Induction of rat hepatic P450IIE1 (CYP 2E1) by pyridine: evidence for a role of protein synthesis in the absence of transcriptional activation

Effect of pyridine on the hepatic and pulmonary metabolism of 2-butanol in rat and rabbit

Pyridine has been shown to be an effective inducer of the ethanol-inducible cytochrome P-450IIE1 in both liver and lung. The oxidation of 2-butanol by rat liver is inducible by chronic ethanol consumption. The purpose of this study was to determine the effect of pyridine on the hepatic and pulmonary metabolism of butanol. Comparisons were made between rat and rabbit. Acute pyridine treatment (200 mg/kg, ip) increased hepatic metabolism of 2-butanol in the rat twofold and in the rabbit threefold. The effect of pyridine on hepatic butanol oxidase is similar to the effect reported by other investigators for ethanol administered in the drinking water for 3 wk. Control rabbit pulmonary butanol oxidase activity was 10-fold higher than that in the rat. Pyridine decreased pulmonary butanol oxidase activity in the rabbit. The effect was demonstrated both in vitro and in the isolated perfused rabbit lung. Pyridine had no effect on pulmonary butanol oxidase activity in the rat.

Potentiation of carbon tetrachloride-induced hepatotoxicity and pneumotoxicity by pyridine

Induction of P450IIE1 by pyridine was compared with that by ethanol, and the resulting potentiation of the pneumotoxicity and hepatotoxicity following carbon tetrachloride inhalation by pyridine was examined. Rats were treated with ethanol as either a 10% solution in the drinking water or as a daily bolus (3 ml/kg, ip) dose for 7 days or one bolus dose of pyridine (200 mg/kg, ip) and compared for P450IIE1 apoprotein content by immunoblot analysis. Ethanol in the drinking water and pyridine elevated both hepatic and pulmonary P450IIE1 apoprotein content, but bolus dose ethanol did not. The induction was greatest in the pyridine group. In the interaction study, rats were treated with pyridine (200 mg/kg, ip) and 12 hours later were exposed to CCl4 (8000 ppm for 3 hours). Pulmonary injury and hepatic damage were assessed 24 hours later by bronchoalveolar lavage fluid (BALF) analysis [gamma-glutamyl transpeptidase (GGT), lactate dehydrogenase (LDH), and total protein] and serum sorbitol dehydrogenase (SDH) activity, respectively. Pyridine alone had no effect on BALF or SDH but enhanced GGT and LDH release into the BALF and SDH release into the serum when compared with CCl4 exposure alone. Evaluation of the liver at the light microscopic level revealed characteristic CCl4-induced centrilobular necrosis which was potentiated by pyridine. No changes were observed in the lung by light microscopic evaluation. Pyridine induced pulmonary and hepatic microsomal apoprotein levels of cytochrome P450IIE1 two- and 2- to sixfold, respectively. Exposure to CCl4 decreased hepatic but not pulmonary P450IIE1 levels. Induction of cytochrome P450IIE1 by pyridine increases the bioactivation of CCl4 in both the liver and lung, leading to enhanced toxicity.

Induction of cytochrome P-4502E1 in the human liver by ethanol is caused by a corresponding increase in encoding messenger RNA

The propensity of centrilobular liver damage to develop in alcohol abusers after exposure to various hepatotoxins, including ethanol itself, has been linked to the induction by ethanol of P-4502E1, a microsomal P-450 enzyme that bioactivates these agents to reactive metabolites. Whereas long-term ethanol consumption elicits a marked increase in hepatic P-4502E1 content, the molecular mechanism by which ethanol produces this effect is the subject of controversy in animals, and it has not been elucidated in human beings. Possible mechanisms include increased enzyme synthesis stemming from elevated 2E1 messenger RNA levels, enhanced translation of preexisting messenger RNA or stabilization of P-4502E1 protein. To determine which, if any, of these mechanisms underlies P-4502E1 induction in human beings, we examined the effects of ethanol intake on the hepatic intralobular distribution of P-4502E1 messenger RNA and the corresponding protein. Liver sections derived from needle biopsy specimens were obtained from five recently drinking alcoholics (last drink no more than 36 hr before) and eight control subjects (five abstaining alcoholics [last drink 96 hr or more before] and three nondrinkers). In situ hybridization of these liver sections with a human P-4502E1 complementary DNA probe was used to localize P-4502E1 messenger RNA transcripts. Quantitative image analysis of hybridized sections from control subjects revealed that P-4502E1 transcript content in perivenular (zone 3) hepatocytes was significantly higher (p < 0.05) than in midzonal (zone 2) and periportal (zone 1) cells (18.3 +/- 1, 9.5 +/- 2 and 3.1 +/- 2 arbitrary density units, respectively; mean +/- S.E.M.). In recent drinkers, acinar regions containing P-4502E1 transcripts were elevated 2.9-fold compared with those in controls (32.8% +/- 7% vs. 11.2% +/- 2%; p < 0.01), with this messenger RNA increase occurring mainly in perivenular cells (29.6 +/- 3 vs. 18.3 +/- 1 units; p < 0.01). P-4502E1 protein distribution, assessed by the immunohistochemical staining of liver sections with P-4502E1 antibodies, was found to be analogous to that of the messenger RNA in control subjects (the level in perivenular cells was greater than that in midzonal cells, which was greater than that in periportal cells), whereas recent drinkers exhibited marked elevations in enzyme content in both perivenular and midzonal hepatocytes. Moreover, cellular levels of P-4502E1 protein and messenger RNA were significantly correlated (rs = 0.79; p < 0.001) in all patients.(ABSTRACT TRUNCATED AT 400 WORDS)

Bioactivation of halogenated hydrocarbons by cytochrome P4502E1

Numerous halogenated hydrocarbons of the alkane, alkene, and alkyne classes are metabolized by P450 enzymes to products that elicit cytotoxic and/or carcinogenic effects. Such halogenated hydrocarbons include anesthetics (e.g., halothane and enflurane) and industrial solvents (e.g., carbon tetrachloride, chloroform, and vinylidine chloride). Formation of reaction intermediates from these compounds occurs via P450-promoted dehalogenation, reduction, or reductive oxygenation, with certain hydrocarbons undergoing all three reaction types. Of the multiple forms of P450 present in liver microsomes, P4502E1 has been identified as the primary catalyst of hydrocarbon bioactivation in animals and, most likely, in humans as well. As hepatic concentrations of this P450 enzyme are highly inducible by ethanol and similar agents, prior exposure to 2E1-inducing compounds can play a pivotal role in halogenated hydrocarbon toxicity. Considering that metabolism governs the cytotoxicity and carcinogenicity of halogenated hydrocarbons, an understanding of the mechanism(s) underlying 2E1 induction in man becomes all the more important.

Post-transcriptional regulation of mouse renal cytochrome P450 2E1 by testosterone

Our previous studies demonstrated that the sex-related difference in renal metabolism of N-nitrosodimethylamine in C3H/HeJ mouse was due to the sexual dichotomy of cytochrome P450 2E1 (P450 2E1) and that renal P450 2E1 in female mouse was inducible by testosterone. The present study demonstrates that the sex-related difference in renal P450 2E1 and the testosterone-mediated regulation also occurred in other mouse strains studied. The time- and dose-responses in the testosterone-mediated regulation of P450 2E1 were characterized. 19-Nortestosterone, an analog of testosterone, was shown to have an effect on the regulation of mouse renal P450 2E1 similar to that of testosterone. Testicular feminized mice (Tfm, a mouse strain devoid of functional androgen receptors) had about only one-tenth the renal P450 2E1 mRNA level as the wild-type male mice and testosterone treatment of the Tfm mice had no effect on the level of renal P450 2E1 mRNA. The result suggests that androgen receptor plays an important role in the sex- and testosterone-related regulation of mouse renal P450 2E1. To study the mechanism of the sex-related and testosterone-mediated regulation of P450 2E1 mRNA in mouse kidney, the transcription rate of the P450 2E1 gene was measured by a nuclear run-on transcription assay. Although the kidneys of male and testosterone-treated female mice had much higher steady-state levels of P450 2E1 mRNA, their transcription rates of the P450 2E1 gene were not higher than the kidneys of untreated female mice. This result suggests that the sex- and testosterone-related regulation of mouse renal P450 2E1 is predominantly at the post-transcriptional level.

Evidence for elevation of cytochrome P4502E1 (alcohol-inducible form) mRNA levels in rat kidney following pyridine administration

The effects of pyridine on renal cytochrome P4502E1 (CYP2E1) expression in rat have been examined by immunoblot and Northern blot analyses. Immunoblot analyses revealed that 2E1 protein levels were elevated from 1.4- to 4.6-fold following pyridine administration in a dose- and time-dependent manner. Northern blot analyses revealed that renal 2E1 poly(A)+ RNA levels increased from 1.4- to 3.8-fold following pyridine treatment and that these increases in 2E1 mRNA paralleled the dose- and time-dependent increases in 2E1 protein content. In contrast, hepatic 2E1 poly(A)+ RNA levels failed to increase following these same dosing regimens, suggesting that metabolic alterations, such as those associated with starvation, were not etiologic factors in renal 2E1 induction. These results show that pyridine induced CYP2E1 in kidney and that elevation of renal 2E1 protein levels accompanying pyridine administration occurred at least partly as a consequence of increased 2E1 poly(A)+ RNA levels. The results of this research reveal that regulatory mechanisms governing CYP2E1 expression may differ in hepatic and renal tissues.

Time course characterization of the induction of cytochrome P-450 2E1 by pyrazole and 4-methylpyrazole

Cytochrome P-450 (P-450) 2E1 is under transcriptional and post-transcriptional control. Well-defined time courses were carried out to compare the effect of pyrazole and 4-methylpyrazole on catalytic activities, apo-P-450 2E1 levels and mRNA levels to evaluate whether induction of P-450 2E1 is preceded by altered mRNA levels. Two days of treatment with pyrazole or three days of treatment with 4-methylpyrazole resulted in significant induction of P-450 2E1, as assessed by Western blots and by oxidation of dimethylnitrosamine or p-nitrophenol. No changes in mRNA levels were detected with either inducer. Within 2 h of the second treatment with pyrazole, maximal induction of P-450 2E1 was observed, however, a 8-12 h time-dependent period was required after the third treatment with 4-methylpyrazole for maximal induction. Irrespective of the time period, increased catalytic activity and P-450 2E1 appears to reflect a post-transcriptional mechanism. A single treatment with 4-methylpyrazole increased P-450 2B1/B2 levels and oxidation of pentoxyresorufin about 2- to 3-fold. No change in mRNA levels for 2B1/B2 was observed. Although significant, the induction of 2B1/B2 by 4-methylpyrazole is more than an order of magnitude less than that by phenobarbital. Pyrazole did not induce 2B1/B2. It appears that, similar to acetone and ethanol, 4-methylpyrazole may increase several P-450 isozymes, whereas pyrazole is more specific for induction of P-450 2E1.

Pre-translational induction of pentoxyresorufin O-depentylase by pyridine

Pentoxyresorufin O-depentylase activity, mainly associated with phenobarbital-inducible cytochrome P450IIB1 (designated CYP2B1), was increased after a single treatment of pyridine (250 mg/kg, i.p.), and further increased by repeated treatments for 5 days. The catalytic activity and immunoreactive protein of CYP2B recognized by polyclonal antibodies were significantly induced by a relatively high dose of pyridine (250 mg/kg, i.p.) while ethanol-inducible cytochrome P450IIE1 (CYP2E1) could be induced by a low dosage (25 mg/kg, i.p.). Unlike CYP2E1 induction without changing its mRNA level, the induction of CYP2B by pyridine was accompanied by an elevation of its mRNA, indicating a pre-translational activation of this enzyme. These results indicate that pyridine induces various isozymes of cytochromes P450 by different induction mechanisms.

cDNA sequence, deduced amino acid sequence, predicted gene structure and chemical regulation of mouse Cyp2e1

The cDNA encoding the mouse Cyp2e1 protein has been isolated and sequenced, and shown to share 92%, 79%, 80% and 79% sequence similarity over the coding region with rat, human, rabbit 1 and rabbit 2 CYP2E1 cDNA sequences respectively. The predicted Cyp2e1 protein contains 493 amino acids, with a molecular mass of 56781 Da. The protein contains many features common to other cytochrome P450s, including a potentially phosphorylatable serine residue at position 129 within a canonical cyclic AMP-dependent protein kinase site. Southern blot analysis of genomic DNA prepared from C57BL/6 and DBA/2N mice suggests the presence of only a single Cyp2e1 gene. The Cyp2e1 gene was isolated and its organization was established by PCR using oligonucleotides to its predicted intron/exon boundaries. These results showed that the mouse Cyp2e1 gene is approx. 11,000 bp in length and has a similar structure to the human and rat CYP2E1 genes. Cyp2e1 protein expression was studied in a variety of tissues and a sexual dimorphism in its levels in some tissues was noted. Acetone treatment induced the Cyp2e1 protein in all of the tissues studied in both sexes, but this Cyp2e1 protein induction was not accompanied by an increase in Cyp2e1 mRNA levels. Indeed, mRNA levels were seen to be decreased on treatment, suggesting that acetone administration affects either mRNA translation efficiency or protein stability. Of a wide range of drugs known to modify other cytochrome P450 levels only diethylnitrosamine had a significant effect on Cyp2e1, causing a decrease in protein levels.

Post-translational reduction of cytochrome P450IIE by CCl4, its substrate

The molecular mechanism of cytochrome P450IIE reduction by CCl4 was reexamined by measuring its enzyme activity, immunoreactive protein contents, and mRNA levels. Aniline hydroxylase and the amounts of immunoreactive P450IIE were rapidly decreased in a time-dependent manner after a single dose of CCl4. No changes were observed in the amounts of immunoreactive P450IIC and P450IA despite significant decreases decrease in their catalytic activities. However, the decreases in P450IIE enzyme activity and immunoreactive protein by CCl4 were not accompanied by a decline in its mRNA level. The data thus suggested a post-translational reduction of P450IIE by CCl4, probably due to specific destruction of the P450IIE protein by its own substrate rather than heme moiety.

Toxicokinetics of inhaled 1,3-butadiene in monkeys: comparison to toxicokinetics in rats and mice

1,3-Butadiene is a potent carcinogen in mice and a weaker carcinogen in rats. People are exposed to butadiene through its industrial use--largely in rubber production (over 3 billion pounds of butadiene were produced in 1989)--and because it is common in the environment, occurring in cigarette smoke, gasoline vapor and in the effluents from fossil fuel incineration. Epidemiological studies have provided some evidence for butadiene carcinogenicity in people. Differences in the uptake and metabolism of inhaled butadiene between rodents and primates, including people, might be reflected in differences in its toxicity. In order to compare uptake and metabolism in primates to that in rodents--for which data were already available--we exposed cynomolgus monkeys (Macaca fascicularis) to 14C-labeled butadiene at concentrations of 10.1, 310 or 7760 ppm for 2 hr. Exhaled air and excreta were collected during exposure and for 96 hr after exposure. The uptake of butadiene as a result of metabolism was much lower in monkeys than in rodents. For equivalent inhalation exposures, the concentrations of total butadiene metabolites in the blood were 5-50 times lower in monkey than in the mouse, the more sensitive rodent species, and 4-14 times lower than in the rat. If the toxicokinetics of butadiene in people is more like that of the monkey than that of rodents, then our data suggest that people will receive lower doses of butadiene and its metabolites than rodents following equivalent inhalation exposures to butadiene. This has important implications for assessing the risk to humans of butadiene exposure based on animal studies.

Nasal cavity enzymes involved in xenobiotic metabolism: effects on the toxicity of inhalants

A decade ago, the ability of nasal tissues to metabolize inhalants was only dimly suspected. Since then, the metabolic capacities of nasal cavity tissues has been extensively investigated in mammals, including man. Aldehyde dehydrogenases, cytochrome P-450-dependent monooxygenases, rhodanese, glutathione transferases, epoxide hydrolases, flavin-containing monooxygenases, and carboxyl esterases have all been reported to occur in substantial amounts in the nasal cavity. The contributions of these enzyme activities to the induction of toxic effects from inhalants such as benzo-a-pyrene, acetaminophen, formaldehyde, cocaine, dimethylnitrosamine, ferrocene, and 3-trifluoromethylpyridine have been the subject of dozens of reports. In addition, the influence of these enzyme activities on olfaction and their contribution to vapor uptake is beginning to receive attention from the research community. Research in the next decade promises to provide answers to the many still unanswered questions posed by the presence of the substantial xenobiotic metabolizing capacity of the nasal cavity.

Evidence for increased translational efficiency in the induction of P450IIE1 by solvents: analysis of P450IIE1 mRNA polyribosomal distribution

The potential for enhanced translational processing of P450IIE1 mRNA during the early phase of P450IIE1 induction by pyridine or acetone was assessed by hybridization analysis of polyribosomal P450IIE1 mRNA distribution in rat hepatic tissue. Optical absorbance profiles of polyribosomal fractions exhibited an apparent shift at 5 h following pyridine administration relative to control. Slot and Northern blot analyses for P450IIE1 mRNA in the cytoplasmic extracts isolated from 5 h pyridine-treated rats demonstrated a shift in distribution of P450IIE1 message toward heavier polyribosomal fractions and Northern blot analysis suggested the presence of different populations of P450IIE1 mRNA. Slot blot analyses also demonstrated a shift in the polyribosomal distribution of P450IIE1 mRNA at 12 h following pyridine treatment; in contrast, hybridization analysis for P450IA1 revealed no shift in polyribosomal distribution of P450IA1 mRNA. Acute acetone administration to animals also resulted in a similar shift in polyribosomal distribution of P450IIE1 mRNA as compared to control. These data suggest that P450IIE1 mRNA shifts toward larger polyribosomes following acute exposure of animals to pyridine or acetone and provide evidence that induction of P450IIE1 at early times following acute pyridine or acetone administration involves enhanced translational efficiency through increased loading of ribosomes on P450IIE1 mRNA.

Multiple mechanisms in the regulation of ethanol-inducible cytochrome P450IIE1

Cytochrome P450IIE1 is involved in the metabolic activation of many xenobiotics involved with human toxicity. In particular, cellular concentrations of P450IIE1 are significantly induced by the most widely abused drug in our society today, alcohol. As a result, the synthesis and degradation of this form of P450 has significant health consequences. The regulation of the steady-state concentration of P450IIE1 is an extremely complex process. The enzyme is regulated by transcriptional activation, mRNA stabilization, increased mRNA translatability and decreased protein degradation. The principal mechanism which controls the induction process depends on the chemical nature of the inducer, the age, and the nutritional and hormonal status of the animal. There also appear to be significant sex differences in the expression of P450IIE1. It is entirely possible that the regulation of the enzyme concentration under any given set of conditions will involve all of the mechanisms to different extents.