Metabolic inactivation of five glycidyl ethers in lung and liver of humans,rats and mice in vitro

1. Some glycidyl ethers (GE) have been shown to be direct mutagens in short-term in vitro tests and consequently GE are considered to be potentially mutagenic in vivo. However, GE may be metabolically inactivated in the body by two different enzymatic routes: conjugation of the epoxide moiety with the endogenous tripeptide glutathione (GSH) catalysed by glutathione S-transferase (GST) or hydrolysis of the epoxide moiety catalysed by epoxide hydrolase (EH). 2. The metabolic inactivation of five different GE, the diglycidyl ethers of bis phenol A (BADGE), 4,4'-dihydroxy-3,3',5,5'-tetramethylbiphenyl (Epikote YX4000) and 1,6- hexanediol (HDDGE)and the GE of 1-dodecanol (C₁₂GE)and o-cresol (o-CGE), has been studied in subcellular fractions of human, C3H mouse and F344 rat liver and lung. 3. All GE were chemically very stable and resistant to aqueous hydrolysis, but were rapidly hydrolysed by EH in cytosolic and microsomal fractions of liver and lung. The aromatic GE were very good substrates for EH. In general, microsomal EH is more efficient than cytosolic EH in hydrolysis of GE, and human microsomes are more efficient than rodent microsomes. 4. The more water-soluble GE, o-CGE and HDDGE, were good substrates for GST whereas the more lipophilic GE, YX4000 and C₁₂GE, were poor substrates for GST. In general, rodents are more efficient in GSH conjugation of GE than humans. 5. In general, the epoxide groups of YX4000 are the most and those of HDDGE the least efficiently inactivated of the five GE under study. For the other three GE no general trend was observed: the relative efficiency of inactivation varied with organ and species. 6. The large variation in metabolism observed with five representative GE indicate that GE have variable individual properties and should not be considered as a single, homogenous class of compounds.     

Dermal penetration and metabolism of five glycidyl ethers in human, rat and mouse skin

1. Glycidyl ethers (GE), an important class of industrial chemicals, are considered to be potentially mutagenic in vivo because some GE have been shown to be direct mutagens in short-term in vitro tests. 2. The percutaneous penetration and metabolism of representatives of different classes of GE was studied in the fresh, full-thickness C3H mouse, and dermatomed human and Fisher 344 rat skin to determine the apparent permeability constants, lag times and metabolic profiles. 3. Five different GE, the diglycidyl ethers of bisphenol A (BADGE), 4,4'-dihydroxy-3,3',5,5'-tetramethylbiphenyl (Epikote YX4000) and 1,6-hexanediol (HDDGE) and the GE of 1-dodecanol (C12GE) and o-cresol (o-CGE), were synthesized by reaction of their alcohols with epichlorohydrin. Their radiolabelled analogues were synthesized with a 14C-label using [U-14C]-epichlorohydrin. 4. There was a large variation (four orders of magnitude) in percutaneous penetration between the five GE. In general, penetration through full-thickness mouse skin was higher than through dermatomed rat skin, whereas dermatomed human skin was the least permeable. The permeability increased in the order YX4000 < BADGE < C12GE < o-CGE < HDDGE. 5. The relative skin permeability of the five GE could be explained for a significant part by the lipophilicity, expressed as log P(o/w), in combination with the molecular weight of the compounds. 6. During skin penetration, all GE were extensively metabolized to their corresponding (bis-)diols. Virtually no YX4000, and only very small amounts of C12GE and BADGE, penetrated the skin unchanged, but significant amounts of HDDGE and o-CGE penetrated the skin unchanged. For o-CGE, but none of the other GE, the percentage of the applied dose that penetrated the skin unchanged increased over time. 7. The large variation in response observed with the five selected GE indicates that GE should not be considered as a single class of compounds but rather on the basis of their individual properties.     

Dermal penetration and metabolism of five glycidyl ethers in human,rat and mouse skin

1. Glycidyl ethers (GE), an important class of industrial chemicals, are considered to be potentially mutagenic in vivo because some GE have been shown to be direct mutagens in short-term in vitro tests. 2. The percutaneous penetration and metabolism of representatives of different classes of GE was studied in the fresh, full-thickness C3H mouse, and dermatomed human and Fisher 344 rat skin to determine the apparent permeability constants, lag times and metabolic profiles. 3. Five different GE, the diglycidyl ethers of bisphenol A (BADGE), 4,4'-dihydroxy3,3',5,5'-tetramethylbiphenyl (Epikote YX4000) and 1,6-hexanediol (HDDGE) and the GE of 1-dodecanol (C₁₂GE) and o-cresol (o-CGE), were synthesized by reaction of their alcohols with epichlorohydrin. Their radiolabelled analogues were synthesized with a ¹⁴Clabel using [U-¹⁴C]-epichlorohydrin. 4. There was a large variation (four orders of magnitude) in percutaneous penetration between the five GE. In general, penetration through full-thickness mouse skin was higher than through dermatomed rat skin, whereas dermatomed human skin was the least permeable. The permeability increased in the order YX4000<BADGE<C₁₂GE<o CGE<HDDGE. 5. The relative skin permeability of the five GE could be explained for a significant part by the lipophilicity, expressed as log Po/w, in combination with the molecular weight of the compounds. 6. During skin penetration, all GE were extensively metabolized to their corresponding (bis-)diols. Virtually no YX4000, and only very small amounts of C₁₂GE and BADGE, penetrated the skin unchanged, but significant amounts of HDDGE and o-CGE penetrated the skin unchanged. For o-CGE, but none of the other GE, the percentage of the applied dose that penetrated the skin unchanged increased over time. 7. The large variation in response observed with the five selected GE indicates that GE should not be considered as a single class of compounds but rather on the basis of their individual properties.     

Metabolic inactivation of 2-oxiranylmethyl 2-ethyl-2,5-dimethylhexanoate (C10GE) in skin, lung and liver of human, rat and mouse

The inactivation of 2-oxiranylmethyl 2-ethyl-2,5-dimethylhexanoate (C10GE), one of the most abundant isomers of the epoxy-resin Carduras E-10 glycidyl ester, was studied in subcellular fractions of human, C3H mouse and F344 rat liver, lung and skin. C10GE is chemically very stable and resistant to aqueous hydrolysis, but it was rapidly metabolized in both cytosolic and microsomal fractions of all organs by epoxide hydrolase (EH)-catalysed hydrolysis of the epoxide moiety as well as carboxylesterase (CE)-catalysed hydrolysis of the ester bond. In cytosol the epoxide group was also efficiently conjugated with glutathione, catalysed by glutathione S-transferase (GST), but this conjugation was much less important than hydrolysis in human as well as rodent samples. Although CE-catalysed hydrolysis of C10GE would theoretically give rise to the formation of glycidol, a directly acting mutagen, it is highly unlikely that any significant level of glycidol would occur in vivo since reported rates of inactivation of glycidol exceed the total rate of hydrolysis of C10GE. The overall rates of inactivation in vitro decreased in the following order: mouse > rat > human. Scaling of the data in vitro to clearances in vivo suggests that the detoxifying capacity in the rodents is similar and about an order of magnitude greater than in human. Nevertheless, the rate of inactivation is 2-3 orders of magnitude greater than for simple epoxides such as butadiene monoxide and about one order of magnitude higher than for the diglycidyl ether of bisphenol A (BADGE). The transdermal penetration and metabolism of [14C]-C10GE was studied in fresh full-thickness mouse, and dermatomized human and rat skin. Of the total radioactivity applied on the skin, only 0.24+/-0.06 (SD), 1.8+/-0.2 and 6.8+/-0.6% penetrated through human, mouse and rat skin respectively. The corresponding apparent skin permeability constants were 0.81, 6.42 and 26.4 x 10(-6) cm/h. During transdermal penetration, [14C]-C10GE was extensively hydrolysed to the corresponding diol and the free acid. Only 0.01, 0.11 and 0.21]% of the applied dose was absorbed unchanged through the human, mouse and rat skin respectively.     

Kinetics of propylene oxide metabolism in microsomes and cytosol of different organs from mouse, rat, and humans

Kinetics of the metabolic inactivation of 1,2-epoxypropane (propylene oxide; PO) catalyzed by glutathione S-transferase (GST) and by epoxide hydrolase (EH) were investigated at 37 degrees C in cytosol and microsomes of liver and lung of B6C3F1 mice, F344 rats, and humans and of respiratory and olfactory nasal mucosa of F344 rats. In all of these tissues, GST and EH activities were detected. GST activity for PO was found in cytosolic fractions exclusively. EH activity for PO could be determined only in microsomes, with the exception of human livers where some cytosolic activity also occurred, representing 1-3% of the corresponding GST activity. For GST, the ratio of the maximum metabolic rate (V(max)) to the apparent Michaelis constant (K(m)) could be quantified for all tissues. In liver and lung, these ratios ranged from 12 (human liver) to 106 microl/min/mg protein (mouse lung). Corresponding values for EH ranged from 4.4 (mouse liver) to 46 (human lung). The lowest V(max) value for EH was found in mouse lung (7.1 nmol/min/mg protein); the highest was found in human liver (80 nmol/min/mg protein). K(m) values for EH-mediated PO hydrolysis in liver and lung ranged from 0.83 (human lung) to 3.7 mmol/L (mouse liver). With respect to liver and lung, the highest V(max)/K(m) ratios were obtained for GST in mouse and for EH in human tissues. GST activities were higher in lung than in liver of mouse and human and were alike in both rat tissues. Species-specific EH activities in lung were similar to those in liver. In rat nasal mucosa, GST and EH activities were much higher than in rat liver.     

Metabolic inactivation of 2-oxiranylmethyl 2-ethyl2,5-dimethylhexanoate (C10GE) in skin,lung and liver of human,rat and mouse

1. The inactivation of 2-oxiranylmethyl 2-ethyl-2,5-dimethylhexanoate (C₁₀GE), one of the most abundant isomers of the epoxy-resin Cardura®E-10 glycidyl ester, was studied in subcellular fractions of human, C3H mouse and F344 rat liver, lung and skin. 2. C₁₀GE is chemically very stable and resistant to aqueous hydrolysis, but it was rapidly metabolized in both cytosolic and microsomal fractions of all organs by epoxide hydrolase (EH)-catalysed hydrolysis of the epoxide moiety as well as carboxylesterase (CE)-catalysed hydrolysis of the ester bond. In cytosol the epoxide group was also efficiently conjugated with glutathione, catalysed by glutathione S-transferase (GST), but this conjugation was much less important than hydrolysis in human as well as rodent samples. Although CE-catalysed hydrolysis of C₁₀GE would theoretically give rise to the formation of glycidol, a directly acting mutagen, it is highly unlikely that any significant level of glycidol would occur in vivo since reported rates of inactivation of glycidol exceed the total rate of hydrolysis of C₁₀GE. 3. The overall rates of inactivation in vitro decreased in the following order: mouse &;gt; rat &;gt; human. Scaling of the data in vitro to clearances in vivo suggests that the detoxifying capacity in the rodents is similar and about an order of magnitude greater than in human. Nevertheless, the rate of inactivation is 2-3 orders of magnitude greater than for simple epoxides such as butadiene monoxide and about one order of magnitude higher than for the diglycidyl ether of bisphenol A (BADGE). 4. The transdermal penetration and metabolism of [¹⁴C]-C₁₀GE was studied in fresh full-thickness mouse, and dermatomized human and rat skin. Of the total radioactivity applied on the skin, only 0.24±0.06 (SD), 1.8±0.2 and 6.8±0.6% penetrated through human, mouse and rat skin respectively. The corresponding apparent skin permeability constants were 0.81, 6.42 and 26.4X 10^?6 cm/h. 5. During transdermal penetration, [¹⁴C]-C₁₀GE was extensively hydrolysed to the corresponding diol and the free acid. Only 0.01, 0.11 and 0.21% of the applied dose was absorbed unchanged through the human, mouse and rat skin respectively.     

Glutathione conjugation of the fluorophotometric epoxide substrate, 7-glycidoxycoumarin (GOC), by rat liver glutathione transferase isoenzymes

The fluorophotometric substrate, 7-glycidoxycoumarin (GOC), was examined for the assay of epoxide-glutathione (GSH)-conjugating activities of seven major GSH transferases (GSTs) isolated from rat liver cytosols. GST 7-7 (GST-P), isolated from the liver cytosol of rats bearing hepatic hyperplastic nodules, catalysed the GSH conjugation of GOC at a higher rate than any other examined GST isolated from the normal rat liver cytosol. GSTs 3-3, 3-4 and 4-4 (group 3-4 enzymes) had specific activities towards GOC by one fifth to one third of that of GST 7-7. GSTs 1-1, 1-2 and 2-2 (group 1-2 enzymes) had very low activities towards this epoxide. A kinetic study indicated that GST 7-7 showed the largest kappa cat/Km value for the catalytic reaction of GOC-GSH conjugation among the GSTs. In spite of their much smaller kappa cat values, group 3-4 enzymes showed much larger kappa cat/Km values for GOC than the group 1-2 enzymes, because GOC had a much higher affinity for group 3-4 enzymes than for group 1-2 enzymes. A comparative study was also done with GSH conjugations of styrene 7,8-oxide (STO) and 1-chloro-2,4-dinitrobenzene by the GSTs. Unlike GOC, the conjugation of STO was mediated at rates about twice as high by group 3-4 enzymes than by GST 7-7. STO was also a very poor substrate for group 1-2 enzymes.     

Mutation spectra of S-(2-hydroxy-3,4-epoxybutyl)glutathione: comparison with 1,3-butadiene and its metabolites in the Escherichia coli rpoB gene

S-(2-Hydroxy-3,4-epoxybutyl)glutathione (DEB-GSH conjugate) is formed from the reaction of 1,2:3,4-diepoxybutane (DEB) with glutathione (GSH), and the conjugate is considerably more mutagenic than several other butadiene-derived epoxides-including DEB-in Salmonella typhimurium TA1535 [Cho, S.-H., (2010) Chem. Res. Toxicol. 23, 1544-1546]. We previously identified six DNA adducts in the reaction of the DEB-GSH conjugate with nucleosides and calf thymus DNA and two DNA adducts in livers of mice and rats treated with DEB [Cho, S.-H. and Guengerich, F. P. (2012) Chem. Res. Toxicol. 25, 706-712]. To define the role of GSH conjugation in 1,3-butadiene (BD) metabolism and characterize the mechanism of GSH transferase (GST)-enhanced mutagenicity of DEB, mutation spectra of BD and its metabolites in the absence and presence of GST/GSH and mouse liver microsomes were compared in the rpoB gene of Escherichia coli TRG8. The presence of GST considerably enhanced mutations. The mutation spectra derived from the DEB-GSH conjugate, the DEB/GST/GSH system, and the BD/mouse liver microsomes/GST/GSH system matched each other and were different from those derived from the other systems devoid of GSH. The major adducts in E. coli TRG8 cells treated with the DEB/GST/GSH system, the BD/mouse liver microsomes/GST/GSH system, or the DEB-GSH conjugate were S-[4-(N(7)-guanyl)-2,3-dihydroxybutyl]GSH, S-[4-(N(3)-adenyl)-2,3-dihydroxybutyl]GSH, and S-[4-(N(6)-deoxyadenosinyl)-2,3-dihydroxybutyl]GSH, indicating the presence of the GSH-containing DNA adducts in the systems. These results, along with the strong enhancement of mutagenicity by GST in this system, indicate the relevance of these GSH-containing DNA adducts.     

Involvement of different human glutathione transferase isoforms in the glutathione conjugation of reactive metabolites of troglitazone

Null mutation of glutathione transferase (GST) M1 and GSTT1 was reported to correlate statistically with an abnormal increase in the plasma levels of alanine aminotransferase or aspartate aminotransferase caused by troglitazone in diabetic patients (Clin Pharmacol Ther, 73:435-455, 2003). This clinical evidence leads to the hypothesis that GSH conjugation catalyzed by GSTT1 and GSTM1 has a role in the elimination of reactive metabolites of troglitazone. However, the contribution of GST isoforms expressed in human liver to the detoxification of reactive metabolites of troglitazone has not yet been clarified. We investigated the involvement of human GST isoforms in the GSH conjugation of reactive metabolites of troglitazone using recombinant GST enzymes. Five reported GSH conjugates of reactive metabolites were produced from troglitazone after incubation with liver microsomes, NADPH, and GSH in a GSH concentration-dependent manner. Addition of human recombinant GSTA1, GSTA2, GSTM1, or GSTP1 protein to the incubation mixture further increased the GSH conjugates. However, the addition of GSTT1 did not show any catalytic effect. It is of interest that one of the reactive metabolites with a quinone structure was predominantly conjugated with GSH by GSTM1. Thus, we demonstrated that the GST isoforms contributed differently to the GSH conjugation of individual reactive metabolites of troglitazone, and GSTM1 is the most important GST isoform in the GSH conjugation of a specific reactive metabolite produced from the cytotoxic, quinone-form metabolite of troglitazone.     

The effect of tridiphane (2-(3,5-dichlorophenyl)-2-(2,2,2-trichloroethyl)oxirane) on hepatic epoxide-metabolizing enzymes: indications of peroxisome proliferation

Administration of tridiphane (Tandem, DOWCO 356, 2-(3,5-dichlorophenyl)-2-(2,2,2-trichloroethyl)oxirane) to male Swiss-Webster mice for 3 days at 100, 250, and 500 mg/kg (ip) resulted in increases in liver weight accompanied by an increase in mitotic index and increases in large particle and microsomal protein. Epoxide hydrolase (EH) activity towards cis-stilbene oxide (CSO, microsomal EH) was elevated in microsomes and cytosol, a decrease in microsomal cholesterol EH was found, and hydrolysis of trans-stilbene oxide (TSO, cytosolic EH) was elevated in the cytosol but not in the microsomes. Glutathione S-transferase (GST) activity was elevated in cytosol for CSO, TSO, and 1,2-dichloro-4-nitrobenzene (DCNB), with inconsistent responses found with 1-chloro-2,4-dinitrobenzene (CDNB) and 1,2-epoxy-3-(p-nitrophenoxy)propane (ENPP). Microsomal GST was not consistently effected by tridiphane. Clofibrate (500 mg/kg, 3 daily ip injections) treatment resulted in similar responses in liver size, microsomal protein, and the EHs. The increase in cytosolic EH activity previously has been noted only in animals treated with peroxisome proliferators. Examination of livers from mice treated with 250 mg/kg tridiphane revealed that an increase in hepatic peroxisomes was apparent after 3 days of treatment. This was accompanied by decreases in serum cholesterol and triglyceride levels and increases in liver carnitine acetyl transferase and cyanide-insensitive oxidation of palmitoyl-CoA. This study demonstrates that tridiphane does have in vivo effects on mammalian epoxide-metabolizing enzymes and extends the association of increased cytosolic epoxide hydrolase activity with peroxisome proliferation.     

Metabolism of tridiphane (2-(3,5-dichlorophenyl)-2(2,2,2-trichloroethyl)oxirane) by hepatic epoxide hydrolases and glutathione S-transferases in mouse

The transformation of the herbicide tridiphane (Tandem, Dowco 356, 2-(3,5-dichlorophenyl)-2(2,2,2-trichloroethyl)oxirane by the epoxide-metabolizing enzymes, epoxide hydrolases (EH) and glutathione S-transferases (GST), was investigated in mouse liver microsomes and cytosol. The microsomal EH catalyzed the formation of tridiphane diol. The production of this metabolite was prevented by cyclohexene oxide at 1 mM, a known inhibitor of microsomal EH. The structure of the diol was verified by comparison of retention time or Rf of the compound with those of an authentic standard using gas-liquid chromatography or thin-layer chromatography techniques. The diol formed a diester with 1-butane boronic acid or an aldehyde with lead tetraacetate. Mass spectral analysis supported the structural assignment. After optimization of the assay conditions, kinetic constants for the hydration of tridiphane by the microsomal EH were determined (Km = 65 microM and Vmax = 0.9 nmol/min/mg protein). Dietary exposure of mice to the hypolipidemic drug clofibrate at a dose of 0.5% (w/w) for 2 weeks increased by 173% the metabolism of tridiphane to tridiphane diol by the microsomal fraction. No diol could be detected following incubation of tridiphane with the cytosolic EH, even after induction by clofibrate. Tridiphane was also a substrate for GST, but administration of clofibrate did not change the specific activity for the formation of the glutathione conjugate. The herbicide was a rather weak inhibitor of the microsomal EH and the cytosolic GST activities measured with cis-stilbene oxide and trans-stilbene oxide as substrates with I50's of 3.0 x 10(-5) and 1.8 x 10(-4)M, respectively. Tridiphane diol was a poor inhibitor of the enzymes studied, and the glutathione conjugate of tridiphane caused marked inhibition of only the GST activity (I50, 2.0 x 10(-5)M). By contrast the activity of cytosolic EH (trans-stilbene oxide) was relatively insensitive to the addition of tridiphane or of tridiphane metabolites.     

In vitro interaction of organic mercury compounds with soluble glutathione S-transferases from rat liver

The in vitro interaction of organic mercury compounds with rat liver glutathione S-transferases (GST) was studied, using reduced glutathione (GSH) and 1-chloro-2,4-dinitrobenzene (CDNB) as substrates. The inhibition of the GST activity was dose dependent, but not linear. The different GST isoenzymes were inhibited to different degrees. Kinetic studies never revealed competitive inhibition, with CDNB or with GSH as the variable substrate. Titration of remaining GSH in appropriate incubation mixtures with organomercurials revealed no GST catalyzed conjugation of these compounds with GSH. These experiments showed a spontaneous conjugation of the mercury compounds with GSH, explaining the parabolic inhibition observed in the kinetic studies with GSH as the variable substrate. Both organic and inorganic mercury are spontaneously conjugated with GSH, but interact with GST by direct binding to these proteins. This binding could have a protective function against mercury. No qualitative differences between organic and inorganic mercury were detected.     

Activities of hepatic epoxide hydrolase and glutathione S-transferase in rats under the influence of tetramethyl thiuramdisulfide, tetramethyl thiurammonosulfide or dimethyl dithiocarbamate

The epoxide hydrolase (EH) activity in the liver of adult female Wistar rats significantly increased 18 h after the administration by gavage of tetramethyl thiuramdisulfide (TMTD, 1 mmol/kg) or tetramethyl thiurammonosulfide (TMTM, 2 mmol/kg). No increase was observed 5 h after administration of Na-dimethyl dithiocarbamate (Na-DMDTC, 4 mmol/kg). The glutathione S-transferase (GST) activity in the cytosol and microsomes of the liver was slightly enhanced after oral (gavage) administration of TMTD, TMTM or Na-DMDTC (doses up to 4 mmol/kg). In vitro, TMTD, TMTM, and Na-DMDTC significantly enhanced the hepatic activity of EH prepared from adult female Wistar rats. Cytosolic and microsomal GST activities from the liver were significantly raised in vitro by Na-DMDTC. The results have a bearing on the evaluation of the risk to health of these chemicals in the workplace.     

Effects of D-limonene on hepatic microsomal monooxygenase activity and paracetamol-induced glutathione depletion in mouse

1. d-Limonene, a monoterpenoid constituent of citrus fruit oil, blocks tumour induction by chemical carcinogens in laboratory animals, apparently by preventing bioactivation of procarcinogens and by enhancing conjugation of proximal carcinogenic metabolites.

2. Inhibitory effects of d-limonene were measured in vitro using cytochrome P450 isoform-specific substrates. d-Limonene inhibited p-nitrophenol hydroxylase (pNP) activity in vitro in liver microsomes from acetone-, phenobarbital (PB)- and β-naphthoflavone (BNF)-treated mouse, and 7-ethoxyresorufin O-deethylase (EROD) activity in microsomes from PB- and BNF-treated mouse. p-Nitrophenol and ethoxyresorufin are substrates for cytochromes P2E1 and P1A1, respectively. No inhibition of benzphetamine (BNZP) or aminopyrine (AP) demethylases by d-limonene was observed.

3. EROD, BNZP and AP activities in liver microsomes were increased 18 h after i.p. administration of d-limonene to acetone-induced mouse, while pNP activity was unchanged. The immunodetectable protein level of cytochrome P2B1 in non-acetone treated mouse was increased 18h after d-limonene, with no differences in P2E1 or P1A1.

4. Acute d-limonene did not protect against paracetamol (acetaminophen)-induced depletion of liver reduced glutathione (GSH). A prolonged paracetamol challenge (0–6% diet for 10 days) elevated liver cytosolic GSH-S-transferase activity (GST) two-fold and decreased liver GSH to 46% of control values. Dietary d-limonene (1–0% diet for 10 days) maintained liver GSH concentrations at 92% of control values in the paracetamol-challenged mouse without altering GST activity. d-Limonene also increased liver GSH concentration (23%) in mouse fed 1–0% d-limonene alone.     

Organ distribution and kinetics of Glutathione transferase from African river prawn, Macrobrachium vollenhovenii (Herklots)

The distribution of glutathione transferase (GST) in the major organs of African river prawn (Macrobrachium vollenhovenii) was studied. All the organs studied had GST activity. The specific activity of the extract from the hepatopancreas was highest while that from the muscle lowest. Purified GST from the hepatopancreas which could conjugate glutathione (GSH) with only 1-chloro-2,4-dinitrobenzene (CDNB) and 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole (NBDCl) among some electrophilic substrates tested, had a K(m)(NBDCl) of 2.2+/-0.12 mmol l(-1) while the K(m)CDNB was 2.03+/-0.29 mmol l(-1). Chloride ion, a product of the enzymatic reaction readily inhibited the conjugation of CDNB with GSH with an I50 of 0.12 mmol l(-1), whereas chloride ion up to 0.6 mol l(-1) had no inhibitory effect on the conjugation of GSH with NBDCl. However, nitrite inhibited the two reactions but the K(i) for the conjugation of NBDCl was lower than the K(i) for the conjugation of CDNB. The enzyme had an optimum temperature of 40 degrees C and an activation energy of 35.1 kJ/mol. The overall results show that M. vollenhovenii GST (mvGST) uses different mechanisms for different electrophilic substrates. The high K(m) of mvGST for the electrophilic substrates may be a special physiological adaptation for effective xenobiotic detoxication.     

Glutathione adducts of helenalin and 11 alpha,13-dihydrohelenalin acetate inhibit glutathione S-transferase from horse liver

The 2-mono- and 2,13-bis-glutathionyl adducts of helenalin and the 2-monoglutathionyl adduct of 11 alpha,13-dihydrohelenalin acetate were previously shown to be formed by spontaneous Michael addition at physiological pH. In living cells, glutathione (GSH) conjugation of many types of electrophilic agents is catalysed by a family of GSH S-transferase enzymes (GST). The capability of a glutathione S-transferase from horse liver to catalyze the reaction of helenalin and other helenanolides with GSH was investigated. The enzyme did not accelerate GSH conjugation of helenalin, 11 alpha,13-dihydrohelenalin, or 2-deacetyl-6-deoxychamissonolide. The GSH-adducts, formed by spontaneous reaction, were found to be inhibitors of this enzyme. Free helenalin, a potent inhibitor of many enzymes containing free sulfhydryl groups, did not show any inhibitory activity on GST. It was thus demonstrated that GSH-adducts of sesquiterpene lactones possess their own specific biological activity. Two further enzymes using GSH as substrate, glutathione reductase and glyoxalase I, were not influenced by free helenalin or its GSH-adducts.     

In vitro interaction of dithiocarb with rat liver glutathione S-transferases

The in vitro interaction of dithiocarb (DTC) with rat liver glutathione S-transferase was studied, using reduced glutathione (GSH) and 1-chloro-2,4-dinitrobenzene (CDNB) as substrates. The inhibition of the GST activity by DTC was dose dependent, but not linear. The different GST isoenzymes were inhibited to different degrees. Kinetic studies revealed uncompetitive inhibition towards GSH for GST AA, and an intermediate kinetic pattern between uncompetitive and noncompetitive inhibition for the other GST isoenzymes. With respect to CDNB, mixed type inhibition was found for most GST isoenzymes, and nearly uncompetitive inhibition for GST AA and M. Titration of remaining GSH in appropriate incubation mixtures with DTC revealed no GST catalyzed conjugation of DTC with GSH. It is concluded that DTC interact with GST by direct binding to these proteins. This binding could have a protective function against DTC.     

Acetaminophen-glutathione conjugate formation in a coupled cytochrome P-450-glutathione S-transferase assay system mediated by subcellular preparations from adult and weanling rat tissues.

Previous studies from this laboratory indicated that glutathione (GSH) conjugate formation with acetaminophen (APAP) is remarkably induced in liver of weanling rats in response to a single overdose of the drug administered intraperitoneally (ip). Increased APAP–GSH conjugation has been attributed to inducible glutathione S-transferases (GSTs) in dividing hepatocytes. In order to verify this finding, an in vitro reconstitution assay containing liver microsomes (source of cytochrome P-450) and cytosolic fractions (source of GST) from livers and kidneys of adult and weanling rats has been established. In vitro incubation of the reaction mixture was followed by solvent extraction, enzymatic digestion and HPLC analysis of the conjugate. Under controlled conditions, in vitro, the rate of APAP-GSH conjugation reflected the GST activity of cytosolic sample added to incubation system. The activity of cytosolic GST in catalyzing this reaction was measured using cytosols prepared from various tissue sources, particularly from animals pretreated with dietary butylated hydroxylanisole (BHA). The extent of APAP–GSH conjugate formation mediated by cytosols varied in this order: BHA-treated adult liver>BHA-treated weanling liver>control adult liver>control weanling liver>BHA-adult kidney>control adult kidney>BHA weanling kidney>control weanling kidney. In contrast to findings obtained from in vivo experiments, the rate of GST-dependent APAP conjugate formation with GSH in vitro is not induced in the presence of exogenous drug.     

Metabolism of benz(a)anthracene epoxides by rat-liver

Benz[a]anthracene is metabolized to 5,6-dihydro-5,6-dihydroxybenz[a]anthracene and 8,9-dihydro-8,9-dihydroxybenz[a]anthracene by the microsomal fraction of ratliver and NADPH and these metabolites are formed at similar rates. When the soluble liver fraction and GSH are also present, the rate of formation of the 8,9-dihydrodiol is not affected while that of the 5,6-isomer is considerably reduced. Since epoxides are the intermediates formed in the metabolism of aromatic hydrocarbons, the further metabolism of benz[a]anthracene 5,6- and 8,9-oxide into dihydrodiols and into GSH conjugates has been investigated. Each epoxide is converted into a dihydrodiol by microsomal “epoxide hydrase” at a similar rate, whereas conjugation with GSH. a reaction catalysed by “glutathione S-epoxide transferase” in the soluble liver fraction, proceeds considerably more rapidly with the 5,6- than with the 8,9-isomer. When a mixture of the two epoxides of benz[a]anthracene is incubated both with “epoxide hydrase” and with “GSH transferase”, the 5,6-isomer is converted largely into the GSH conjugate while the main route of metabolism of the 8,9-isomer is by hydration to the dihydrodiol.     

Subcellular distribution of glutathione S-transferase in Chinese fetal liver

Subcellular fractions were isolated from Chinese fetal liver at 4-8 months of age for the determination of glutathione S-transferase (GST). Using 1-chloro-2,4-dinitrobenzene (CDNB) as substrate, GST activity was found to be 66 +/- 34 nmol/(min.mg protein), mainly in the cytosol. The GST activities were detected principally in microsomes and their values were 66 +/- 31 and 144 +/- 83 nmol/(min.mg protein), respectively, when assayed with p-nitrobenzyl chloride (PNB) and ethacrynic acid (EA) as substrates. There were no age and sex-related differences in GST activities for any of the substrates studied during fetal development. The Km values of GST for CDNB, PNB and EA were 1112, 1039 and 205 mumol/L, respectively. The conjugation of GST may play an important role in fetal hepatic metabolism of toxic electrophiles.