Biologically active intermediates generated by the reduced glutathione conjugation pathway. Toxicological implications

Chemoprotective functions of glutathione S-transferases in cell lines induced to express specific isozymes by stable transfection

The authors have shown that expression of mGSTM1-1 or hGSTP1-1 in MCF-7 cells protects against DNA alkylation by 4-nitroquinoline-1-oxide (NQO) in an isozyme-specific manner and is commensurate with relative specific activity. Expression of GSTs also conferred protection against both DNA strand breaks and sister-chromatid exchange induced by NQO. Interestingly, GST expression did not protect against NQO cytotoxicity in transfected MCF-7 cell lines, although resistance to NQO cytotoxicity was observed in a T47D pi transfectant line, expressing much higher specific activity of the transfected hGSTP1-1. However, high level expression of hGSTP1-1 or mGSTM1-1 in V79 transfectants did not confer resistance to cytotoxicity, indicating that expression of GST alone is not sufficient. The authors have also shown protection against AFB1 in cell lines expressing transfected rat CYP2B1 (V79MZr2B1) and transfected mGST-Yc (mGSTA3-3). Protection was observed against both alkylation of DNA (3-fold) by [3H]AFB1 and against AFB1 cytotoxicity (7-fold). Similarly, V79MZr1A1 cells that express CYP1A1 and either transfected human or murine GSTP1-1 (< 5000 mIU/mg, CDNB) exhibited > 70% decrease in covalent labeling of total nucleic acids by [3H]BPDE. However, no protection against the cytotoxicity of BPDE was conferred by expression of hGSTP1-1. Overall, these results indicate that in some (NQO or BPDE), but not all (AFB1) cases, protection by GST expression against DNA damage is more effective than protection against cytotoxicity. In addition, there is evidence to indicate that additional factor(s) other than high GST isozyme expression level and good substrate efficacy affect the degree of protection against cytotoxicity of reactive electrophiles. This includes the differential protection against NQO cytotoxicity in T47D pi, but not V79 Xh pi-33 cells and also the recent studies which showed that expression of the MRP GS-X conjugate efflux transporter confers synergistic protection against NQO cytotoxicity when co-expressed with transfected human GSTP1-1 in MCF-7 cells. Thus, protective efficacy conferred by GST expression can vary with different cellular targets and/or experimental end-points, as well as with variations in relative specific activity or in different cellular phenotypic contexts.

Up-regulation of glutamate-cysteine ligase gene expression by butylated hydroxytoluene is mediated by transcription factor AP-1

Several regulatory elements, including AP-1 and NF-kappa B, are present in the 5'flanking region of the human glutamatex-cysteine ligase (EC 6.3.2.2, gamma-glutamyl-cysteine synthetase) catalytic subunit (GLCLC) gene. In this study, we investigated the role of redox-sensitive transcription factors in the regulation of GLCLC gene expression in LLC-PK1 cells that were exposed to the antioxidant butylated hydroxytoluene (BHT). Exposure of LLC-PK1 cells to 100 microM BHT induced expression of transcription factor AP-1, as demonstrated by an electrophoretic mobility shift assay. Peak AP-1 induction occurred after 3 h of incubation with BHT, BHT increased luciferase gene expression in cells that were transfected with a luciferase reporter vector containing an AP-1 element upstream of a SV40 promoter. Northern analysis showed that transcription of GLCLC gene in cells after incubation with BHT was increased 30% compared with control cells. Cellular glutathione concentrations were also significantly increased in cells exposed to BHT. In contrast, exposure of LLC-PK1 cells to 100 microM BHT did not alter expression of the transcription factor NF-kappa B. These results show that induction of transcription factor AP-1 by BHT is involved in transactivation of GLCLC gene expression.

Inhibition of lipid peroxidation by selenium in chick embryos

Toxic doses of Selenium (Se) (12.5 and 37.5 micro moles/Kg egg wt.) administered to 14 day old chick embryos reduced the level of lipid peroxides (LPO) significantly both in hepatic and brain tissues. However, the LPO formation was inhibited maximally at early hours after exposure (3 h and 6 h) and it was gradually increased thereafter to normal levels by 48 h. Further, the effect of Se on some of the antioxidant enzymes like glutathione peroxidase (GPx), glutathione transferase (GST), glutathione reductase (GR), superoxide dismutase (SOD) and catalase were studied. In hepatic tissues GPx, GST and SOD activities were increased at 6 h post treatment with no change in the activities of GR and catalase. However, at 48 h GST and catalase activities were found to be increased, while GPx, GR and SOD activities were not affected. In brain at 6 h increase in the activities of GPx, GST, GR and SOD and no change of catalase were observed. At 6 h glutathione (GSH) levels were reduced in both hepatic and brain tissues. Our results suggest that the elevated levels of antioxidant enzymes at early hours were successful in bringing LPO levels back to normal.

Pharmacokinetic data in the evaluation of the safety of food and color additives

Safety evaluation of food and color additives intended for human use is usually based on toxicity data obtained from animal studies; human data are rarely available. The extrapolation of animal data to humans is often controversial. The important role that pharmacokinetic data could play in the safety evaluation of food and color additives is now widely recognized. This paper reviews the current scientific knowledge concerning the application of properly designed pharmacokinetic studies to the evaluation of the safety of food and color additives. In principle, pharmacokinetic data can be useful not only in designing, interpreting, and extrapolating animal toxicity studies to humans, but also in providing insight into the mechanisms of toxicity. Examples of such applications are provided.

Glutathione transferases and cancer

The glutathione transferases, a family of multifunctional proteins, catalyze the glutathione conjugation reaction with electrophilic compounds biotransformed from xenobiotics, including carcinogens. In preneoplastic cells as well as neoplastic cells, specific molecular forms of glutathione transferase are known to be expressed and have been known to participate in the mechanisms of their resistance to drugs. In this article, following a brief description of recently identified molecular forms, we review new findings regarding the respective molecular forms involved in carcinogenesis and anticancer drug resistance, with particular emphasis on Pi class forms in preneoplastic tissues. The rat Pi class form, GST-P (GST 7-7), is strongly expressed not only in hepatic foci and hepatomas, but also in initiated cells that occur at the very early stages of chemical hepatocarcinogenesis, and is regarded as one of the most reliable markers for preneoplastic lesions in the rat liver. 12-O-Tetradecanoylphorbol-13-acetate (TPA)-responsive element-like sequences have been identified in upstream regions of the GST-P gene, and oncogene products c-jun and c-fos are suggested to activate the gene. The Pi-class forms possess unique enzymatic properties, including broad substrate specificity, glutathione peroxidase activity toward lipid hydroperoxides, low sensitivity to organic anion inhibitors, and high sensitivity to active oxygen species. The possible functions of Pi class glutathione transferases in neoplastic tissues and drug-resistant cells are discussed.

Involvement of glutathione in 1-naphthylisothiocyanate (ANIT) metabolism and toxicity to isolated hepatocytes

1-Naphthylisothiocyanate (ANIT) is a model compound which causes cholestasis in laboratory animals. Various biochemical and morphological changes including biliary epithelial and parenchymal cell necrosis occur in the liver of animals treated with ANIT. Although the mechanism(s) for these effects is not understood, a role for glutathione (GSH) in toxicity has been implicated. The possible role of GSH in hepatocellular toxicity caused by ANIT was investigated in this study. Treatment of freshly isolated rat hepatocytes with ANIT caused a concentration- and time-dependent depletion of cellular GSH that preceded lactate dehydrogenase (LDH) leakage. Analysis of the incubation medium indicated that the majority of the cellular GSH which was lost was present extracellularly as GSH or as a GSH-releasing compound. Mixing ANIT with GSH at pH 7.5 yielded a compound that was characterized by HPLC and fast atom bombardment-mass spectrometry (FAB-MS) S-(N-naphthyl-thiocarbamoyl)-L-glutathione (GS-ANIT). When dissolved in aqueous solutions at neutral pH, 95% of GS-ANIT dissociated to yield free ANIT and GSH. Under conditions designed to maximize formation and stability of GS-ANIT, GS-ANIT was found in the extracellular medium of hepatocytes treated with ANIT. Treatment of hepatocytes with the GS-ANIT caused GSH depletion and LDH leakage similar to that observed with equimolar amounts of ANIT. These data suggest that ANIT depletes hepatocytes of GSH through a reversible conjugation process. Such a process may play a role in the toxicity of ANIT.

Suppressive effect of geniposide on the hepatotoxicity and hepatic DNA binding of aflatoxin B1 in rats

The effects of geniposide pretreatment on both hepatic aflatoxin B1 (AFB1)-DNA binding and AFB1 hepatotoxicity in rats has been examined. For these studies, male Sprague-Dawley rats were treated with AFB1 (2 mg/kg) by i.p. administration, and the different degrees of hepatic damage were revealed by the elevations of levels of serum marker enzymes such as aspartate aminotransferase (AST), alanine amino-transferase (ALT) and gamma-glutamyltranspeptidase (gamma-GT). After pretreatment of animals with geniposide (10 mg/kg) daily for 3 consecutive days, the enzyme elevations were significantly suppressed. This suggested that the geniposide possessed chemopreventive effects on the early acute hepatic damage induced by AFB1. Under these experimental conditions, consistent elevation of the activities of glutathione S-transferase (GST) and gamma-glutamylcysteine synthetase but not glutathione peroxidase (GSH-Px) and gamma-glutamyltranspeptidase were observed. Treatment of rats with geniposide significantly lowered hepatic GSH and GSSG levels, but the ratio of GSH to GSSG was not changed. Geniposide treatment also decreased AFB1-DNA adduct formation in AFB1-treated animals. From these results, we suggest that the protective effect of geniposide on AFB1 hepatotoxicity in rats might be due to the hepatic tissues' defense mechanisms that involve the enhanced GST activity for AFB1 detoxication and induction gamma-glutamylcysteine synthetase for GSH biosynthesis.

The effect of glutathione depletion by buthionine sulphoximine on 1-cyano-3,4-epithiobutane toxicity

The effect of glutathione (GSH) depletion by buthionine sulphoximine (BSO) on the nephrotoxicity and GSH-enhancing effect of the naturally occurring, crucifer-derived nitrile 1-cyano-3.4-epithiobutane (CEB), was investigated. Male Fischer 344 rats were administered 50 or 125 mg CEB/kg body weight by gavage with or without prior ip treatment with 550 mg/kg body weight L-BSO. One group of control animals was treated with water only by gavage, while another group was pretreated with BSO and then given water by gavage. Liver and kidney samples were taken 48 hr after CEB treatment for GSH determinations and histological examination. The high-dose CEB without BSO resulted in increased GSH in liver and kidney, marked karyomegaly in the pars recta of renal proximal tubules and tubular epithelial necrosis, which was limited to a few renal tubules. The low-dose CEB alone resulted in increased hepatic GSH and mild karyomegaly. Pretreatment with BSO abrogated the tubular necrosis and karyomegaly induced by either CEB dose. BSO pretreatment inhibited low-dose CEB-induced GSH enhancement in the liver. The combined BSO and high-dose CEB treatment still resulted in increased hepatic GSH, although the increase was less than that observed with high-dose CEB alone. In the kidney, BSO pretreatment abrogated the high-dose CEB-induced increase in GSH, but GSH content was not significantly different from that with high- or low-dose CEB alone. These results provide evidence that CEB conjugation may be a bioactivation reaction with the conjugate involved in nephrotoxicity. The conjugate may also be involved in increasing renal and hepatic GSH.

Bioactivation of xenobiotics by formation of toxic glutathione conjugates

Evidence has been accumulating that several classes of compounds are converted by glutathione conjugate formation to toxic metabolites. The aim of this review is to summarize the current knowledge on the biosynthesis and toxicity of glutathione S-conjugates derived from halogenated alkanes, halogenated alkenes, and hydroquinones and quinones. Different types of toxic glutathione conjugates have been identified and will be discussed in detail: (i) conjugates which are transformed to electrophilic sulfur mustards, (ii) conjugates which are converted to toxic metabolites in an enzyme-catalyzed multistep mechanism, (iii) conjugates which serve as a transport form for toxic quinones and (iv) reversible glutathione conjugate formation and release of the toxic agent in cell types with lower glutathione concentrations. The kidney is the main, with some compounds the exclusive, target organ for compounds metabolized by pathways (i) to (iii). Selective toxicity to the kidney is easily explained due to the capability of the kidney to accumulate intermediates formed by processing of S-conjugates and to bioactivate these intermediates to toxic metabolites. The influences of other factors participating in the renal susceptibility are discussed.

1,2-Dichloropropane hepatotoxicity in rats after inhalation exposure

The hepatic effects of 1,2-dichloropropane (DCP) were investigated in male Wistar rats exposed to 15, 50, 100, 250, 450, 1000, 1300, 1800 or 4900 mg DCP m-3. At the end of a 4-h period of exposure, average blood DCP levels were 0.025 and 5.38 micrograms ml-1 in animals treated with 15 and 1300 mg m-3, respectively. Blood DCP concentrations were correlated with the air DCP concentrations in the inhalation chamber. At DCP concentrations of 100 mg m-3 or higher, the liver non-protein thiol (NPT) content was significantly reduced. Assays performed 20 h after 4-h DCP exposure showed that exposure to 100-1000 mg DCP m-3 had no effect on hepatic NPT levels. The NPT content increased only in the liver of rats exposed to higher (1300-4900 mg m-3) DCP concentrations. Treatment with DCP did not cause hepatic lipid peroxidation and did not modify total protein content. The observed changes in liver cell thiol homeostasis are likely to reflect the action of reactive intermediates formed during DCP metabolism. These changes can occur in rats following exposure to considerably low levels of DCP vapour.

Effect of ethanol on hepatotoxicity and hepatic DNA-binding of aflatoxin B1 in rats

The hepatocarcinogen aflatoxin B1 is converted to reactive metabolites that bind covalently to cellular macromolecules. These metabolites may also react with glutathione, resulting in the formation of glutathione conjugates and detoxication of the reactive metabolite. When rats were pretreated with ethanol by gastric intubation at a dose of 100 mmol/kg, 6 hr (the time of maximal GSH depletion) before the administration of aflatoxin B1, the covalent binding of 8,9-epoxide-aflatoxin B1 to DNA in vivo was increased by 47% and the hepatotoxicity was also potentiated. However, the covalent binding was not increased by pretreatment with ethanol 18 hr (time with approximately normal GSH levels) before administration of the toxin, and no potentiation of hepatotoxicity was observed. Pretreatment with a non-toxic dose of ethanol had no effects on the activity of glutathione S-transferase and glutathione peroxidase. These results suggest that the depletion of GSH and the increased formation of DNA-adduct from the liver constitute an important mechanism for the potentiation of aflatoxin B1-induced hepatotoxicity by ethanol.

Is the toxicity of cysteine conjugates formed during mercapturic acid biosynthesis relevant to the toxicity of covalently bound drug residues?

In this brief review, we have focused on the relevance of the data on cysteine conjugate toxicity to the potential hazard of bound drug residues. A resonable scenario, based on assumptions as well as literature data, has been presented for the release of cysteine conjugates of drug residues from protein. Furthermore, we have presented evidence that should this occur, the conjugate would be bioavailable. Finally, the mechanisms which could lead to cysteine conjugate-induced toxicity have been discussed. The question which must be answered is, how realistic is the treat of toxicity to the consumer from cysteine-bound drug residues in food products? Based on the data presented here, the danger is minimal, though it cannot be excluded. This is particularly true of the potential for renal complications. However, an important caveat which must not be overlooked is the marked species differences in cysteine conjugate toxicity. Though S-(1,2LD50-dichlorovinyl)-L-cysteine (DCVC) is a renal toxin in rodent models (LD50 = 66-83 mg/kg) [88], a single dose of 4-5 mg/kg causes fatal aplastic anemia in calves [44,59]. Though such a response has never been reported for any other cysteine conjugate, these data must be reckoned with if attempts are made to place acceptable limits on the amount of residues allowable in food products.

A role for a new vascular enzyme in the metabolism of xenobiotic amines

Although it has long been thought that environmental toxins may play an underlying role in vascular diseases such as atherosclerosis, this concept is not supported by any clear-cut experimental evidence of toxic metabolism by cardiovascular enzymes. In this study, we demonstrate that allylamine, a selective cardiovascular toxin in vivo, is actively metabolized in vitro by a purified vascular enzyme (semicarbazide-sensitive amine oxidase), which has been localized recently to vascular smooth muscle cells. Oxidative deamination of allylamine to a highly toxic aldehyde, acrolein, was blocked through enzyme inhibition by semicarbazide-sensitive amine oxidase suggests that this vascular enzyme's physiological role may include metabolism of exogenous amines.

Contraluminal para-aminohippurate (PAH) transport in the proximal tubule of the rat kidney. VI. Specificity: amino acids, their N-methyl-, N-acetyl- and N-benzoylderivatives; glutathione- and cysteine conjugates, di- and oligopeptides

In order to evaluate the specificity of the renal contraluminal PAH transport system for amino acids, oligopeptides and their conjugates, the inhibitory potency of these substances against contraluminal [3H] PAH influx has been determined. For this, inhibition of 3H-PAH flux from the interstitium into cortical tubular cells of the rat kidney in situ has been measured. Apparent Ki values were evaluated by a computer program assuming competitive inhibition. Unconjugated amino acids (glycine, cysteine, alanine, leucine, phenylalanine, tyrosine, aspartate, glutamate, arginine, ornithine and lysine) do not inhibit [3H] PAH influx. The very hydrophobic tryptophan, however, does. N-alpha-methylation does not change this behaviour. N-alpha-acetylation does not evoke interaction with the PAH transporter when it occurs with glycine, cysteine (to yield mercapturic acid), arginine, ornithine and lysine. However, it renders alanine, leucine, phenylalanine, tryptophan, L-aspartate moderately, and L-glutamate strongly, inhibitory. The acetylated D-isomers of alanine, leucine and phenylalanine exert a higher inhibitory potency compared with the respective L-isomers. N-alpha-benzoylation of L-lysine is ineffective. N-alpha-benzoylation, however, evokes interaction with the PAH transporter, when it occurs with ornithine less than arginine less than histidine less than glycine = leucine less than alanine = phenylalanine = aspartate = glutamate. Dipeptides interact with the PAH transporter according to their hydrophobicity (Nozaki scale down to 0.9, Fauchère scale up to 1.0). N-acetylation does not change this behaviour. Hydrophobicity also renders oligopeptides, as angiotensin II, inhibitory against PAH transport. Similarly the anionic angiotensin I converting enzyme inhibitors Captopril, Enalapril and Ramipril inhibit contraluminal PAH influx.

Influence of aging on chemically induced hepatotoxicity: role of age-related changes in metabolism

The effects on hepatotoxicity of age-associated changes in drug metabolism are not always straightforward. In the case of allyl alcohol hepatotoxicity in male rats, there is a good relationship between increased metabolic activation by liver alcohol dehydrogenase and enhanced hepatotoxicity in old age. With regard to two other hepatotoxicants, some tentative conclusions about the role of metabolism can be drawn, but they must be tempered with caution due to gaps in the available information. Acetaminophen-induced hepatotoxicity is reduced in old age, and decreased formation of the toxic intermediate may be the reason. There is a prominent effect of aging on acetaminophen conjugation, a shift from sulfation to glucuronidation, but this change does not affect total clearance. The situation with carbon tetrachloride is difficult to interpret because the final outcome is unaltered hepatotoxicity in old age. Nevertheless, the available data suggest that an age-associated decrease in activation of carbon tetrachloride is counterbalanced by a loss in resistance to lipid peroxidation. These conclusions are summarized in Table 5. Again, it must be emphasized that all of these age-dependent changes in toxicity could be related to effects on other systems that are not necessarily involved in the metabolism of hepatotoxicants. Future research is needed to identify pathways of metabolic activation and detoxification in which age-dependent changes occur that result in significant changes in hepatotoxicity. The entire sequence of events from changes at the molecular level to their sequelae at the level of the cell, tissue and intact animal should be investigated, and the results should be confirmed in more than one mammalian model of aging. The aim would be to identify basic mechanisms that result in increased hazard for the aged liver from exposure to toxic compounds.

Relationship between 1-chloro-2,4-dinitrobenzene-induced cytoskeletal perturbations and cellular glutathione

Exposure of 3T3 cells to micromolar doses of 1-chloro-2,4-dinitrobenzene, a substrate for glutathione-S-transferase, resulted in a rapid depletion of total cellular glutathione accompanied by disassembly of microtubules as visualized by fluorescence microscopy. However, prolonged incubation resulted in cellular recovery from 1-chloro-2,4-dinitrobenzene insult as evidenced by a steady rise in total cellular glutathione accompanied by microtubule reassembly to their normal organization 5 hours after treatment. To evaluate the role of total cellular glutathione in modulating the 1-chloro-2,4-dinitrobenzene-induced cytoskeletal perturbation, we used 1-chloro-2,4-dinitrobenzene and/or buthionine sulfoximine, an effective irreversible inhibitor of glutathione synthesis, to manipulate cellular glutathione levels. Incubation of 3T3 cells with 2.5 microM 1-chloro-2,4-dinitrobenzene and 250 microM buthionine sulfoximine for 5 hours resulted in a complete depletion of total cellular glutathione accompanied by essentially complete loss of microtubules and marked alterations in the density and distribution pattern of microfilaments. Buthionine sulfoximine enhanced markedly the extent and duration of cellular glutathione depletion and the severity of microtubule disruption of 3T3 cells over the level achieved by 1-chloro-2,4-dinitrobenzene treatment alone. Furthermore, buthionine sulfoximine also prevented the restoration of cellular glutathione content and microtubule reassembly that normally were evident 5 hours after 1-chloro-2,4-dinitrobenzene treatment. Exposure of 3T3 cells to 50 microM 2-cyclohexene-1-one, which depletes free glutathione by conjugation, resulted in a complete depletion of total cellular glutathione content without altering the microtubule organization. These results suggest that the total glutathione content may be important for cellular recovery from 1-chloro-2,4-dinitrobenzene-mediated cytoskeletal injuries, and that microtubule disassembly observed in 1-chloro-2,4-dinitrobenzene-treated cells probably results from depletion of cellular glutathione coupled with binding to tubulin and/or other microtubule components.

Nephrotoxicity of mercapturic acids of three structurally related 2,2-difluoroethylenes in the rat. Indications for different bioactivation mechanisms

The biotransformation and the hepato- and nephrotoxicity of the mercapturic acids (N-acetyl-1-cysteine S-conjugates) of three structurally related 2,2-difluoroethylenes were investigated in vivo in the rat. All mercapturic acids appeared to cause nephrotoxicity, without any measureable effect on the liver. The mercapturic acid of tetrafluoroethylene (TFE-NAC) appeared to be the most potent nephrotoxin, causing toxicity upon an i.p. dose of 50 mumol/kg. The mercapturic acids of 1,1-dichloro-2,2-difluoroethylene (DCDFE-NAC) and 1,1-dibromo-2,2-difluoroethylene (DBDFE-NAC) were nephrotoxic at slightly higher doses, i.e. at 75 and 100 mumol/kg, respectively. In the urine of TFE-NAC-treated rats significant amounts of difluoroacetic acid (DFAA) could be detected. With increasing doses, the relative amount of DFAA in urine increased progressively (5-18% of dose). In urine of rats treated with DCDFE-NAC and DBDFE-NAC, however, the corresponding dihaloacetic acids, dichloroacetic acid and dibromoacetic acid, could not be detected. Formation of DFAA and pyruvate could also be observed during in vitro metabolism of the cysteine conjugate of tetrafluoroethylene (TFE-CYS) by rat renal cytosol. Inhibition by aminooxyacetic acid (AOA) pointed to a beta-lyase dependency for the DFAA-formation. Next to DFAA and pyruvate, also formation of hydrogen sulfide and thiosulfate could be detected. These results suggest that TFE-CYS is bioactivated to a significant extent to difluorothionacyl fluoride, which most likely is subsequently hydrolysed to difluorothio(no)acetic acid and difluoroacetic acid. According to formation of pyruvate, the cysteine conjugates derived from DCDFE-NAC and DBDFE-NAC also were efficiently metabolized by rat renal beta-lyase. However, the formation of corresponding dihaloacetic acids, dichloroacetic acid and dibromoacetic acid, could not be detected in vitro at all. Only very small amounts of hydrogen sulfide and thiosulfate were detected. These results suggest that bioactivation of the latter two conjugates to a dichloro- or dibromothionoacyl fluoride represents only a minor route. Because of better leaving group abilities of chloride and bromide compared to fluoride, rearrangement of the initially formed ethanethiol to a thiirane might be favoured. Based on the present in vivo and in vitro data, it is concluded that the nephrotoxicity of the structurally related mercapturic acids of 2,2-difluoroethylenes is dependent on halogen substitution and presumably the result of at least two different mechanisms of bioactivation.

The use of alkoxycarbonyl derivatives for the mass spectral analysis of drug-thioether metabolites. Studies with the cysteine, mercapturic acid and glutathione conjugates of acetaminophen

Alkoxycarbonyl derivatives of the cysteine-, N-acetylcysteine- and glutathione conjugates of acetaminophen have been prepared in aqueous buffer solutions and their chromatographic and mass spectrometric properties examined. Structurally informative fragmentation patterns of the cysteine- and N-acetylcysteine derivatives were obtained when their methyl esters were subjected to analysis by direct insertion chemical ionization (CH4) mass spectrometry, although field desorption and liquid secondary ion mass spectrometric techniques were required in order to obtain satisfactory spectral data for derivatives of the glutathione adduct. Treatment of ethoxycarbonyl derivatives of the three acetaminophen metabolites with N-methyltrifluoroacetamide-based silylating reagents led to the formation of a common volatile product which was ideally suited to analysis by gas chromatography/electron impact mass spectrometry. A mechanism is proposed for the formation of this novel derivative, which appears to possess a benzo-1,3-thioxalane structure, and its mass spectral characteristics are reported. Finally, the utility of alkoxycarbonyl derivatives for the analysis of drug-thioether conjugates in biological fluids is discussed in terms of their advantages for aqueous phase derivatization, purification by high-performance liquid chromatography and characterization by mass spectrometry.

Glutathione transferases--structure and catalytic activity

The glutathione transferases are recognized as important catalysts in the biotransformation of xenobiotics, including drugs as well as environmental pollutants. Multiple forms exist, and numerous transferases from mammalian tissues, insects, and plants have been isolated and characterized. Enzymatic properties, reactions with antibodies, and structural characteristics have been used for classification of the glutathione transferases. The cytosolic mammalian enzymes could be grouped into three distinct classes--Alpha, Mu, and Pi; the microsomal glutathione transferase differs greatly from all the cytosolic enzymes. Members of each enzyme class have been identified in human, rat, and mouse tissues. Comparison of known primary structures of representatives of each class suggests a divergent evolution of the enzyme proteins from a common precursor. Products of oxidative metabolism such as organic hydroperoxides, epoxides, quinones, and activated alkenes are possible "natural" substrates for the glutathione transferases. Particularly noteworthy are 4-hydroxyalkenals, which are among the best substrates found. Homologous series of substrates give information about the properties of the corresponding binding site. The catalytic mechanism and the active-site topology have been probed also by use of chiral substrates. Steady-state kinetics have provided evidence for a "sequential" mechanism.

Biosynthesis and biotransformation of glutathione S-conjugates to toxic metabolites

The material presented in this review deals with the hypothesis that the nephrotoxicity of certain halogenated alkanes and alkenes is associated with hepatic biosynthesis of glutathione S-conjugates, which are further metabolized to the corresponding cysteine S-conjugates. Some glutathione or cysteine S-conjugates may be direct-acting nephrotoxins, but most cysteine S-conjugates require bioactivation by renal, pyridoxal phosphate-dependent enzymes, such as cysteine conjugate beta-lyase (beta-lyase). The biosynthesis of glutathione S-conjugates is catalyzed by both the cytosolic and the microsomal glutathione S-transferases, although the latter enzyme is a better catalyst for the reaction of haloalkenes with glutathione. When glutathione S-conjugate formation yields sulfur mustards, as occurs with vicinal-dihaloethanes, the S-conjugates are direct-acting toxins. In contrast, the S-conjugates formed from fluoro- and chloroalkenes yield S-alkyl- or S-vinyl glutathione conjugates, respectively, which are metabolized to the corresponding cysteine S-conjugates by gamma-glutamyltransferase and dipeptidases; inhibition of these enzymes blocks the toxicity of the glutathione S-conjugates. The cysteine S-conjugates must be metabolized by beta-lyase for the expression of toxicity; the beta-lyase inhibitor aminooxyacetic acid blocks the toxicity of cysteine S-conjugates, and the corresponding alpha-methyl cysteine S-conjugates, which cannot be metabolized by beta-lyase, are not toxic. Moreover, probenecid, an inhibitor of renal anion transport system, blocks the toxicity of cysteine S-conjugates, which cannot be metabolized by beta-lyase, are not toxic. Moreover, probenecid, an inhibitor of renal anion transport system, blocks the toxicity of cysteine S-conjugates. Homocysteine S-conjugates are also potent cyto- and nephrotoxins. The high renal content of gamma-glutamyltransferase and the renal anion transport system are probably determinants of kidney tissue as a target site. Biochemical studies indicate that renal mitochondrial dysfunction is produced by the cysteine S-conjugates. Finally, some of the glutathione and cysteine conjugates are mutagenic in the Ames test, and reactive intermediates formed by the action of beta-lyase may contribute to the nephrocarcinogenicity of certain chloroalkenes.

In vivo metabolism of the cardiovascular toxin, allylamine

Previous evidence from this laboratory demonstrated that allylamine, a known cardiovascular toxin, is metabolized in vitro to acrolein, which has been hypothesized to act as a distal toxin. In this study, 3-hydroxypropylmercapturic acid was isolated and identified by MS, NMR, and 2D-NMR spectroscopy as the sole urinary metabolite of allylamine metabolism in vivo. Parallel experiments showed reduced glutathione (GSH) depletion in several organs (most marked in aorta, blood, and lung), which is consistent with GSH conjugation of the proposed acrolein intermediate. These findings indicate that allylamine was metabolized in vivo to a highly reactive aldehyde which was converted to a mercapturic acid through a GSH conjugation pathway; the exact mechanisms of cellular damage remain unclear.

The glutathione S-transferases of fish

Substantial soluble glutathione S-transferase activity and millimolar reduced glutathione (GSH) are present in most tissues of both teleosts and elasmobranchs. The hepatic enzymes of fish conjugate a range of electrophilic substrates with GSH, although their specificities are less broad than those of the transferases in rodent liver. There is no good evidence that fish transferases have ligandin-like activity or a 'suicide' function. All fish livers tested have several transferase isoenzymes. They are dimers of subunits whose Mrs are about 25 kDa and which may have different catalytic properties. In some species transferase activity is induced by agents such as phenols or 3-methylcholanthrene. Glutathione S-transferases are important detoxication enzymes in fish.