Differential expression of microsomal epoxide hydrolase gene by azole heterocycles in rats

Expression of microsomal epoxide hydrolase is elevated in Alzheimer's hippocampus and induced by exogenous β-amyloid and trimethyl-tin

The brain is a potential target for drugs and environmental toxins. Microsomal epoxide hydrolase (mEH) is one of several critical biotransformation enzymes in xenobiotic metabolism and detoxification. In the present study, we report that the expression of mEH is significantly elevated in the hippocampus and associated cortex, but not in the cerebellum, in Alzheimer's disease (AD) patients. A large proportion of the mEH-positive cells are located around beta-amyloid plaques. The mEH-positive-staining cells are astrocytes and pyramidal neurons. Western blotting analysis confirmed increased expression of mEH in AD hippocampal tissues. In primary hippocampal glial culture, beta-amyloid aggregation stimulated mEH expression in the astrocytes, which displayed a patchy distribution. An environmental neurotoxic agent, trimethyl-tin, also activated mEH expression in rat hippocampus and entorhinal cortex. The present study demonstrates a significant increase in mEH expression in the AD hippocampus, a region showing abundant neuropathology in AD. The expression of mEH could also be elevated by exposure to exogenous beta-amyloid in vitro and environmental toxins in vivo. Our studies suggest that mEH may play a role in pathogenesis of neurodegeneration in response to environmental stress.

Effects of benzothiazole on the xenobiotic metabolizing enzymes and metabolism of acetaminophen

Benzothiazole (BT) is present in tobacco smoke and widely used for industrial and pharmaceutical purposes. In this study we have investigated the influence of BT on the activities of hepatic cytochrome P450 monooxygenases (P450s) and UDP-glucuronyltransferase (UDP-GT), sulphotransferase and glutathione-S-transferase (GST) in male Sprague-Dawley rats. We also examined if BT would change the metabolism and toxification of acetaminophen (AA) through modulation of metabolizing enzymes. Benzothiazole (1 mmol kg(-1), p.o., 5 days) markedly increased the enzyme activities of P4501A1, 1A2, 2B1, 3A4, 2E1, UDP-GT and GST in liver. Pretreatment with BT significantly decreased the amount of total AA recovered in bile to 68.5% of controls, mainly as a consequence of reduced AA-glucuronide conjugate (35.3% of controls), whereas the AA-glutathione conjugate (AA-GS) was augmented to 1.6-fold. After pretreatment with BT, potentiation of the hepatotoxicity by AA (400 mg kg(-1), i.p., 24 h) was observed by measuring serum alanine aminotransferase activities in ICR mice. These results indicate that: BT is a potent inducer of P450s and phase II metabolizing enzymes; and the increase of AA-GS conjugate and aggravation of AA hepatotoxicity by BT may be related to induction of P450s.

Induction of class alpha glutathione S-transferases by 4-methylthiazole in the rat liver: role of oxidative stress

The expression of glutathione S-transferase (GST) is a crucial factor in determining the sensitivity of cells and organs in response to a variety of toxicants. Expression of class alpha GST genes by methyl-substituted thiazoles was assessed in the rat liver. Northern blot analysis revealed that 4-methylthiazole (4-MT) elevated rGSTA2, A3, A5 and M1 mRNAs in the liver by 19-, 4-, 6- and 9-fold at 24 h after treatment, respectively, as compared to control. Consecutive 3-day treatment with 4-MT resulted in 4- to 7-fold increases in rGSTA and M1 mRNAs. Multiple treatments with 5-methylthiazole (5-MT) caused marginal increases in GST mRNAs in spite of the large increases in certain GST mRNAs at 24 h. Either 4, 5-dimethylthiazole (DT) or 2,4,5-trimethylthiazole (TT) minimally affected the rGSTA and rGSTM mRNA expression at 1-3 day(s). Western blot analysis showed that 4-MT induced rGSTA1/2, rGSTA3/5 and rGSTM1 proteins by 2.6-, 2.1- and 2.1-fold at 3 days, respectively, while other methylthiazoles failed to induce the GST subunits. Starving rats were treated with a lower dose of methylthiazoles to study the role of oxidative stress in the mRNA expression. The levels in rGSTA2/3/5 mRNAs were significantly enhanced by 4-MT in starving rats, whereas rGSTM1/2 mRNAs were not further increased. Other methylthiazoles were inactive in enhancing the mRNAs in starving animals. Pretreatment of starving rats with either cysteine or methionine completely prevented the increases in class alpha GST mRNAs by 4-MT. Data showed that 4-MT induces class alpha GSTs with the increases in the mRNAs, whereas 5-methyl-, dimethyl- and trimethyl-substituted thiazoles were minimally active. Increases in the class alpha GST mRNAs by 4-MT may be associated with the oxidative stress in hepatocytes, as supported by starvation and sulfur amino acid experiments.

Enhanced expression of rat hepatic microsomal epoxide hydrolase by methylthiazole in conjunction with liver injury

Microsomal epoxide hydrolase (mEH) is inducible by a number of xenobiotics. Induction of mEH by certain chemopreventive agents may implicate the protective effect. In contrast, many of carcinogenic agents also induce the enzyme. The hepatotoxicity and mEH expression by methylthiazoles, which are incorporated as functional groups in a number of therapeutic agents, were assessed in the rat liver to study the structural basis for the enzyme induction and the correlative enzyme expression with hepatotoxicity. Among the methylthiazoles examined, 4-methylthiazole (MT) at the daily dose of 1.17 mmol/kg body weight caused hepatic necrosis and degeneration after 1-3 consecutive daily treatment(s), whereas 4, 5-dimethylthiazole (DT) and 2,4,5-trimethylthiazole (TT) elicited no toxicity. Treatment of rats with MT at the daily dose of 1.17 mmol/kg increased the mEH mRNA by 17- and 7-fold at day 1 and day 3, respectively, relative to control. Whereas DT caused 5- and 2-fold increases in mEH mRNA at day 1 and day 3, respectively, TT minimally affected mEH expression. The mRNA increase was consistent with the protein induction. Hence, the methylthiazole causing hepatotoxicity was more active in inducing the enzyme. Whereas treatment with MT at the dose of 0.35 mmol/kg caused no hepatotoxicity, MT caused hepatic necrosis in starving rats. Northern blot analysis showed that the mEH mRNA level was increased to a greater extent by MT in starving rats than in control animals. Conversely, treatment of starving rats with either cysteine or methionine prior to MT prevented the hepatic necrosis. Elevation of the mEH mRNA by MT in starving animals was also inhibited by either cysteine or methionine pretreatment. These results demonstrated that the methylthiazole which caused hepatotoxicity also up-regulated mEH expression, whereas other methylthiazoles showing no toxicity minimally increased the gene expression. The observation that the extent of mEH expression by MT was highly associated with that of liver injury raised the notion that mEH expression by xenobiotics may not necessarily represent the beneficial and protective effects.

Thioureas differentially induce rat hepatic microsomal epoxide hydrolase and rGSTA2 irrespective of their oxygen radical scavenging effect: effects on toxicant-induced liver injury

Thioureas have been employed as potent hydroxyl radical scavengers and also inhibit production of oxygen free radicals. The in vitro oxygen radical scavenging effect by N,N'-substituted thioureas including dimethylthiourea (DMT), diethylthiourea (DET), tetramethylthiourea (TMT) and diphenylthiourea (DPT) was assessed by the conversion of phi x-174 DNA from supercoiled DNA to the open circular form or to fragmented DNA. Addition of the N,N'-substituted thioureas to the incubation mixture significantly prevented a single strand breakage of phi x-174 DNA induced by autooxidation of benzenetriol. These thioureas were also effective in preventing degradation of phi x-174 DNA induced by autooxidation of benzenetriol in the presence of ferrous iron. In view of the in vitro radical scavenging effect by the thioureas and the role of reactive oxygen species in the induction of phase II detoxifying enzymes, expression of microsomal epoxide hydrolase (mEH) and rGSTA2 in response to these agents was investigated in the rat liver. Rats treated with each of the alkylthioureas exhibited marked increases of mEH and rGSTA2 mRNA levels with TMT being the most effective. DPT an arylthiourea, however, was minimally active in increasing the mRNAs. Time-course studies revealed that DMT, DET and TMT increased the mRNA levels to the greatest extent at 24 h after a single dose of treatment. The levels of mEH and rGSTA2 mRNA were elevated in a dose-dependent manner by the alkylthioureas. Immunoblot analysis showed that the alkylthioureas induced mEH and rGSTA2 proteins in the liver (0.6 mmol/kg per day, 3 days), which was consistent with the increases in the mRNA levels. DMT, DET or TMT enhanced CCl4-induced liver toxicity, as monitored by plasma aminotransferase activity, although each of the agents alone caused only slight increase in the alanine aminotransferase activity. In contrast to the effects of the alkylthioureas, DPT protected the liver against the toxicant-induced injury. All of the thioureas prevented decreases in the hepatic glutathione level by CCl4. Expression of cytochrome P450 2E1 and P450 2B1/2, which are implicated with metabolic activation of CCl4, was assessed after treatment with the thioureas. P450 2E1 and P450 2B1/2 were differentially induced by the alkylthioureas with the expression of P450 2E1 being inversely related with that of P450 2B1/2. These results showed that N,N'-substituted alkylthioureas were capable of inducing mEH and rGSTA2 in the liver with elevation of the mRNAs, that induction of mEH and rGSTA2 by these alkylthioureas might be mediated by production of the reactive oxygens derived from metabolic activation of the agents irrespective of their radical scavenging effect and that the agents rather enhanced toxicant-induced liver injury with the induction of P450 2E1 or P450 2B1/2.

Differential induction of rat hepatic microsomal epoxide hydrolase and rGSTA2 by diazines: the role of cytochrome P450 2E1-mediated metabolic activation

Previous studies have shown that pyridazine (PD) and pyrazine (PZ) are efficacious in inducing microsomal epoxide hydrolase (mEH) in the liver with elevation of the mRNA level. The present study was designed to investigate the expression of mEH and rGSTA2 genes in response to the diazines including PD, PZ and pyrimidine (PM) and the basis for their enzyme induction. Rats treated with either PD or PZ for 3 days resulted in marked increases in mEH and rGSTA2 mRNA levels with concomitant induction of the proteins, whereas PM failed to elevate the mRNA levels. Treatment of rats with a single dose of PD or PZ showed dose-dependent increases in mEH and rGSTA2 mRNA levels at 24 h with ED50 values being approximately 10 mg/kg. Time-course studies showed that the mRNA levels were increased to maximal extents at 24-48 h after treatment. Studies were extended to assess the mechanistic basis for the enzyme induction by PD and PZ. beta-Naphthoflavone (BNF) caused a 6-fold increase of rGSTA2 mRNA in the liver (100 mg/kg per day, p.o., 3 days), as compared to control, whereas the agent failed to increase mEH mRNA level. Administration of PD or PZ (50 mg/kg) to BNF-pretreated rats resulted in no enhanced increase of the mEH mRNA as compared to the individual treatment, while the rGSTA2 mRNA level was additively elevated, suggesting the possibility that increases of the mEH and rGSTA2 mRNAs by PD or PZ might be mediated with antioxidant responsive element(s) in the genes, but not with xenobiotic responsive element. Western blot analysis revealed that cytochrome P450 2E1 was induced 3- to 4-fold by both PD and PZ, whereas PM failed to induce P450 2E1. Concomitant treatment of rats with PD or PZ in combination with acetone, a substrate for P450 2E1, caused no significant increase in the mEH and rGSTA2 mRNA levels relative to that in untreated animals, whereas PD or PZ treatment without a concomitant acetone administration resulted in marked increases of the mRNAs. Diazine-inducible mEH and rGSTA2 mRNA levels were approximately 2-fold enhanced in P450 2E1-induced starved rats, as compared to those in diazine-treated unstarved animals. These data indicate that P450 2E1-mediated bioactivation of the diazines might contribute to transcriptional activation of the mEH and GST genes. These results provide evidence that both PD and PZ efficaciously induce mEH and rGSTA2 in the liver with increases in the mRNA levels, while PM is ineffective, and that induction of mEH and rGSTA2 may be mediated through bioactivation of the diazines by P450 2E1.

Expression of glutathione S-transferases Ya, Yb1, Yb2, Yc1 and Yc2 and microsomal epoxide hydrolase genes by thiazole, benzothiazole and benzothiadiazole

The effects of thiazole (TH), benzothiazole (BT) and benzothiadiazole (BZ) on the expression of hepatic glutathione S-transferases (GSTs) Ya, Yb1, Yb2, Yc1 and Yc2 and microsomal epoxide hydrolase (mEH) genes were compared in rats. TH treatment resulted in 4- to 24-fold increases in GST Ya mRNA levels at 24 hr posttreatment; the ED50 value was 70 mg/kg. GST Ya mRNA levels were elevated 13-, 20-, 20- and 9-fold at 12, 24, 48 and 72 hr following 100 mg/kg of TH treatment, respectively, as compared with the control. BT was a moderate inducer of GST Ya with a maximal 18-fold increase observed, whereas BZ treatment caused a transient increase in GST Ya mRNA at 12 hr posttreatment, followed by a return to a 4-fold relative increase at 24 hr or afterward. Treatment of rats with TH at the dose of 100 mg/kg resulted in an approximately 10-fold increase in either Yb1 or Yb2 mRNA levels at 24 hr posttreatment. BT-treated rats showed 7- and 3-fold increases in the GST subunit Yb1 and Yb2 mRNA levels at 24 hr posttreatment. BZ was the least effective in modulating either GST Yb1 or Yb2 mRNA, resulting in < 2-fold changes. GST Yc1 and Yc2 mRNA levels were increased approximately 8-fold at the dose of 200 mg/kg of TH. BT minimally affected GST subunit Yc1 and Yc2 mRNA levels, with a maximal 4-fold relative increase observed. BZ was the least effective in enhancing Yc1 and Yc2 mRNA levels. Protein levels for GST subunit Ya, Yb1, Yb2 and Yc were also elevated in response to TH by 3-, 2-, 2-, and 2-fold, respectively. Thus, TH was effective in modulating both constitutive and inducible GST gene expression. BT or BZ was much less effective in increasing the expression of GST subunits. These RNA and Western blot analyses revealed that the levels of major GST were differentially increased after treatment with these thiazoles, exhibiting a rank order of GST expression of TH > BT > BZ. mEH expression by these compounds appeared to be consistent with that of GST Ya. The mRNA levels for GST Ya, Yb1, Yb2, Yc1 and Yc2 and mEH were also determined after treatment with triazole (TR), imidazole (IM), benzoxazole (BX), benzotriazole (BTR) or benzimidazole (BIM). TR, IM, BX or BTR caused increases in Ya, Yb1, Yc1 and Yc2 mRNA levels by 2- to 3-fold, whereas the agents failed to modulate the expression of GST Yb2. The fact that benzene, cyclohexane or n-hexane minimally affected the major GST or mEH mRNA levels provided evidence that certain heterocyclic compounds are more capable of modulating GST or mEH gene expression than hydrocarbons. These results corroborate evidence that the thiazoles differentially stimulate GST or mEH genes, with TH being the most efficacious; that thiazoles with carbocyclic ring are much less effective in increasing GST or mEH levels than is TH; and that the changes in these GST and mEH levels are primarily associated with increases in mRNA levels.

Expression of rat microsomal epoxide hydrolase during pregnancy

Microsomal epoxide hydrolase (mEH) protein and messenger ribonucleic acid (mRNA) levels were assessed in maternal rats during pregnancy and mEH gene expression was compared with cytochrome P450 expression. Immunoblot analysis using goat anti-rat mEH antibody showed that hepatic mEH levels in adult rats at day 12 of gestation were comparable to those in virgin female rats at the same age, whereas mEH protein levels were substantially decreased by approximately 70% at day 20 of pregnancy. Northern and slot blot analyses revealed that hepatic mEH mRNA levels failed to be modulated at day 12 of pregnancy, whereas mEH mRNA levels were decreased to approximately 20% of virgin control in late pregnancy (i.e. day 20), which was consistent with the result of mEH immunoblot analysis. Hepatic cytochrome P4502E1 levels were also diminished at day 12 and day 20 of gestation by approximately 50% and approximately 70%, respectively, relative to virgin control rats, as supported by immunoblot analysis. Hepatic P4502E1 mRNA levels at day 12 and day 20 of pregnancy were also significantly decreased to 30% and 8% of virgin rats at 17 weeks of age, respectively, demonstrating that suppression in P4502E1 protein levels accompanied decreases in its mRNA expression. The levels of cytochrome P4501A2 mRNA at either day 12 or day 20 of pregnancy was decreased by approximately 50% relative to virgin female rats, which was less than that observed in mEH or P4502E1 expression. Pregnancy failed to affect P4501A1 mRNA levels, which were not detectable in female rats at 17 weeks of age. Renal mEH mRNA levels in maternal rats at day 20 of gestation were also decreased to 25% of virgin control. These results demonstrated that levels of mEH and P4502E1 proteins decreased significantly in late pregnancy with concomitant decreases in their mRNA levels.