient cell lines to mutation induction for concentrations up to 2.5 mM SO (P < 0.001, regression analysis). These results suggest that cell lines containing metabolically competent GSTM1 are able to efficiently use GSTM1 to conjugate SO and reduce its hazard. This supports the epidemiological evidence that GSTM1 influences sensitivity to chemical carcinogenesis and subsequent risk of cancer induction.

Inhibition of glutathione S-transferases (GSTs) from parasitic nematodes by extracts from traditional Nigerian medicinal plants

Piliostigma thonningii, Ocimum gratissimum, Nauclea latifolia and Alstonia boonei are used in Nigerian traditional medicines against gastrointestinal helminths of animals and man. Proanthocyanidins were detected in Piliostigma and Nauclea, but not Alstonia or Ocimum. Extracts of these plants killed 50% of brine shrimp nauplii at <10 ppm (Nauclea), 100 ppm (Piliostigma) and <1000 ppm (Ocimum and Alstonia), the Nauclea LD50 being similar to the anthelmintic drug piperazine. Extracts were also toxic to the parasitic nematode Haemonchus infective L3 stage. Nematode glutathione-S-transferases (GSTs) are potential drug targets. Apart from Alstonia all the medicinal plants contained heat-stable inhibitory activities against recombinant Ascaris and Onchocerca GSTs in vitro. Piliostigma, Ocimum and Nauclea had IC50s of 2, 10 and 15 microg/mL respectively for Ascaris GST and 4, 8, 28 microg/mL respectively for Onchocerca GST. We suggest that the inhibitory properties of some of these Nigerian plant extracts against GST may contribute to the pharmacological basis of their efficacy against helminths in traditional herbal use.

Genetic risk factors for chronic obstructive pulmonary disease

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.

Increased resistance to acetaminophen hepatotoxicity in mice lacking glutathione S-transferase Pi

Overdose of acetaminophen, a widely used analgesic drug, can result in severe hepatotoxicity and is often fatal. This toxic reaction is associated with metabolic activation by the P450 system to form a quinoneimine metabolite, N-acetyl-p-benzoquinoneimine (NAPQI), which covalently binds to proteins and other macromolecules to cause cellular damage. At low doses, NAPQI is efficiently detoxified, principally by conjugation with glutathione, a reaction catalyzed in part by the glutathione S-transferases (GST), such as GST Pi. To assess the role of GST in acetaminophen hepatotoxicity, we examined acetaminophen metabolism and liver damage in mice nulled for GstP (GstP1/P2((-/-))). Contrary to our expectations, instead of being more sensitive, GstP null mice were highly resistant to the hepatotoxic effects of this compound. No significant differences between wild-type (GstP1/P2((+/+))) mice and GstP1/P2((-/-)) nulls in either the rate or route of metabolism, particularly to glutathione conjugates, or in the levels of covalent binding of acetaminophen-reactive metabolites to cellular protein were observed. However, although a similar rapid depletion of hepatic reduced glutathione (GSH) was found in both GstP1/P2((+/+)) and GstP1/P2((-/-)) mice, GSH levels only recovered in the GstP1/P2((-/-)) mice. These data demonstrate that GstP does not contribute in vivo to the formation of glutathione conjugates of acetaminophen but plays a novel and unexpected role in the toxicity of this compound. This study identifies new ways in which GST can modulate cellular sensitivity to toxic effects and suggests that the level of GST Pi may be an important and contributing factor in the sensitivity of patients with acetaminophen-induced hepatotoxicity.

Mammalian class theta GST and differential susceptibility to carcinogens: a review

Glutathione S-transferases (GSTs) are an important part of the cellular detoxification system and, perhaps, evolved to protect cells against reactive oxygen metabolites. Theta is considered the most ancient among the GSTs and theta-like GSTs are found in mammals, fish, insects, plants, unicellular algae, and bacteria. It is thought that an ancestral theta-gene underwent an early duplication before the divergence of fungi and animals and further duplications generated the variety of the other classes of GSTs (alpha, mu, phi, etc.). The comparison of the aminoacidic homologies among mammals suggests that a duplication of an ancient GST theta occurred before the speciation of mammals and resulted in the subunits GSTT1 and GSTT2. The ancestral GST theta has a dehalogenase activity towards several halogenated compounds, such as the dichloromethane. In fact, some aerobic and anaerobic methylotrophic bacteria can use these molecules as the sole carbon and energy source. The mammalian GST theta cannot sustain the growth of bacteria but still retains the dehalogenating activity. Therefore, although mammalian GST theta behaves as a scavenger towards electrophiles, such as epoxides, it acts also as metabolic activator for halogenated compounds, producing a variety of intermediates potentially dangerous for DNA and cells. For example, mice exposed to dichloromethane show a dose-dependent incidence of cancer via the GSTT1-1 pathway. Because GSTT1-1 is polymorphic in humans, with about 20% of Caucasians and 80% of Asians lacking the enzyme, the relationship between the phenotype and the incidence of cancer has been investigated extensively in order to detect GSTT1-1-associated differential susceptibility towards endogenous or exogenous carcinogens. The lack of the enzyme is related to a slightly increased risk of cancer of the bladder, gastro-intestinal tract, and for tobacco-related tumors (lung or oral cavity). More pronounced risks were found in males with the GSTT1-null genotype for brain diseases and skin basal cell carcinomas not related to sunlight exposures. Moreover, there was an increased risk of kidney and liver tumors in humans with the GSTT1-1 positive genotype following exposures to halogenated solvents. Interestingly, the liver and kidney are two organs that express the highest level of GST theta in the human body. Thus, the GSTT1-1 genotype is suspected to confer decreased or increased risk of cancer in relation to the source of exposure; in vitro studies, mostly conducted on metabolites of butadiene, confirm the protective action of GSTT1-1, whereas, thus far, experimental studies prove that the increasing risk is limited.

Protein oxidation and turnover

All biomacromolecules are faced with oxidative stress. Oxidation of a protein molecule always induces inactivation of the molecule and introduces a tag to that molecule. These modified protein molecules are prone to degradation in vivo by the proteasome system. Coupling of protein modification and degradation of chemically modified proteins is one of the normal protein turnover pathways in vivo. We call this a 'chemical apoptosis' process, which is one of the early manifestations of programmed cell death. Impairment of the proteasome system leads to accumulation of modified nonfunctional proteins or 'aged proteins' that might cause various clinical syndromes including cataractogenesis, premature aging, neurological degeneration and rheumatoid disease. The metal-catalyzed oxidation of biomacromolecules provides an excellent artificial aging system in vitro. The system is very useful in the characterization of structure and function relationships of proteins (enzymes), especially in those containing metal binding domain(s), because the oxidation is always followed by an affinity cleavage at the metal binding site(s) that allows easy identification and further characterization.

A lens glutathione S-transferase, class mu, with thiol-specific antioxidant activity

A protein that protected against the thiol-mediated metal-catalysed oxidative inactivation of enzymes but did not protect against the ascorbate-dependent oxidation system was extensively purified from bovine lens. The protein was a homodimer (pI 7) of 26 kDa subunits. Sixty per cent of the protein sequence was obtained by Edman sequencing and by sequence comparison was determined to be a class mu glutathione S-transferase (GST). The sequence of the enzyme is homologous to, but not identical to, that of any other class mu GST in the databanks. The complete protein sequence was derived from sequencing the cDNA and is the first complete sequence of a class mu GST from a bovine tissue. The enzyme was cloned and expressed in E. coli. The recombinant GST also protected against the thiol-mediated oxidative inactivation of enzymes but with lower activity than the native enzyme did and the recombinant GST had a comparable higher K(m)for GSH. The native and recombinant enzymes possessed similar low level peroxidase activity utilizing alkyl and cumene peroxides as substrates, but exhibited little activity against hydrogen peroxide.

Glutathione S-transferase p elicits protection against H2O2-induced cell death via coordinated regulation of stress kinases

To elucidate mechanisms underlying glutathione S-transferase p (GSTp)-mediated cellular protection against oxidative stress-induced cell death, the effect of GSTp on stress signaling pathways was investigated before and after H2O2 treatment. Under nonstressed conditions, increased expression of GSTp via a tet-off-inducible GSTp in NIH 3T3 cells increased the phosphorylation of mitogen-activated protein (MAP) kinase kinase 4, p38, extracellular receptor kinase (ERK), and inhibitor of kappa-kinase (IKK), and reduced phosphorylation of MAP kinase kinase 7 and Jun NH2-terminal kinase (JNK). Whereas H2O2 treatment of cells induced JNK, p38, and IKK activities, in the presence of H2O2 and elevated GSTp expression there was an additional increase in ERK, p38, and IKK activities and a decrease in JNK activity. GSTp-mediated protection from H2O2-induced death was attenuated upon inhibition of p38, nuclear factor KB, or MAP kinase by dominant negative or pharmacological inhibitors. Conversely, expression of a dominant negative JNK protected cells from H2O2-mediated death. These data suggest that the coordinated regulation of stress kinases by GSTp, as reflected by increased p38, ERK, and nuclear factor kappaB activities together with suppression of JNK signaling, contributes to protection of cells against reactive oxygen species-mediated death.

Glutathione S-transferase-pi gene expression and platinum drug exposure in human lung cancer

We examined the association between the gene expression levels of glutathione S-transferase-pi (GST-pi) and platinum drug exposure in human lung cancer. First we monitored GST-pi gene expression levels in two lung cancer cell lines and in peripheral mononuclear cells of ten previously untreated lung cancer patients after platinum drug exposure. Next we examined GST-pi gene expression levels in 40 lung cancer autopsy specimens. The GST-pi gene expression levels were assessed by the quantitative reverse transcription-polymerase chain reaction or Northern blot analysis. The GST-pi gene expression was not induced by platinum drugs either in vitro and in vivo within 24 h of exposure. In contrast, GST-pi gene expression levels in lung cancer tissues of patients who had been exposed to platinum drugs at least 1 month before death were significantly higher than that in those of patients who had not been exposed. These results suggest that GST-pi gene expression is associated with chronic exposure to platinum drugs in lung cancer and/or the stress response to xenobiotics.

Conservation of polar residues as hot spots at protein interfaces

A number of studies have addressed the question of which are the critical residues at protein-binding sites. These studies examined either a single or a few protein-protein interfaces. The most extensive study to date has been an analysis of alanine-scanning mutagenesis. However, although the total number of mutations was large, the number of protein interfaces was small, with some of the interfaces closely related. Here we show that although overall binding sites are hydrophobic, they are studded with specific, conserved polar residues at specific locations, possibly serving as energy "hot spots." Our results confirm and generalize the alanine-scanning data analysis, despite its limited size. Previously Trp, Arg, and Tyr were shown to constitute energetic hot spots. These were rationalized by their polar interactions and by their surrounding rings of hydrophobic residues. However, there was no compelling reason as to why specifically these residues were conserved. Here we show that other polar residues are similarly conserved. These conserved residues have been detected consistently in all interface families that we have examined. Our results are based on an extensive examination of residues which are in contact across protein interfaces. We utilize all clustered interface families with at least five members and with sequence similarity between the members in the range of 20-90%. There are 11 such clustered interface families, comprising a total of 97 crystal structures. Our three-dimensional superpositioning analysis of the occurrences of matched residues in each of the families identifies conserved residues at spatially similar environments. Additionally, in enzyme inhibitors, we observe that residues are more conserved at the interfaces than at other locations. On the other hand, antibody-protein interfaces have similar surface conservation as compared to their corresponding linear sequence alignment, consistent with the suggestion that evolution has optimized protein interfaces for function.

Glutathione S-transferase enzyme expression in hematopoietic cell lines implies a differential protective role for T1 and A1 isoenzymes in erythroid and for M1 in lymphoid lineages

BACKGROUND AND OBJECTIVES

Glutathione S-transferases (GSTs) are phase II metabolizing enzymes which catalyze the conjugation of glutathione (GSH) to electrophilic substrates and possess selenium-independent glutathione peroxidase activity. The GST enzyme family includes the cytosolic isoforms GST-alpha, mu (GSTM), pi (GSTP), theta (GSTT) and sigma (GSTS). GSTT1, P1 and M1 are polymorphic and altered polymorphic frequency of genes encoding these proteins has been suggested as a potential risk factor for the development of hematopoietic malignancies. Overexpression of GSTs has also been implicated in chemotherapeutic drug resistance. This study was undertaken to elucidate the potential functional relevance of these genetic polymorphisms in hematopoiesis.

DESIGN AND METHODS

GST genotype of 14 hematopoietic cell lines was determined by polymerase- chain-reaction (PCR). Gene expression of GSTs in a cell line was detected by real-time quantitative reverse transcriptase-polymerase chain reaction (RT-PCR) on TaqMan 7700 and by semi-quantitative RT-PCR. Cytosolic GST protein expression was detected by Western blot. GST conjugation activity was assayed using 1-chloro-2,4-dinitrobenzene (CDNB) as substrate.

RESULTS

GSTP1 expression was higher than other GSTs in 13/14 cell lines and paralleled CDNB conjugation activity. GSTP1 and GSTM1 predominated in lymphoid lines whilst T1 expression was relatively greatest in erythroid lines but was absent in 7/12 non-null lines. GSTT2 was expressed in only 3/4 lines. The 3 cell lines which expressed GSTA1 were all erythroid.

INTERPRETATION AND CONCLUSIONS

Glutathione S-transerases showed differential lineage expression in hematopoietic cell lines. This implies a greater cytoprotective role for GSTT1 and GSTA1 in erythroid cells and GSTM1 in lymphoid cells. We postulate that inherited gene deletion of GSTT1 and M1 may produce increased genotoxic susceptibility for erythroid and lymphoid cell respectively, following exposure to xenobiotics that are substrates for these enzymes.

Glutathione S-transferase: genetics and role in toxicology

The glutathione S-transferases (GST) are a supergene family of dimeric, enzymes that catalyse the conjugation of glutathione (GSH) to a variety of electrophiles including arene oxides, unsaturated carbonyls, organic halides and other substrates. Their importance is suggested by the finding that GST enzymes are expressed in probably all life forms. In humans, polymorphism in GST genes has been associated with susceptibility to various diseases though some recent data indicate that these genotypes modify disease phenotype. Thus, GST genotypes alone and in combination have been linked with clinical outcome.

The biochemical, molecular, and genomic aspects of leukotriene C4 synthase

Leukotriene C4 (LTC4) synthase is an 18 kD integral membrane enzyme of the 5-lipoxygenase/LTC4 synthase pathway and is positioned as the pivotal and only committed enzyme for the formation of the cysteinyl leukotrienes. Although its function is to conjugate catalytically LTA4 to reduced glutathione, LTC4 synthase is differentiated from other glutathione S-transferase family members by its lack of amino acid homology, substrate specificity, and kinetics. LTC4 synthase (LTC4S) protein is present in the perinuclear membranes of a limited number of hematopoietic cells involved in allergic inflammation, including mast cells, eosinophils, basophils, and macrophages. The cDNA encodes a monomeric protein of 150 amino acids with three hydrophobic domains interspersed with two hydrophilic loops. Site-directed mutagenic studies reveal that the enzyme functions as a homodimer and that arginine-51 in the first hydrophilic loop, and tyrosine-93 in the second hydrophilic loop, are involved in the acid and base catalysis of LTA4 and glutathione, respectively. Homology and secondary structural predictions indicate that LTC4S is a novel member of a new gene superfamily of integral membrane proteins, each with the capacity to participate in leukotriene biosynthesis. The gene for LTC4S is 2.5 kb in length and is localized on chromosome 5q35, distal to that of the genes for cytokines and receptors important in the development and perpetuation of allergic inflammation. Immunohistochemical studies of mucosal biopsies from the bronchi of aspirin-intolerant asthmatics show that LTC4S is overrepresented in individuals with this phenotype, and this finding correlates with overproduction of cysteinyl leukotrienes and lysine-aspirin bronchial hyperreactivity.

Metabolism of xenobiotics and chemical carcinogenesis

In order to avoid the accumulation of harmful xenobiotics in cells, living organisms have developed ways for their elimination. Multiple xenobiotic metabolizing enzymes with variable but partially overlapping catalytic properties play a key role in the elimination process. These enzymes are encoded by superfamilies of genes which, during the course of evolution, have evolved in a way that has made it possible for the different species to survive and take advantage of different habitats and diet containing a variable composition of harmful xenobiotics. As a result of this evolutionary process, species have achieved capacities to metabolize xenobiotics which are appropriate for their survival but which may differ considerably from those of other species. This evolutionary process may also explain the interethnic and interindividual variability of drug metabolism in humans. Because many carcinogens are substrates of drug-metabolizing enzymes it is reasonable to assume that humans have a variable capacity to activate or inactivate carcinogens. This has been shown to be the case. It appears that most of the carcinogen-metabolizing enzymes are inducible by xenobiotics: they respond to environmental stimuli and therefore vary in their activity. Furthermore, many of the encoding genes are polymorphic and multiple allelic variants relevant for the phenotype may exist in human populations. Analysis of the genetic variability that affects the capacity to metabolize carcinogens in humans has shown that a few members of the cytochrome P450, glutathione S-transferase and N-acetyltransferase gene families may play an Important role in chemical carcinogenesis. Yet for several enzymes such a role has not been established until now, although their catalytic properties and expression in human tissues suggest that such a role should exist. More studies on the role of individual enzymes in chemical carcinogenesis are therefore warranted.

The glutathione S-transferases: influence of polymorphism on cancer susceptibility

The glutathione S-transferase supergene family is an important part of cellular enzymic defence against endogenous and exogenous chemicals, many of which have a carcinogenic potential. However, while a wide variety of chemicals can act as substrates for different members of the supergene family, the precise function of these enzymes remains unclear. The supergene family comprises several gene families that include polymorphic loci, prompting the hypothesis that allelic variants associated with less effective detoxification of potential carcinogens can confer an increased susceptibility to cancer. For example, the null genotypes at the mu class GSTM1 and theta class GSTT1 loci have attracted particular interest, and recently identified allelic variants at the mu class GSTM3 and pi class GSTP1 loci are also putative susceptibility candidates. However, while associations between GSTM1 and GSTT1 genotypes and risk have been observed in some case-control studies in lung, bladder and colon cancers, other studies have reported contrary findings, and the importance of these polymorphisms in mediating the risk of smoking-related cancers remains generally unproven. We describe the influence of glutathione S-transferase polymorphisms on the risk of several cancers, including basal cell carcinoma of skin. In the latter cancer, associations between tumour numbers, site and accrual have been observed, suggesting a role for GST enzymes in the detoxification of the products of ultraviolet radiation-induced oxidative stress. We review below current knowledge of polymorphism in GST loci, possible in vivo GST substrates, and the difficulties of determining the role of this complex gene family on the basis of available epidemiological data.

Crystal structure of a murine glutathione S-transferase in complex with a glutathione conjugate of 4-hydroxynon-2-enal in one subunit and glutathione in the other: evidence of signaling across the dimer interface

mGSTA4-4, a murine glutathione S-transferase (GST) exhibiting high activity in conjugating the lipid peroxidation product 4-hydroxynon-2-enal (4-HNE) with glutathione (GSH), was crystallized in complex with the GSH conjugate of 4-HNE (GS-Hna). The structure has been solved at 2.6 A resolution, which reveals that the active site of one subunit of the dimeric enzyme binds GS-Hna, whereas the other binds GSH. A marked asymmetry between the two subunits is evident. Most noticeable are the differences in the conformation of arginine residues 69 and 15. In all GST structures published previously, the guanidino groups of R69 residues from both subunits stack at the dimer interface and are related by a (pseudo-) 2-fold axis. In the present structure of mGSTA4-4, however, the two R69 side chains point in opposite directions, although their guanidino groups remain in contact. In the subunit with bound GSH, R69 also interacts with R15, and the guanidino group of R15 points away from the active site, whereas in the subunit that binds GS-Hna, R15 pivots into the active site, which breaks its interaction with R69. According to our previous results [Nanduri et al. (1997) Arch. Biochem. Biophys. 335, 305-310], the availability of R15 in the active site assists the conjugation of 4-HNE with GSH. We propose a model for the catalytic mechanism of mGSTA4-4 in conjugating 4-HNE with GSH-i.e., the guanidino group of R15 is available in the active site of only one subunit at any given time and the stacked pair of R69 residues act as a switch that couples the concerted movement of the two R15 side chains. The alternate occupancy of 4-HNE in the two subunits has been confirmed by our kinetic analysis that shows the negative cooperativity of mGSTA4-4 for 4-HNE. Disruption of the signaling between the subunits by mutating the R69 residues released the negative cooperativity with 4-HNE.

The role of human glutathione S-transferases hGSTA1-1 and hGSTA2-2 in protection against oxidative stress

In order to elucidate the protective role of glutathione S-transferases (GSTs) against oxidative stress, we have investigated the kinetic properties of the human alpha-class GSTs, hGSTA1-1 and hGSTA2-2, toward physiologically relevant hydroperoxides and have studied the role of these enzymes in glutathione (GSH)-dependent reduction of these hydroperoxides in human liver. We have cloned hGSTA1-1 and hGSTA2-2 from a human lung cDNA library and expressed both in Escherichia coli. Both isozymes had remarkably high peroxidase activity toward fatty acid hydroperoxides, phospholipid hydroperoxides, and cumene hydroperoxide. In general, the activity of hGSTA2-2 was higher than that of hGSTA1-1 toward these substrates. For example, the catalytic efficiency (kcat/Km) of hGSTA1-1 for phosphatidylcholine (PC) hydroperoxide and phosphatidylethanolamine (PE) hydroperoxide was found to be 181.3 and 199.6 s-1 mM-1, respectively, while the catalytic efficiency of hGSTA2-2 for PC-hydroperoxide and PE-hydroperoxide was 317.5 and 353 s-1 mM-1, respectively. Immunotitration studies with human liver extracts showed that the antibodies against human alpha-class GSTs immunoprecipitated about 55 and 75% of glutathione peroxidase (GPx) activity of human liver toward PC-hydroperoxide and cumene hydroperoxide, respectively. GPx activity was not immunoprecipitated by the same antibodies from human erythrocyte hemolysates. These results show that the alpha-class GSTs contribute a major portion of GPx activity toward lipid hydroperoxides in human liver. Our results also suggest that GSTs may be involved in the reduction of 5-hydroperoxyeicosatetraenoic acid, an important intermediate in the 5-lipoxygenase pathway.

Role of glutathione S-transferase 8-8 in allylamine resistance of vascular smooth muscle cells in vitro

Allylamine (AA) is a cardiovascular toxin that causes lesions resembling atherosclerosis in several mammalian species. AA's toxic effects are thought to be exerted through its conversion to acrolein (AC), a potent electrophilic alkylating agent and atherogen. Semicarbazide sensitive amine oxidase (SSAO) catalyzes the oxidation of AA to AC. Glutathione S-transferases (GST) can catalyze the first step of detoxification of AC to mercapturic acid. Our previous studies suggest that the isozyme rGST8-8 is a principal defense against electrophilic stress exerted by alpha,beta-unsaturated carbonyls such as AC. In the present studies, we use cultured rat vascular smooth muscle cells (VSMC) to examine the relative roles of SSAO and rGST8-8 in the cytotoxic effects of the atherogens, AA and AC. Exposure derived AA-resistant cells (VSMC-AA) were 3.5-fold more resistant to AA when compared to VSMC and 1.8-fold more resistant to acrolein. SSAO activity was 2-fold higher in VSMC-AA than in VSMC. Consistent with the role of SSAO in biotransformation of AA, the SSAO inhibitor semicarbazide (SC; 100 microM) provided nearly complete protection from AA to both VSMC-AA and VSMC. As expected, SC did not affect the cytotoxicity of AC. Pretreatment with 100 microM sulfasalazine (SS), a GST inhibitor, potentiated AA and AC toxicity in both VSMC-AA and VSMC, indicating a protective role of GST. Catalytic efficiency (K(cat)/K(m)) of GSTs was higher toward 4-hydroxynonenal (4-HNE) (0.65 mM(-1) s(-1)) than toward 1-chloro-2, 4-dinitrobenzene (CDNB) (0.14 mM(-1) s(-1)) for VSMC. In VSMC-AA, K(cat)/K(m) was increased 4.1-fold toward CDNB (0.58 mM(-1) s(-1)) and 6-fold toward 4HNE (3.9 mM(-1) s(-1)) when compared to VSMC, indicating a preferential increase in VSMC-AA of GST isozymes which utilize alpha,beta-unsaturated carbonyls. Western blots confirmed induction of rGST8-8 in VSMC-AA. Expression of recombinant mGSTA4 (the mouse homolog of rGST8-8) in VSMC caused a 1.6-fold increase in resistance to AA and AC. This resistance was fully reversed by 50 microM SS. Our results demonstrate that GSTs are an important defense against electrophilic atherogens and that isozymes with high activity toward alpha,beta-unsaturated carbonyls are particularly important in the vascular wall.