An enzyme catalysing the conjugation of epoxides with glutathione

1. Liver supernatant preparations from rats and ferrets catalyse the conjugation of some epoxides with glutathione. The enzyme involved might be called `glutathione S-epoxidetransferase', as it is different from glutathione S-aryltransferase, the enzyme catalysing the conjugation of 1,2-dichloro-4-nitrobenzene, 4-nitro-pyridine N-oxide and other cyclic compounds with glutathione and from the enzyme catalysing the conjugation of iodomethane and glutathione. 2. The enzyme does not catalyse the reaction with cysteine. It is not inactivated by dialysis but is unstable at pH 5·0. 3. The role of the enzyme in metabolism of foreign compounds is discussed.     

Cloning,characterization and regulation of a family of phi class glutathione transferases from wheat

Six phi (F) class glutathione transferases (GSTs) were cloned from bread wheat (Triticum aestivum L.) treated with the herbicide safener fenchlorazole ethyl and named TaGSTF1–6. Recombinant TaGSTFs were assayed for glutathione conjugating activity towards xenobiotics including herbicides and for glutathione peroxidase (GPOX) activity. TaGSTF1, which resembled ZmGSTF1, the dominant GST in maize (Zea mays), was highly active in conjugating 1-chloro-2,4-dinitrobenezene (CDNB) but had low activities towards chloroacetanilide, diphenyl ether and aryloxphenoxypropionate herbicides. TaGSTF2, TaGSTF3 and TaGSTF4 all resembled the safener-inducible ZmGSTF2, with TaGSTF2 and TaGSTF3 being highly active GPOXs and rapidly detoxifying chloroacetanilides. TaGSTF5 resembled ZmGSTF3, having limited conjugating and GPOX activity. TaGSTF6 contained both ZmGSTF1- and ZmGSTF2-like sequences but was most similar to ZmGSTF1 in detoxifying activity. The expression of TaGSTFs in wheat seedlings was enhanced upon exposure to fenchlorazole ethyl, herbicides or other chemical inducing treatments. TaGSTFs were also enhanced by treatment with the natural products caffeic acid, 7,4-dihydroxyflavone and naringenin. The CDNB-conjugating activity of TaGSTF1, and to a lesser extent TaGSTF6, was highly sensitive to inhibition by flavonoids, particularly the chalcone isoliquiritigenin. The other TaGSTFs were much less sensitive to such inhibition. It was subsequently determined that isoliquiritigenin underwent glutathione conjugation, though this reversible reaction did not require the intervention of any TaGSTF. The potential importance of GSTFs and glutathione conjugation in flavonoid metabolism is discussed.     

Glutathione transferases,regulators of cellular metabolism and physiology

Background

The cytosolic glutathione transferases (GSTs) comprise a super family of proteins that can be categorized into multiple classes with a mixture of highly specific and overlapping functions.

Scope of review

The review covers the genetics, structure and function of the human cytosolic GSTs with particular attention to their emerging roles in cellular metabolism.

Major conclusions

All the catalytically active GSTs contribute to the glutathione conjugation or glutathione dependant-biotransformation of xenobiotics and many catalyze glutathione peroxidase or thiol transferase reactions. GSTs also catalyze glutathione dependent isomerization reactions required for the synthesis of several prostaglandins and steroid hormones and the catabolism of tyrosine. An increasing body of work has implicated several GSTs in the regulation of cell signaling pathways mediated by stress-activated kinases like Jun N-terminal kinase. In addition, some members of the cytosolic GST family have been shown to form ion channels in intracellular membranes and to modulate ryanodine receptor Ca^2 + channels in skeletal and cardiac muscle.

General significance

In addition to their well established roles in the conjugation and biotransformation of xenobiotics, GSTs have emerged as significant regulators of pathways determining cell proliferation and survival and as regulators of ryanodine receptors that are essential for muscle function. This article is part of a Special Issue entitled Cellular functions of glutathione.     

The extended catalysis of glutathione transferase

Glutathione transferase reaches 0.5–0.8 mM concentration in the cell so it works in vivo under the unusual conditions of, [S] ? [E]. As glutathione transferase lowers the pK_a of glutathione (GSH) bound to the active site, it increases the cytosolic concentration of deprotonated GSH about five times and speeds its conjugation with toxic compounds that are non-typical substrates of this enzyme. This acceleration becomes more efficient in case of GSH depletion and/or cell acidification. Interestingly, the enzymatic conjugation of GSH to these toxic compounds does not require the assumption of a substrate–enzyme complex; it can be explained by a simple bimolecular collision between enzyme and substrate. Even with typical substrates, the astonishing concentration of glutathione transferase present in hepatocytes, causes an unusual “inverted” kinetics whereby the classical trends of v versus E and v versus S are reversed.     

Involvement of glutathione metabolism in Eichhornia crassipes tolerance to arsenic

• Aquatic macrophytes are potentially useful for phytoremediation programmes in environments contaminated by arsenic (As). Biochemical and physiological modification analyses in different plant parts are important to understand As tolerance mechanisms.
• The objective was to evaluate glutathione metabolism in leaves and roots of Eichhornia crassipes (Mart.) Solms treated to As. Specimens of E. crassipes were cultured for 3 days in Clark's nutrient solution containing 7 μm As. The enzymes ATP sulphurylase (ATPS), glutathione reductase (GR), glutathione peroxidase (GSH‐Px), glutathione sulphotransferase (GST) and γ‐glutamylcysteine synthetase (γ‐ECS) activity, glutathione content, total protein and non‐protein thiols were evaluated.
• The ATPS activity increased in roots. GR activity in leaves and GSH‐Px in roots were lower. GST activity was higher in roots and lower in leaves, and γ‐ECS activity was higher in leaves. Glutathione levels were lower, total thiol levels were higher and non‐protein levels did not change in E. crassipes leaves and roots. Exposure to As increased enzyme activity involved with sulphur metabolism, such as ATPS. Higher GR activity and lower GSH‐Px indicate increased glutathione conjugation to As due to increased GSH availability. The higher GST activity indicates its participation in As detoxification and accumulation through As GSH conjugation. Changes in glutathione and thiol levels suggest high phytochelatin synthesis.
• In conclusion, the increments in ATPS, GR, GST and γ‐ECS activity indicate that these enzymes are involved in GSH metabolism and are part of the E. crassipes As detoxification mechanism.

     

Interaction of the mycotoxin penicillic acid with glutathione and rat liver glutathione S-transferases

The in vitro interaction of the mycotoxin penicillic acid (PA) with rat liver glutathione S-transferase (GST) was studied using reduced glutathione and 1-chloro-2,4-dinitrobenzene as substrates. The inhibition of the GST activity by PA in crude extracts was dose dependent. Each of the different GST isoenzymes was inhibited, albeit at different degrees. Kinetic studies never revealed competitive inhibition kinetics. The conjugation of PA with GSH occurred spontaneously; it was not enzymatically catalyzed by GST, indicating that an epoxide intermediate is not involved in conjugation. The direct binding of PA to GST provides an additional detoxication mechanism.     

The biochemistry of drug metabolism--an introduction: part 3. Reactions of hydrolysis and their enzymes

This review continues a general presentation of the metabolism of drugs and other xenobiotics begun in two recent issues of Chemistry & Biodiversity. This Part presents some of the numerous hydrolases involved, their nomenclature, relevant biochemical properties, catalytic mechanisms, and the many reactions of hydrolysis they catalyze. A number of medicinally, environmentally, and toxicologically relevant examples are presented and discussed. The reactions examined include the hydrolysis of carboxylic esters, amides and peptides, lactones, and other labile rings, and esters of inorganic acids. The hydration of epoxides and its enzymology are treated separately.     

Early habituation of maize (Zea mays) suspension‐cultured cells to 2,6‐dichlorobenzonitrile is associated with the enhancement of antioxidant status

The cellulose biosynthesis inhibitor 2,6‐dichlorobenzonitrile (DCB) has been widely used to gain insights into cell wall composition and architecture. Studies of changes during early habituation to DCB can provide information on mechanisms that allow tolerance/habituation to DCB. In this context, maize‐cultured cells with a reduced amount of cellulose (～20%) were obtained by stepwise habituation to low DCB concentrations. The results reported here attempt to elucidate the putative role of an antioxidant strategy during incipient habituation. The short‐term exposure to DCB of non‐habituated maize‐cultured cells induced a substantial increase in oxidative damage. Concomitantly, short‐term treated cells presented an increase in class III peroxidase and glutathione S‐transferase activities and total glutathione content. Maize cells habituated to 0.3–1 µM DCB (incipient habituation) were characterized by a reduction in the relative cell growth rate, an enhancement of ascorbate peroxidase and class III peroxidase activities, and a net increment in total glutathione content. Moreover, these cell lines showed increased levels of glutathione S‐transferase activity. Changes in antioxidant/conjugation status enabled 0.3 and 0.5 µM DCB‐habituated cells to control lipid peroxidation levels, but this was not the case of maize cells habituated to 1 μM DCB, which despite showing an increased antioxidant capacity were not capable of reducing the oxidative damage to control levels. The results reported here confirm that exposure and incipient habituation of maize cells to DCB are associated with an enhancement in antioxidant/conjugation activities which could play a role in incipient DCB habituation of maize‐cultured cells.     

A Tale of Plant Glutathione <Emphasis Type="Italic">S</Emphasis>-Transferases: Since 1970

Ubiquitously distributed multifunctional superfamily of Glutathione S-transferases (GST) generally constitute a dimeric enzymes and catalyse the conjugation of the thiol group of the glutathione (GSH) to diverse electrophilic centres on lipophilic molecules with the formation of rather less active end products. Besides their well investigated conjugation reaction for the detoxification of endogenous and xenobiotic compounds, they can also be involved in both GSH dependent peroxidation or isomerization reactions, and several other non-catalytic functions, like binding of non-substrate ligands, stress-induced signalling processes and preventing of apoptosis. Plant GSTs have been a focus of attention because of their roles in herbicide detoxification and today seven distinct classes of soluble (cytosolic) GSTs are presented as Phi, Tau, Theta, Zeta, Lambda, Dehydroascorbate reductases (DHARs) and Tetrachlorohydroquinone dehalogenase (TCHQD). While GSTs show overall sequence diversification within and between classes, they retain a high level of three-dimensional structure conservation over long evolutionary periods. In this review mainly the soluble plant GSTs will be considered by giving attention to their structures, subcellular localizations, genomic organizations, catalytic/noncatalytic functions, and comparisons given with respect to their mammalian counterparts where necessary.     

Review: Risk assessment implications of variation in susceptibility to perchloroethylene due to genetic diversity,ethnicity, age,gender, diet and pharmaceuticals

Current cancer risk assessments do not adequately consider impacts of human inter-individual variability on susceptibility to environmental pollutants like perchloroethylene (PCE). PCE is metabolized through both oxidative and glutathione (GSH) conjugation pathways. Toxicity criteria derived using both pathways are 23-fold more stringent than those calculated using only oxidative metabolism. While toxicokinetic modeling of PCE metabolism predicted very high variability through the GSH conjugation pathway, it is unclear if the range in estimates is due to human variability or uncertainty. Thus, the variation in the GSH conjugation pathway of PCE metabolism due to genetics, ethnicity, age, gender, diet, and pharmaceutical co-exposures is examined. Genetic polymorphisms were found at several loci including, GSTT1, GSTM1, CCBL1, AGXT2, NAT8, ACY3, MRP2, OAT1/3, FMO3, and CYP3A that code for enzymes/transporters in the GSH conjugation pathway. Genetic diversity in GSTT1, GSTM1, and CCBL1 between ethnic populations, as well as age, gender, diet, and pharmaceutical co-exposures influences toxic and mutagenic metabolites produced through this pathway. Given this diversity, large differences in PCE metabolism through the GSH conjugation pathway are expected. To be health protective for diverse ethnic populations and lifestyles, both the oxidative and GSH conjugation pathways need to be considered in developing PCE toxicity criteria.     

Homology model for the human GSTT2 theta class glutathione transferase

A tertiary model of the human GSTT2 Theta class glutathione transferase is presented based on the recently solved crystal structure of a related thetalike isoenzyme from Lucilia cuprina. Although the N-terminal domains are quite homologous, the C-terminal domains share less than about 20% identity. The model is used to consolidate the role of Ser 11 in the active site of the enzyme as well as to identify other residues and mechanisms of likely catalytic importance. The T2 subfamily of theta class enzymes have been shown to inactivate reactive sulfate esters arising from arylmethanols. A possible reaction pathway involving the conjugation of glutathione with one such sulfate ester, 1-menaphthyl-sulfate, is described. It is also proposed that the C-terminal region of the enzyme plays an important role in allowing substrate access to the active site. Proteins 27:118–130 © 1997 Wiley-Liss, Inc.     

Aromatic residues in the C-terminal region of glutathione transferase A1-1 influence rate-determining steps in the catalytic mechanism [Biochimica et Biophysica Acta 1597 (2002) 157-163]

Human glutathione transferase A1-1 (GST A1-1) has a flexible C-terminal segment that forms a helix (α9) closing the active site upon binding of glutathione and a small electrophilic substrate such as 1-chloro-2,4-dinitrobenzene (CDNB). In the absence of active-site ligands, the C-terminal segment is not fixed in one position and is not detectable in the crystal structure. A key residue in the α9-helix is Phe 220, which can interact with both the enzyme-bound glutathione and the second substrate, and possibly guide the reactants into the transition state. Mutation of Phe 220 into Ala and Thr was shown to reduce the catalytic efficiency of GST A1-1. The mutation of an additional residue, Phe 222, caused further decrease in activity. The presence of a viscosogen in the reaction medium decreased the kinetic parameters k_cat and k_cat/K_m for the conjugation of CDNB catalyzed by wild-type GST A1-1, in agreement with the view that product release is rate limiting for the substrate-saturated enzyme. The mutations cause a decrease of the viscosity dependence of both kinetic parameters, indicating that the motion of the α9-helix is linked to catalysis in wild-type GST A1-1. The isomerization reaction with the alternative substrate Δ⁵-androstene-3,17-dione (AD) is affected in a similar manner by the viscosogens. The transition state energy of the isomerization reaction, like that of the CDNB conjugation, is lowered by Phe 220 as indicated by the effects of the mutations on k_cat/K_m. The results demonstrate that Phe 220 and Phe 222, in the dynamic C-terminal segment, influence rate-determining steps in the catalytic mechanism of both the substitution and the isomerization reactions.     

Roles for glutathione transferases in plant secondary metabolism

Plant glutathione transferases (GSTs) are classified as enzymes of secondary metabolism, but while their roles in catalysing the conjugation and detoxification of herbicides are well known, their endogenous functions are largely obscure. Thus, while the presence of GST-derived S-glutathionylated xenobiotics have been described in many plants, there is little direct evidence for the accumulation of similarly conjugated natural products, despite the presence of a complex and dichotomous metabolic pathway which processes these reaction products. The conservation in glutathione conjugating and processing pathways, the co-regulation of GSTs with inducible plant secondary metabolism and biochemical studies showing the potential of these enzymes to conjugate reactive natural products are all suggestive of important endogenous functions. As a framework for addressing these enigmatic functions we postulate that either: (a) the natural reaction products of GSTs are unstable and undergo reversible S-glutathionylation; (b) the conjugation products of GSTs are very rapidly processed to derived metabolites; (c) GSTs do not catalyse conventional conjugation reactions but instead use glutathione as a cofactor rather than co-substrate; or (d) GSTs are non-catalytic and function as transporter proteins for secondary metabolites and their unstable intermediates. In this review, we describe how enzyme biochemistry and informatics are providing clues as to GST function allowing for the critical evaluation of each of these hypotheses. We also present evidence for the involvement of GSTs in the synthesis of sulfur-containing secondary metabolites such as volatiles and glucosinolates, and the conjugation, transport and storage of reactive oxylipins, phenolics and flavonoids.     

Comparative toxicity of (+)-(R)- and (−)-(S)-1,2-dibromo-3-chloropropane

The haloalkane 1,2-dibromo-3-chloropropane (DBCP), an environmental pollutant that was widely used as a soil fumigant, is a carcinogen and a mutagen and displays target-organ toxicity to the testes and the kidneys. Because little is known about effects of stereochemistry on the metabolism and toxicity of halogenated alkyl compounds and because DBCP, which has a chiral center at C-2, may show enantioselectivity in its metabolism and/or toxicities, the optically pure enantiomers of DBCP were tested in vivo in rats for organ toxicity as well as for bacterial mutagenicity. Organ toxicity studies showed that (S)-DBCP was slightly more renal toxic than (R)-DBCP but was not significantly more toxic than the racemate, and that no significant differences were observed in the extents of testicular necrosis and atrophy caused by either enantiomer or the racemate. In contrast, (R)-DBCP was more mutagenic than either (S)-DBCP or the racemate to Salmonella typhimurium (S. typhimurium) strains TA 100 and TA104. However, there was little or no enantioselectivity in glutathione S-transferase (GST)-catalyzed conjugation reactions of glutathione with DBCP based on the lack of selectivity in the rates of disappearance of the enantiomers of DBCP in the presence of glutathione (GSH) and GSTs as monitored by chiral gas chromatography (GC). © 1995 Wiley-Liss, Inc.     

Structures of yeast glutathione‐S‐transferase Gtt2 reveal a new catalytic type of GST family

Glutathione‐S‐transferases (GSTs) are ubiquitous detoxification enzymes that catalyse the conjugation of electrophilic substrates to glutathione. Here, we present the crystal structures of Gtt2, a GST of Saccharomyces cerevisiae, in apo and two ligand‐bound forms, at 2.23 Å, 2.20 Å and 2.10 Å, respectively. Although Gtt2 has the overall structure of a GST, the absence of the classic catalytic essential residues—tyrosine, serine and cysteine—distinguishes it from all other cytosolic GSTs of known structure. Site‐directed mutagenesis in combination with activity assays showed that instead of the classic catalytic residues, a water molecule stabilized by Ser129 and His123 acts as the deprotonator of the glutathione sulphur atom. Furthermore, only glycine and alanine are allowed at the amino‐terminus of helix‐α1 because of stereo‐hindrance. Taken together, these results show that yeast Gtt2 is a novel atypical type of cytosolic GST.     

The expression of a maize glutathione S-transferase gene in transgenic wheat confers herbicide tolerance,both in planta and in vitro

Maize (Zea mays), in common with a number of other important crop species, has several glutathione S-transferase (GST) isoforms that have been implicated in the detoxification of xenobiotics via glutathione conjugation. A cDNA encoding the maize GST subunit GST-27, under the control of a strong constitutive promoter, was introduced into explants of the wheat (Triticum aestivum L.) lines cv. Florida and L88-31 via particle bombardment, using the phosphinothricin acetyltransferase (pat) gene as a selectable marker. All six independent transgenic wheat lines recovered expressed the GST-27 gene. T₁ progeny of these wheat lines were germinated on solid medium containing the chloroacetanilide herbicide alachlor, and tolerance to this herbicide was correlated with GST-27 expression levels. In glasshouse sprays, homozygous T₂ plants were resistant not only to alachlor but also to the chloroacetanilide herbicide dimethenamid and the thiocarbamate herbicide EPTC. These additional GST-27 activities, demonstrated via over-expression in a heterologous host, have not been described previously. T₂ plants showed no enhanced tolerance to the herbicides atrazine (an s-triazine) or oxyfluorfen (a diphenyl ether). In further experiments, T₂ wheat plants were recovered from immature transgenic scutella cultured on medium containing 100 mg/l alachlor, a concentration which killed null segregant and wild-type scutella. These data indicate the potential of the maize GST-27 gene as a selectable marker in wheat transformation.     

Studies on conjugation of <Emphasis Type="Italic">Spirogyra</Emphasis> using monoclonal culture

We succeeded in inducing conjugation of Spirogyra castanacea by incubating algal filaments on agar plate. Conjugation could be induced using clone culture. The scalariform conjugation was generally observed, while lateral conjugation was rarely. When two filaments formed scalariform conjugation, all cells of one filament behaved as male and those of other filament did as female. Very rarely, however, zygospores were formed in both of pair filaments. The surface of conjugation tube was stained with fluorescently labeled-lectins, such as Bandeiraea (Griffonia) simplicifolia lectin (BSL-I) and jacalin. BSL-I strongly stained the conjugation tubes, while weakly did the cell surface of female gamete first and then that of male gamete. Jacalin stained mainly the conjugation tubes. Addition of jacalin inhibited the formation of papilla, suggesting some important role of jacalin-binding material at the initial step of formation of the conjugation tubes.     

Inhibition of sulfation of phenols in vivo by 2,6-dichloro-4-nitrophenol: selectivity of its action in relation to other conjugations in the rat in vivo

The effect of 2,6-dichloro-4-nitrophenol, an inhibitor of the sulfation of the phenolic compound harmol in vivo, on the sulfation of other phenolic substances and on various conjugation reactions has been studied in the rat in vivo. Compounds chemically related to 2,6-dichloro-4-nitrophenol were also tested as sulfation inhibitors. 2,6-Dichloro-4-nitrophenol inhibited the sulfation of phenol while it had no effect on biliary excretion of dibromosulphthalein, glucuronidation of phenolphthalein, acetylation of procainamide ethobromide or glutathione conjugation of ethacrynic acid. It is concluded that of these conjugation reactions sulfation is inhibited selectively at the dose level used. Some phenols with chloro- or nitro-substituents effectively inhibited the sulfation of harmol but to a lesser extent than 2,6-dichloro-4-nitrophenol. Many other phenols did not affect the conjugation of harmol, which is both glucuronidated and sulfated.     

The hypothalamic–hypophyseal–gonadal regulation of hepatic glutathione S-transferases in the rat

Hepatic glutathione S-transferase activities were determined with the substrates 1,2-dichloro-4-nitrobenzene and 1-chloro-2,4-dinitrobenzene. Sexual differentiation of glutathione S-transferase activities is not evident during the prepubertal period, but glutathione conjugation with 1,2-dichloro-4-nitrobenzene is 2–3-fold greater in adult males than in females. Glutathione conjugation with 1-chloro-2,4-dinitrobenzene is slightly higher in adult males than adult females. No change in activity was observed after postpubertal gonadectomy of males or females. Neonatal castration of males results in a significant decrease in glutathione conjugation with 1,2-dichloro-4-nitrobenzene. Hypophysectomy, or hypophysectomy followed by gonadectomy did result in significantly higher glutathione S-transferase activities in both sexes. These increases can be reversed by implanting an adult male or female pituitary or four prepubertal pituitaries under the kidney capsule. Postpubertal sexual differentiation of glutathione S-transferase activities is neither dependent on pituitary sexual differentiation nor pituitary maturation. Prolactin concentrations are inversely related to glutathione S-transferase activities in hypophysectomized rats with or without ectopic pituitaries. Somatotropin exogenously administered to hypophysectomized rats results in decreased glutathione S-transferase activities, whereas prolactin has no effect. Adult male rats treated neonatally with monosodium l-glutamate to induce arcuate nucleus lesions of the hypothalamus have decreased glutathione S-transferase activities towards 1,2-dichloro-4-nitrobenzene and decreased somatotropin concentrations. Our experiments suggests that sexual differentiation of hepatic glutathione S-transferase is a result of a hypothalamic inhibiting factor in the male (absent in the female). This postpubertally expressed inhibiting factor acts on the pituitary to prevent secretion of a pituitary inhibiting factor (autonomously secreted by the female), resulting in higher glutathione S-transferase activities in the adult male than the adult female.     

Morphological Drift Accompanying Nascent Population Differentiation in the Ciliate Euplotes vannus

A rare phenomenon can occur in ciliated protists of the genus Euplotes, which can undergo genetic recombination by the normal outbreeding process of conjugation following mild starvation. Occasionally, the dominant mutation for the autogamy trait arises. Individuals possessing the trait show obligate self-fertilization upon mild starvation. This yields, after normal asexual division, a population of individuals that are reproductively isolated from the parental outbreeding strain. A morphometric analysis of sympatric autogamous and non-autogamous populations of Euplotes vannus from Somalia demonstrates that there has been morphological drift in gross body proportions in the autogamous populations. However, the positional patterns of the locomotory organelles on the ventral surface remain unchanged. The changes in body proportions in the autogamous populations are relevant to the mechanics of the conjugation process, which involves fusion of the oral regions of paired cells belonging to complementary mating types.