An enzyme from rat liver catalysing conjugations with glutathione

Purification and characterization of glutathione S-transferases in human retina

Human retina has two forms of glutathione (GSH) S-transferases. These forms having pI 4.5 and greater than 10 have been purified and their kinetic, structural and immunological characteristics are described. Both the enzymes of human retina do not express glutathione peroxidase II activity. The anionic enzyme (pI 4.5) of retina cross reacts with the antibodies raised against the anionic GSH S-transferases of human lung and placenta but does not cross react with the antibodies raised against the cationic enzymes of human liver. On the other hand, the cationic enzyme (pI greater than 10) of human retina cross reacts with the antibodies raised against the cationic GSH S-transferases of human liver but not with antibodies raised against the anionic enzymes of lung and placenta. Differences in the kinetic characteristics of the two forms of human retinal GSH S-transferases are also indicated. Results of these studies suggest that the anionic enzyme of retina may be similar to the anionic enzymes of lung and placenta. However, the cationic form appears to be different from all other GSH S-transferases of human tissues characterized so far. Human retina has selenium dependent glutathione peroxidase I and in this respect is different from bovine retina which has no glutathione peroxidase I as demonstrated in earlier studies.

The major rat heart glutathione S-transferases are anionic isozymes composed of Yb size subunits

The GSH S-transferases from rat heart cytosol has been purified by S-hexylglutathione-linked Sepharose-6B affinity chromatography. The majority (approximately 80%) of these GSH S-transferases are anionic isozymes which can be resolved further by DEAE-cellulose column chromatography and isoelectric focusing. They are mainly composed of Yb size (Mr = 27,000) subunits with different substrate specificity patterns from the rat liver anionic GSH S-transferases. The major cationic GSH S-transferases from liver are not expressed in rat heart. Although some cationic GSH S-transferases from rat heart can be purified by CM-cellulose column chromatography they are composed of major subunits of Yb electrophoretic mobility.

Rat lung glutathione S-transferases. Evidence for two distinct types of 22000-Mr subunits

Two immunologically distinct types of 22000-Mr subunits are present in rat lung glutathione S-transferases. One of these subunits is probably similar to Ya subunits of rat liver glutathione S-transferases, whereas the other subunit Ya' is immunologically distinct. Glutathione S-transferase II (pI7.2) of rat lung is a heterodimer (YaYa') of these subunits, and glutathione S-transferase VI (pI4.8) of rat lung is a homodimer of Ya' subunits. On hybridization in vitro of the subunits of glutathione S-transferase II of rat lung three active dimers having pI values 9.4, 7.2 and 4.8 are obtained. Immunological properties and substrate specificities indicate that the hybridized enzymes having pI7.2 and 4.8 correspond to glutathione S-transferases II and VI of rat lung respectively.

Human glutathione S-transferases. Characterization of the anionic forms from lung and placenta

Anionic glutathione S-transferases were purified from human lung and placenta. Chemical and immunochemical characterization, including polyacrylamide-gel electrophoresis, gave strong evidence that the anionic lung and placental enzymes are chemically similar, if not identical, proteins. The electrophoretic mobilities of both proteins were identical in conventional alkaline gels as well as in gels containing sodium dodecyl sulphate. Gel filtration of the intact active enzyme established an Mr value of 45000; however, with sodium dodecyl sulphate/polyacrylamide-gel electrophoresis under dissociating conditions a subunit Mr of 22500 was obtained. Amino acid sequence analysis of the N-terminal region of the placental enzyme revealed a single polypeptide sequence identical with that of lung. Results obtained from immunoelectrophoresis, immunotitration, double immunodiffusion and rocket immunoelectrophoresis also indicated the anionic lung and placental enzymes to be closely similar. The chemical similarity of these two proteins was further supported by protein compositional analysis and fragment analysis after chemical hydrolysis. Immunochemical comparison of the anionic lung and placental enzymes with human liver glutathione S-transferases revealed cross-reactivity with the anionic omega enzyme, but no cross-reactivity was detectable with the cationic enzymes. Comparison of the N-terminal region of the human anionic enzyme with reported sequences of rat liver glutathione S-transferases gave strong evidence of chemical similarity, indicating that these enzymes are evolutionarily related. However, computer analysis of the 30-residue N-terminal sequence did not show any significant chemical similarity to any other reported protein sequence, pointing to the fact that the glutathione S-transferases represent a unique class of proteins.

The hepatic glutathione transferases of the male little skate, Raja erinacea

Five cytosolic glutathione transferases were isolated from the liver of the male little skate, Raja erinacea, a marine elasmobranch. They were designated E-1 through E-5 in order of their elution from a DEAE-cellulose column with a 0 to 100 mM KCl gradient in 0.01 M Tris (pH 8.0). Each eluted peak of glutathione transferase activity, after concentration, was applied to an affinity column prepared by reaction of epoxy-activated Sepharose 6B with glutathione (GSH). Elution of the various glutathione transferases from this column with GSH resulted in the further purification of each enzyme; the major glutathione transferase, E-4 and E-1, were purified to apparent homogeneity by this procedure. Skate glutathione transferase E-4 is dimeric and the subunits are either very similar or identical in molecular weight (about 26 000 daltons). Enzymes E-2 through E-5 were acidic proteins (pI less than 7.0) and had high specific glutathione transferase activity (0.3--12 mumol/min/mg protein) with benzo[a]pyrene 4,5-oxide (BPO) as substrate, whereas the other enzyme (E-1) had low activity (0.01 mumol/min/mg) with BPO and a basic pI (greater than 9.5). Bilirubin and hematin, non-substrate ligands, bound tightly to homogeneous E-4, with dissociation constants in the micromolar range.

Comparative effect of the induction of the subunits of rat liver glutathione S-transferases by butylated hydroxytoluene

When butylated hydroxytoluene (BHT) was administered to rats, the smallest subunit Ya (Mr 22,000) of rat liver GSH S-transferases was found to undergo maximum induction. It is suggested that the differential induction of GSH S-transferase activities by BHT towards different substrates may be due to the differences in the induction of the constituent subunits of GSH S-transferases.

Kinetic studies on a glutathione S-transferase from the larvae of Costelytra zealandica

Of the glutathione S-transferases from the New Zealand grass grub (Costelytra zealandica) active in conjugating the model substrate 1-chloro-2,4-dinitrobenzene, the most active was isolated in a functionally homogeneous form. This had an isoelectric point of 8.7. Preliminary evidence suggests that it is a homodimer with subunits of Mr 23 500. The dependence of the enzyme-catalysed reaction on substrate concentration was analysed in terms of the rate equation characteristic of Ordered Bi Bi or Rapid-Equilibrium Random mechanisms. Evidence was found for a critical ionizing event at pH 9.3 at 37 degrees C. This event appears to involve a twofold change in charge on the enzyme, which may be the result of co-operative ionizations rather than independent ionizations. This appears to affect neither the binding of the aromatic substrate to the enzyme, nor the maximum catalytic velocity of the enzyme-catalysed reaction. The variation of the kinetics with temperature was studied. Apparent thermodynamic parameters characteristic of the reaction were derived. The possible relevance of the temperature-dependence of the enzyme-catalysed reaction in vivo is discussed.

Detoxification of xenobiotics by glutathione S-transferases in erythrocytes: the transport of the conjugate of glutathione and 1-chloro-2,4-dinitrobenzene

The incubation of human erythrocytes with 1-chloro-2,4-dinitrobenzene (CDNB) results in almost quantitative conjugation of glutathione (GSH) to form S-(2,4-dinitrophenyl) glutathione. The reaction is catalysed by erythrocyte glutathione S-transferase. During the present studies we have identified the conjugate in the incubation medium of CDNB-treated erythrocytes, indicating that the conjugate of GSH and CDNB is transported out by the erythrocytes. Quantitation of the conjugate in the incubation medium by amino acid analysis and thin layer chromatography indicates that the erythrocytes transport the conjugate at an approximate rate of 140 nmol/h/ml erythrocytes. The transport of the conjugate is inhibited by sodium fluoride. Exhaustion of ATP from the erythrocytes results in a significant decrease in the rate of transport which is restored with the regeneration of ATP by incubating the erythrocytes with adenine and inosine. This indicates that the transport of conjugate is an energy dependent process.

The effect of propylthiouracil on glutathione S-transferase activity of rat spleen in vitro and in vivo

Propylthiouracil (PTU) inhibited glutathione (GSH) S-transferase (EC 2.5.1.18) activity of rat spleens in a concentration dependent manner in vitro. PTU (1.5 mmoles/kg) treatment of rats for 1 or 2 weeks caused a decrease in leukocyte number and spleen weight. Nevertheless, GSH S-transferase activity was not affected by the same treatment.

Effect of butylated hydroxytoluene on glutathione S-transferase and glutathione peroxidase activities in rat liver

When rats were fed a diet containing 0.4% (w/w) butylated hydroxytoluene (BHT), glutathione (GSH) S-transferase activity towards 1-chloro-2,4-dinitrobenzene (CDNB) increased approximately 3-fold in the liver. Immunotitration studies using the antibodies raised against rat liver GSH S-transferase B and GSH S-transferase A and C indicated that the increase in GSH S-transferase activity was probably due to de novo protein synthesis. Since some forms of rat liver GSH S-transferases express GSH peroxidase II activity, a concomitant increase in GSH peroxidase II was expected. However, GSH peroxidase II activity in the liver of BHT-treated rats remained unchanged. Gel filtration of supernatant fractions from livers of control and BHT-treated rats, followed by isoelectric focusing, indicated that BHT induced the activity of hepatic GSH S-transferases, without any apparent effect on GSH peroxidase II activity.

Biochemical and immunological analysis of an abundant form of glutathione S-transferase, in mouse testis

One of the major forms of glutathione S-transferase (designated as Ft transferase) has been identified and purified to near homogeneity from mouse testis. The purification was achieved by ammonium sulfate fractionation, DEAE cellulose chromatography, hydroxylapatite chromatography and the preparative isoelectric focusing. Purified Ft transferase has an isoelectric point of 4.9 +/- 0.3 and was shown to be a homodimer with a native molecular weight of about 50000. Immunologically, antisera to Ft transferase do not crossreact with F2 or F3 transferase. However, a weak cross reactivity was observed between the antisera to F3 transferase and FT transferase. Biochemical properties of purified Ft transferase are similar to those transferases isolated from mouse liver. Tissue distributions of the multiple forms of glutathione S-transferase were examined by column isoelectric focusing of various mouse tissue homogenates. It was found that mouse Ft transferase is present only in testis as a major form and in brain as a minor form, but not in other tissues that were examined.

Cloning and sequence analysis of a cDNA plasmid for one of the rat liver glutathione S-transferase subunits

We describe the construction and characterization of a cDNA plasmid for one of the rat liver glutathione S-transferase subunits. Poly(A)-RNA isolated from rat livers was enriched for glutathione S-transferase mRNA activity and used as templates to synthesize double stranded cDNA. The double stranded cDNAs were annealed to pBR322 through terminal deoxynucleotidyl transferase generated GC-tails followed by transformation into E. coli. Several candidate clones were selected by colony hybridization using polynucleotide kinase labeled liver and testis poly(A)-RNA probes. These candidate clones were further characterized by hybrid-selected translation of mRNA followed by immunoprecipitation and SDS gel electrophoresis. The positive clone, pGTR112 was mapped with restriction endonuclease analysis and sequenced by the chemical method of Maxam and Gilbert. The largest upen reading frame contains 142 amino acids very rich in Arg and Lys residues. The C-terminal residue phenylalanine of this open reading frame is consistent with what was reported for one of the ligandin subunits by Bhargava et al., (J. Biol. Chem. 253, 4116-4119, 1978). Among the 352 nucleotides covered by both pGTR112 and pGST94 described by Kalinyak and Taylor (J. Biol. Chem. 257, 523-530, 1982), there are only 9 nucleotide differences resulting in four changes of amino acid sequences.

Mercapturic acid pathway enzymes in bovine ocular lens, cornea, retina and retinal pigmented epithelium

Analogous to the liver, ocular tissues contain large concentrations of glutathione and are exposed to potentially damaging chemical compounds. Since glutathione has been shown to have a detoxification function, via mercapturic acid production in the liver, we investigated whether glutathione has a similar function in ocular tissues. We have demonstrated the presence of all of the enzymes involved in the mercapturic acid pathway i.e. glutathione S-transferase, gamma-glutamyl transpeptidase, cysteinylglycinase, and N-acetyl transferase, in the ocular tissues of bovine lens, cornea, retina, and retinal pigmented epithelium. Therefore glutathione may have another function in ocular tissues, that of the detoxification of xenobiotics.

Glutathione S-transferase (transferase pi) from human placenta is identical or closely related to glutathione S-transferase (transferase rho) from erythrocytes

Glutathione S-transferase (RX: glutathione R-transferase, EC 2.5.1.18) from human placenta has been purified to homogeneity. This enzyme, transferase pi, is an acidic protein (isoelectric point at pH 4.8) composed of two subunits. The molecular weights for the dimer and monomer were determined by independent methods as 47,000 and 23,400, respectively. These properties are not significantly different from those of glutathione S-transferase rho from human erythrocytes. Antibodies to transferase pi reacted with the enzyme from erythrocytes but not with the basic transferases alpha - epsilon and the neutral transferase mu isolated from human liver. Antibodies to the latter enzymes did not react with the transferase from placenta. Further similarities between transferases pi and rho appear in amino acid compositions, kinetic constants and substrate specificities. Both the placental and the erythrocyte enzyme have considerably higher activity with ethacrynic acid than any other of the human glutathione S-transferases. The glutathione S-transferase could be distinguished from two additional acidic glutathione-dependent enzymes, glyoxalase I and selenium-dependent glutathione peroxidase. It is concluded that transferase pi from placenta is identical with or very closely related to transferase rho from erythrocytes.

Affinity chromatography of hepatic glutathione S-transferases on omega-aminoalkyl sepharose derivatives of glutathione

Rat liver glutathione S-transferases (RX: glutathione R-transferase, EC 2.5.1.18) were found to adsorb S-carbamidomethyl glutathione linked to Sepharose CL-4B via lysyl or aliphatic diamine spacers of various carbon chain lengths (-NH-(CH2)n-NH-, n = 2, 4, 5, 6, 8 and 10). Proteins were eluted specifically by reduced glutathione. The affinity of the enzymes for the adsorbent increased with increase in the carbon chain length of aliphatic diamine spacers used. Adsorbent having a free carboxyl group within the spacer moiety had high capacity and was specific for glutathione S-transferases. The transferases were specifically eluted from the column in high yield by low concentrations of glutathione. Enzymes purified by the lysyl spacer adsorbent were homogeneous in sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis and contained most of the hepatic glutathione S-transferase isozymes in isoelectric focusing. Oxidized glutathione and S-methyl glutathione were equally effective as reduced glutathione in eluting glutathione S-transferases from the adsorbent, but gamma-glutamylcysteinylglycineamide or gamma-glutamylcysteinylglycine-1-methyl ester were not effective. These data suggested that the free carboxyl group of glycyl moiety of glutathione might also be important for the specific binding of the transferases to this adsorbent.

Induction and development of mouse liver glutathione S-transferase activity

Mouse liver glutathione S-transferase activity at birth was 1/10 that of adults, and increased steadily with each successive week of age until adult values were reached at 8 weeks. Activity was inducible with phenobarbital; however, the percentage increase in activity was dependent upon substrate. 2 distinct peaks of transferase activity were obtained on CM-cellulose chromatography. The ratios of transferase activity observed for each peak demonstrated that glutathione S-transferase activity in mouse liver is associated with at least 2 distinct proteins with differing substrate specificities.

Interrelationship between anionic and cationic forms of glutathione S-transferases of human liver

Human liver glutathione S-transferases (GSH S-transferases) were fractionated into cationic and anionic proteins. During fractionation with (NH4)2SO4 the anionic GSH S-transferases are concentrated in the 65%-saturated-(NH4)2SO4 fraction, whereas the cationic GSH S-transferases separate in the 80%-saturated-(NH4)2SO4 fraction. From the 65%-saturated-(NH4)2SO4 fraction two new anionic GSH S-transferases, omega and psi, were purified to homogeneity by using ion-exchange chromatography on DEAE-cellulose, Sephadex G-200 gel filtration, affinity chromatography on GSH bound to epoxy-activated Sepharose and isoelectric focusing. By a similar procedure, cationic GSH S-transferases were purified from the 80%-saturated-(NH4)2SO4 fraction. Isoelectric points of GSH S-transferases omega and psi are 4.6 and 5.4 respectively. GSH S-transferase omega is the major anionic GSH S-transferase of human liver, whereas GSH S-transferase psi is present only in traces. The subunit mol.wt. of GSH S-transferase omega is about 22500, whereas that of cationic GSH S-transferases is about 24500. Kinetic and structural properties as well as the amino acid composition of GSH S-transferase omega are described. The antibodies raised against cationic GSH S-transferases cross-react with GSH S-transferase omega. There are significant differences between the catalytic properties of GSH S-transferase omega and the cationic GSH S-transferases. GSH peroxidase II activity is displayed by all five cationic GSH S-transferases, whereas both anionic GSH S-transferases do not display this activity.

Characterization of rat-liver microsomal glutathione S-transferase activity

Rat liver microsomes were shown to catalyze the conjugation of 1-chloro-2,4-dinitrobenzene with glutathione and this activity has been characterized. It cannot be removed from the microsomes by washing or other procedures which release loosely bound material from membranes. The microsomal glutathione S-transferase can be activated up to eight fold by treatment with N-ethylmaleimide. This activation also affects the apparent Km of the enzyme(s) for both glutathione and 1-chloro-2,4-dinitrobenzene. Upon subcellular fractionation of the liver the N-ethylmaleimide-activateable glutathione S-transferase distributes in the same manner as a marker for the endoplasmic reticulum and unlike markers for the other organelles and for the cytoplasm. Treatment of microsomes with proteases revealed that the enzyme is at least partially exposed on the cytoplasmic surface of the endoplasmic reticulum. Finally, three inducers of drug-metabolizing systems-i.e. phenobarbital, methylcholanthrene, and trans-stilbene oxide-all increase the activity of the cytoplasmic glutathione S-transferases, but they do not affect the microsomal activity. These and other considerations indicate that the microsomal glutathione S-transferase(s) is distinct from the cytoplasmic enzymes catalyzing similar reactions. The microsomal enzyme is likely to be involved in drug metabolism and the possibility of activating it through attack on a sulfhydryl group may represent an important physiological response to certain xenobiotics.

Glutathione S-transferases in earthworms (Lumbricidae)

Glutathione S-transferase activity (EC 2.5.1.18) was demonstrated in six species of earthworms of the family Lumbricidae: Eisenia foetida, Lumbricus terrestris, Lumbricus rebellus, Allolobophora longa, Allolobophora caliginosa and Allolobophora chlorotica. Considerable activity was obtained with 1-chlorl-2,4-dinitrobenzene and low activity with 3,4-dichloro-1-nitrobenzene, but no enzymic reaction was detectable with sulphobromophthalein 1,2-epoxy-3-(p-nitrophenoxy)propane of trans-4-phenylbut-3-en-2-one as substrates. Enzyme prepartations from L. rubellus and A. longa were the most active, whereas A. chlorotica gave the lowest activity. The ratio of the activities obtained with 1-chloro-2,4-dinitrobenzene and 3,4-cichloro-1-nitrobenzene was very different in the various species, but no phylogenetic pattern was evident. Isoelectric focusing gave rise to various activity peaks as measured with 1-chloro-2,4-dinitrobenzene as a substrate, and the activity profiles of the species examined appeared to follow a taxonomic pattern. The activity of Allolobophora had the highest peak in the alkaline region, whereas that of Lumbricus had the highest peak in the acid region. Eisenia showed a very complex activity profile, with the highest peak ne pH 7. As determined by an enzymic assay, all the species contained glutathione, on an average about 0.5 mumol/g wet wt. Conjugation with glutathione catalysed by glutathione S-transferases may consequently be an important detoxification mechanism in earthworms.

The association of bacterial mutagenicity of hydrocarbon-derived 'bay-region' dihydrodiols with the Iball indices for carcinogenicity and with the extents of DNA-binding on mouse skin of the parent hydrocarbons

The mutagenic activities of benz[alpha]anthracene, 7-methylbenz[alpha]anthracene, 7,12-dimethylbenz[alpha]anthracene, 3-methylcholanthrene and benzo[alpha]pyrene, together with those of the trans-dihydrodiols derived from these hydrocarbons that would be expected to yield 'bay-region' vicinal diolepoxides on further metabolism have been examined in assays with S. typhimurium TA100 using post-mitochondrial supernatant fractions prepared from the livers of 3-methylcholanthrene-treated rats. Mutagenic activities obtained have been compared with: (a) the extents of reaction with DNA that occur in mouse skin following treatment with these hydrocarbons; (b) the carcinogenicities of the hydrocarbons expressed as Iball indices; (c) their activities as tumour-initiating agents on mouse skin. Close positive associations were found between the microsome-mediated mutagenicities of the dihydrodiols that could yield "bay-region" diol-epoxides and: (a) the extents of reaction with DNA in hydrocarbon-treated mouse skin; (b) the carcinogenic potencies of the parent hydrocarbons; although these correlations are not perfect, the mutagenic activities of the hydrocarbons themselves in microsome-mediated assays with S. typhimurium show no correlation with their extents of DNA binding on mouse skin and a poor correlation with their activities as initiating agents. These comparisons also indicated a statistically-significant positive correlation between carcinogenicity and the in vivo DNA binding on mouse skin treated with the hydrocarbons. Differences in the metabolic pathways by which polycyclic hydrocarbons are activated in vivo and in vitro are discussed in relation to the improved correlations found with the dihydrodiols.

Epoxide hydrase and glutathione S-transferase activities with selected alkene and adrene oxides in several marine species

Epoxide hydrase and glutathione (GSH) S-transferase activities were measured in subcellular fractions prepared from liver or hepatopancreas and some extrahepatic organs of a number of marine species common to Maine or Florida. These activities were easily detected in the species studied. In fish, hepatic GSH S-transferase activities were normally higher than hepatic epoxide hydrase activities for the alkene oxide (styrene oxide and octene oxide) and arene oxide (benzo[a]pyrene 4,5-oxide) substrates studied, whereas in crustacea, hepatopancreas epoxide hydrase activities were higher than hepatopancreas GSH S-transferase activities with the same substrates. Extrahepatic organs from fish and crustacea usually had higher GSH S-transferase activities than epoxide hydrase activities with the alkene and arene oxide substrates. GSH S-transferase activity was also found in liver or hepatopancreas of every aquatic species studied and in a number of extrahepatic organs, when 1,2-dichloro-4-nitrobenzene or 1-chloro-2,4-dinitrobenzene served as substrate.

Mechanism of formation of mercapturic acids from (1-bromoethyl)benzene and (2-bromoethyl)benzene in the rat

1. Three hypotheses have been proposed for the mechanism of metabolism of alkylhalides to hydroxy-alkylmercapturic acids, two of which involve the intermediate step of dehydrohalogenation and formation of an epoxide. 2. After injection of (1-bromoethyl)benzene in rat, the only mercapturic acid appearing in the urine was N-acetyl-S-1-phenylethylcysteine. After injecting (2-bromoethyl)benzene in the rat only N-acetyl-S-2-phenylethylcysteine and N-acetyl-S-(2-phenyl-2-hydroxyethyl)cysteine were found in the urine. 3. Since the principal mercapturic acid formed from both styrene and styrene oxide could not be detected in the urine of rats receiving either 1- or 2-bromoethyl benzene, the intermediate formation of styrene or styrene oxide from the arylalkylhalides does not occur.

Comparative studies on the molecular weight of glutathione S-transferases from mammalian livers and an insect

1. A comparative study was conducted on the molecular weights of glutathione S-transferases in the housefly and liver of the mouse and rat using Sephadex G-100 gel chromatography. 2. The values varied depending upon the buffers used in gel filtration. Molecular weights of 44,600, 53,600 and 43,000 daltons respectively were obtained with 0.01 M potassium phosphate buffer, pH 6.7; 0.05 M Tris-HCl buffer, pH 8.0; and 0.05 M Tris-HCl buffer containing 0.1 M KCl, pH 8.0, respectively. 3. There was no difference in the molecular weights of the enzymes obtained from the insect and from the mammalian livers. Purified enzymes eluted in the same fractions as those from the crude extracts, suggesting little modification in the molecular size of the enzymes during purification. 4. The presence of a large volume of stabilizer(s) in the enzyme solutions applied to the column delayed the elution of the activity peaks and resulted in erroneous values. Therefore, different literature values of molecular weights for glutathione S-transferases may be the result of different buffers and stabilizers used in gel filtration and probably do not represent a real difference in molecular size.

Glutathione and mercapturic acid conjugations in the metabolism of naphthalene and 1-naphthyl N-methylcarbamate (carbaryl)

The formation of glutathione (GSH) conjugate in the detoxification of [1-14C]-naphthalene and [naphthyl-14C]-carbaryl was investigated using rat liver homogenate. The mercapturic acid conjugate in rats was also investigated by collection of urine after intraperitoneal injection of 14C substrates. The formation of water-soluble metabolites in vitro from naphthalene was dependent on the amount of glutathione added, but this was not seen in carbaryl metabolism. In vitro, the metabolism of [1-14C]-naphthalene produced 50% GSH conjugates in the incubation mixture, whereas in vivo the metabolism of this compound produced 65% mercapturic acid conjugate in the urine. There was no evidence of GSH or mercapturic acid conjugate in the metabolism of [naphthyl-14C]-carbaryl in vitro and in vivo. This conclusion was made by comparing the nature and chemical characteristics of GSH and mercapturic acid conjugates formed in [1-14C]-naphthalene metabolism. With the aid of the specific enzyme (e.g. beta-glucuronidase and sulfatase) and acid hydrolysis, the water-soluble metabolites of [naphthyl-14C]-carbaryl were tentatively recognized as glucuronide or sulfate conjugated mainly with 5,6-dihydro-5,6-dihydroxycarbaryl or N-hydroxy-methyl carbaryl and their hydrolytic products. This data demonstrated that the substituent group on the naphthalene molecule may affect the significance of GSH conjugation.

The glutathione-linked metabolism of 2-allyl-2-isopropy-lacetamide in rats. Further evidence for the formation of a reactive metabolite

2-Allyl-2-isopropylacetamide (AIA) causes a depletion of liver glutathione in rats only if the animals have been pretreated with phenobarbitone. Phenobarbitone stimulates the excretion in bile of a component derived from AIA and glutathione which is apparently not the same as the conjugate formed by reaction of the two components in simple solutions. The significance of these findings are considered in relation to the suggestion that AIA is metabolised to an epoxide by the microsomal enzyme system; in addition several differences between AIA and the non-porphyrogenic compound, acrylamide, are discussed.