Oxidative metabolism of the alkaloid rutaecarpine by human cytochrome P450.

Rutaecarpine is the main active alkaloid of the herbal medicine, Evodia rutaecarpa. To identify the major human cytochrome P450 (P450) participating in rutaecarpine oxidative metabolism, human liver microsomes and bacteria-expressed recombinant human P450 were studied. In liver microsomes, rutaecarpine was oxidized to 10-, 11-, 12-, and 3-hydroxyrutaecarpine. Microsomal 10- and 3-hydroxylation activities were strongly inhibited by ketoconazole. The 11- and 12-hydroxylation activities were inhibited by alpha-naphthoflavone, quinidine, and ketoconazole. These results indicated that multiple hepatic P450s including CYP1A2, CYP2D6, and CYP3A4 participate in rutaecarpine hydroxylations. Among recombinant P450s, CYP1A1 had the highest rutaecarpine hydroxylation activity. Decreased metabolite formation at high substrate concentration indicated that there was substrate inhibition of CYP1A1- and CYP1A2-catalyzed hydroxylations. CYP1A1-catalyzed rutaecarpine hydroxylations had V(max) values of 1,388 to approximately 1,893 pmol/min/nmol P450, K(m) values of 4.1 to approximately 9.5 microM, and K(i) values of 45 to approximately 103 microM. These results indicated that more than one molecule of rutaecarpine is accessible to the CYP1A active site. The major metabolite 10-hydroxyrutaecarpine decreased CYP1A1, CYP1A2, and CYP1B1 activities with respective IC(50) values of 2.56 +/- 0.04, 2.57 +/- 0.11, and 0.09 +/- 0.01 microM, suggesting that product inhibition might occur during rutaecarpine hydroxylation. The metabolite profile and kinetic properties of rutaecarpine hydroxylation by human P450s provide important information relevant to the clinical application of rutaecarpine and E. rutaecarpa.     

Characterization of human liver cytochrome P450 enzymes involved in the metabolism of rutaecarpine

Rutaecarpine has recently been characterized to have an anti-inflammatory activity through cyclooxygenase-2 inhibition. The incubation of rutaecarpine with human liver microsomes in the presence of NADPH generated six isobaric mono-hydroxylated metabolites. The specific cytochrome P450 (CYP) isozymes responsible for rutaecarpine metabolites were identified using the combination of chemical inhibition, immuno-inhibition and metabolism by cDNA expressed CYP enzymes. The results suggested that CYP3A4 might play major roles in the metabolism of rutaecarpine in human liver microsomes. The production of M1, M2, M3, M4 and M6 formed in human liver microsomes was inhibited by ketoconazole, a selective CYP3A4 inhibitor, and anti-CYP3A4 antibody. CYP1A2 and CYP2C9 played minor roles in the metabolism of rutaecarpine. These results were confirmed in microsomes derived from cDNA expressed lymphoblastoid cells. CYP3A4 microsome clearly formed M1, M2, M3 and M6. CYP1A2 and CYP2C9 microsomes comparably formed M5.     

The alkaloid rutaecarpine is a selective inhibitor of cytochrome P450 1A in mouse and human liver microsomes.

Rutaecarpine, evodiamine, and dehydroevodiamine are quinazolinocarboline alkaloids isolated from a traditional Chinese medicine, Evodia rutaecarpa. The in vitro effects of these alkaloids on cytochrome P450 (P450)-catalyzed oxidations were studied using mouse and human liver microsomes. Among these alkaloids, rutaecarpine showed the most potent and selective inhibitory effect on CYP1A-catalyzed 7-methoxyresorufin O-demethylation (MROD) and 7-ethoxyresorufin O-deethylation (EROD) activities in untreated mouse liver microsomes. The IC(50) ratio of EROD to MROD was 6. For MROD activity, rutaecarpine was a noncompetitive inhibitor with a K(i) value of 39 +/- 2 nM. In contrast, rutaecarpine had no effects on benzo[a]pyrene hydroxylation (AHH), aniline hydroxylation, and nifedipine oxidation (NFO) activities. In human liver microsomes, 1 microM rutaecarpine caused 98, 91, and 77% decreases of EROD, MROD, and phenacetin O-deethylation activities, respectively. In contrast, less than 15% inhibition of AHH, tolbutamide hydroxylation, chlorzoxazone hydroxylation, and NFO activities were observed in the presence of 1 microM rutaecarpine. To understand the selectivity of inhibition of CYP1A1 and CYP1A2, inhibitory effects of rutaecarpine were studied using liver microsomes of 3-methylcholanthrene (3-MC)-treated mice and Escherichia coli membrane expressing bicistronic human CYP1A1 and CYP1A2. Similar to the CYP1A2 inhibitor furafylline, rutaecarpine preferentially inhibited MROD more than EROD and had no effect on AHH in 3-MC-treated mouse liver microsomes. For bicistronic human P450s, the IC(50) value of rutaecarpine for EROD activity of CYP1A1 was 15 times higher than the value of CYP1A2. These results indicated that rutaecarpine was a potent inhibitor of CYP1A2 in both mouse and human liver microsomes.     

吴茱萸次碱在人肝微粒体中对细胞色素P450酶的抑制作用

目的研究吴茱萸次碱(WZY)在人肝微粒体中对细胞色素P450酶的抑制作用。方法对照组和抑制组酶活性均用探针药测定,探针药物及其代谢产物用HPLC进行检测。用代谢产物与母药比值来表达酶的活性。结果加入50μmol·L-1吴茱萸次碱组CYP1A2,CYP2C19,CYP2E1和CYP2D6的活性显著降低,CYP3A4和CYP2C9活性无显著变化。结论吴茱萸次碱对CYP1A2,CYP2C19,CYP2E1和CYP2D6的活性有显著抑制作用,而对CYP2C9和CYP3A4的活性无显著影响。     

Metabolism of genistein by rat and human cytochrome P450s.

The metabolism of genistein (4',5,7-trihydroxyisoflavone), a phytoestrogen derived from soy products, was investigated using rat and human liver microsomes and recombinant human cytochrome P450 enzymes. Metabolism of genistein by microsomes obtained from rats treated with pyridine, phenobarbital, beta-naphthoflavone, isosafrole, pregnenolone-16alpha-carbonitrile, or 3-methylcholanthrene resulted in very different product profiles consisting of five different NADPH- and time-dependent metabolites as observed by HPLC reverse-phase analysis at 260 nm. The metabolism of genistein was also investigated with recombinant human cytochrome P450 1A1, 1A2, 1B1, 2B6, 2C8, 2E1, or 3A4. P450s 1A1, 1A2, 1B1, and 2E1 metabolized genistein to form predominantly one product (peak 3) with smaller amounts of peaks 1 and 2. P450 3A4 produced two different products (peaks 4 and 5). Product peaks 1-3 eluted off the HPLC column prior to the parent compound genistein, and the UV/vis spectra, GC/MS, and ESI/MS/MS analyses support the conclusion that these products result from hydroxylation of genistein. The product peak 3 has been identified by tandem mass spectrometry as 3',4',5, 7-tetrahydroxyisoflavone, also known as orobol, and peaks 1 and 2 appear to be hydroxylated at position 6 or 8.     

Differential selectivity in carbamazepine-induced inactivation of cytochrome P450 enzymes in rat and human liver

Oxidative metabolism of carbamazepine results in covalent binding of its reactive metabolite to liver microsomal proteins, which has been proposed as an important event in pathogenesis of the hypersensitivity reactions to this drug. Although the proposed reactive metabolites are produced by cytochrome P450 enzymes (P450 or CYP), the impact of the formation of unstable metabolites on the enzyme itself has not been elucidated. The present study examines the alteration of P450 enzyme activities during the metabolism of carbamazepine. Liver microsomes from rats and humans were preincubated with carbamazepine in the presence of NADPH, and subsequently assayed for monooxygenase activities representing several P450s. No evidence was obtained for inactivation of CYP2C11, CYP3A, CYP1A1/2 or CYP2B1/2 in rat liver microsomes during the carbamazepine metabolism, whereas the CYP2D enzyme was inactivated in a manner related to the preincubation time. Interestingly, under the same protocol human liver microsomes did not exhibit inactivation of CYP2D6, as well as there being no CYP2C8, CYP2C9 or CYP3A4 inactivation, whereas CYP1A2 was inactivated. Reduced glutathione could not protect against the observed inactivation of the P450s. These results suggest that CYP2D enzyme(s) in rats and CYP1A2 in humans biotransform carbamazepine into reactive metabolites, resulting in inactivation of the enzyme themselves, and raise the possibility that the P450 isoforms participate in toxicity induced by the drug in both animal species.     

Characterization of triptolide hydroxylation by cytochrome P450 in human and rat liver microsomes

Triptolide, the primary active component of a traditional Chinese medicine Tripterygium wilfordii Hook F, has a wide range of pharmacological activities. In the present study, the metabolism of triptolide by cytochrome P450s was investigated in human and rat liver microsomes. Triptolide was converted to four metabolites (M-1, M-2, M-3, and M-4) in rat liver microsomes and three (M-2, M-3, and M-4) in human liver microsomes. All the products were identified as mono-hydroxylated triptolides by liquid chromatography-mass spectrometry (LC-MS). The studies with chemical selective inhibitors, complementary DNA-expressed human cytochrome P450s, correlation analysis, and enzyme kinetics were also conducted. The results demonstrate that CYP3A4 and CYP2C19 could be involved in the metabolism of triptolide in human liver, and that CYP3A4 was the primary isoform responsible for its hydroxylation.     

Characterization of triptolide hydroxylation by cytochrome P450 in human and rat liver microsomes

Triptolide, the primary active component of a traditional Chinese medicine Tripterygium wilfordii Hook F, has a wide range of pharmacological activities. In the present study, the metabolism of triptolide by cytochrome P450s was investigated in human and rat liver microsomes. Triptolide was converted to four metabolites (M-1, M-2, M-3, and M-4) in rat liver microsomes and three (M-2, M-3, and M-4) in human liver microsomes. All the products were identified as mono-hydroxylated triptolides by liquid chromatography-mass spectrometry (LC-MS). The studies with chemical selective inhibitors, complementary DNA-expressed human cytochrome P450s, correlation analysis, and enzyme kinetics were also conducted. The results demonstrate that CYP3A4 and CYP2C19 could be involved in the metabolism of triptolide in human liver, and that CYP3A4 was the primary isoform responsible for its hydroxylation.     

Trimethoprim: novel reactive intermediates and bioactivation pathways by cytochrome p450s

Trimethoprim (TMP) is a widely used antibacterial agent that is usually considered as a safe drug. TMP has, however, been implicated in rare adverse drug reactions (ADRs) in humans. Bioactivation to a reactive iminoquinone methide intermediate has been proposed as a possible cause for the toxicity of the drug. However, little is known about the cytochrome P450s (P450s) involved in this bioactivation and in the metabolism of TMP in general. In this study, we have investigated the metabolism and bioactivation of TMP by human liver microsomes (HLM) and rat liver microsomes, by recombinant human cytochrome P450s, and by the bacterial P450 BM3 mutant M11(his). In addition to non GSH-dependent metabolites, five GSH adducts were identified in the HLM incubations. Next to two major GSH adducts probably originating from the iminoquinone methide intermediate described previously, three minor GSH adducts were also identified, indicating that other types of reactive intermediates are formed by HLM, such as ortho-quinones and para-quinone methide intermediates. The major GSH adducts were produced by P450 1A2 and P450 3A4, while the minor GSH adducts were mainly formed by P450 1A2, P450 3A4, and P450 2D6. Although preliminary, these results might implicate that genetic polymorphisms in P450 enzymes could play a role in the onset of TMP-related ADRs in humans.     

Theophylline metabolism by human, rabbit and rat liver microsomes and by purified forms of cytochrome P450

The capacity of human, rabbit and rat liver microsomes and purified isozymes of cytochrome P450 to metabolize theophylline has been assessed. In all three species the 8-hydroxylation of theophylline to 1,3-dimethyluric acid (1,3-DMU) was the major pathway. In human, control rabbit and rat liver microsomes this metabolite accounted for 59, 77 and 94%, respectively, of the total metabolites formed. In both human and control rabbit liver microsomes the N-demethylation of theophylline to 1-methylxanthine (1-MX) accounted for 20% of the total metabolites formed. N-demethylation of theophylline to 3-methylxanthine (3-MX) accounted for 21% of theophylline metabolism in human microsomes but was a minor pathway in control rabbit and rat microsomes. Acetone and phenobarbitone pretreatment markedly increased the formation of 1,3-DMU by rabbit liver microsomes. Rifampicin and 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) administration caused a slight but significant increase in this pathway. In general the N-demethylation pathways in rabbit liver microsomes were refractory to induction. In the rat, the metabolism of theophylline to 1-MX, 3-MX and 1,3-DMU were all significantly increased in Aroclor 1254, dexamethasone, phenobarbitone and 3-methylcholanthrene-treated microsomes. In reconstitution experiments the polycyclic hydrocarbon inducible rabbit cytochrome P450 Forms 4 and 6 and the constitutive Form 3b all metabolized theophylline to its three metabolites. In human liver microsomes from four subjects anti-rabbit cytochrome P450 Form 4 IgG inhibited the metabolism of theophylline to 1-MX, 3-MX and 1,3-DMU by approximately 30%. These data indicate that theophylline is metabolized by multiple forms of cytochrome P450 in human, rabbit and rat liver microsomes.     

Hepatic microsomal metabolism of the anthelmintic benzimidazole fenbendazole: enhanced inhibition of cytochrome P450 reactions by oxidized metabolites of the drug.

Potentiation of the anthelmintic action of benzimidazole carbamates, such as fenbendazole [methyl 5(6)-(phenylthio)-1H-benzimidazol-2-ylcarbamate], has been noted during concurrent administration of benzimidazoles that possess no intrinsic anthelmintic activity. This study investigated the possibility that inhibition of P450 enzymes by fenbendazole and its metabolites could play a role in the potentiation phenomenon. Fenbendazole underwent P450-mediated oxidation in microsomes from untreated rat liver to the sulfoxide and (4'-hydroxyphenyl)thio metabolites [2.92 and 2.87 nmol/(mg of protein.h)]. Pretreatment of rats with phenobarbital or dexamethasone enhanced sulfoxidation by 1.9- and 2.9-fold, respectively. 4'-Hydroxylation was increased slightly (by 28%) by phenobarbital and decreased slightly (by 41%) by dexamethasone. Induction also promoted further metabolism of the sulfoxide to fenbendazole sulfone. Immunoinhibition and chemical inhibition studies suggested that P450 3A proteins and the flavin-containing monooxygenase are involved in sulfoxide and sulfone formation whereas 4'-hydroxylation involved the P450s 2C11, 2C6, and 2B1, depending on the type of induction. In untreated rat liver, the sulfoxide and (4'-hydroxyphenyl)thio metabolites of fenbendazole were relatively potent inhibitors of P450-mediated androstenedione 16 alpha-, 16 beta-, and 6 beta-hydroxylation (IC50 values of 42, 36, and 74 microM, respectively); 7 alpha-hydroxylase activity was uninhibited. In contrast, fenbendazole and its sulfone metabolite were not inhibitors of these reactions. Mixed-function oxidase activities in phenobarbital-induced rat hepatic microsomes were refractory to inhibition by most compounds, but P450 1A1 mediated activities in microsomes from beta-naphthoflavone-induced rat liver were quite susceptible to inhibition by fenbendazole sulfoxide. Studies with two analogous sulfoxides yielded similar findings.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of lindane on hepatic and brain cytochrome P450s and influence of P450 modulation in lindane induced neurotoxicity.

Oral administration of lindane (2.5, 5, 10 and 15 mg/kg, body weight) for 5 days was found to produce a dose-dependent increase in the activity of P450 dependent 7-ethoxyresorufin-O-deethylase (EROD), 7-pentoxyresorufin-O-dealkylase (PROD) and N-nitrosodimethylamine demethylase (NDMA-d) in rat brain and liver. A significant increase in the hepatic and brain P450 monooxygenases was also observed when the duration of exposure of low dose (2.5 mg/kg) of lindane was increased from 5 days to 15 or 21 days. As observed with different doses, the magnitude of induction in the activity of P450 monooxygenases was several fold higher in liver microsomes when compared with the brain. Western blotting studies have indicated that the increase in the P450 enzymes could be due to the increase in the expression of P450 1A1/1A2, 2B1/2B2 and 2E1 isoenzymes. In vitro studies using organic inhibitors specific for individual P450 isoenzymes and antibody inhibition experiments have further demonstrated that the increase in the activity of PROD, EROD and NDMA-d are due to the increase in the levels of P450 2B1/2B2, 1A1/1A2 and 2E1 isoenzymes, respectively. Induction studies have further shown that while pretreatment of 3-methylcholanthrene (MC), an inducer of P4501A1/1A2, did not produce any significant effect in the incidence of lindane induced convulsions, pretreatment with phenobarbital (PB), an inducer of P450 2B1/2B2 or ethanol, an inducer of P450 2E1 catalysed reactions, significantly increased the incidence of lindane induced convulsions. Similarly, when the P450-mediated metabolism of lindane was blocked by cobalt chloride incidence of convulsions was increased in animals treated with lindane indicating that lindane per se or its metabolites formed by PB or ethanol inducible P450 isoenzymes are involved in its neurobehavioral toxicity.     

In vitro metabolism of genistein and tangeretin by human and murine cytochrome P450s

Recombinant cytochrome P450 (CYP) 1A2, 3A4, 2C9 or 2D6 enzymes obtained from Escherichia coli and human liver microsomes samples were used to investigate the ability of human CYP enzymes to metabolize the two dietary flavonoids, genistein and tangeretin. Analysis of the metabolic profile from incubations with genistein and human liver microsomes revealed the production of five different metabolites, of which three were obtained in sufficient amounts to allow a more detailed elucidation of the structure. One of these metabolites was identified as orobol, the 3'-hydroxylated metabolite of genistein. The remaining two metabolites were also hydroxylated metabolites as evidenced by LC/MS. Orobol was the only metabolite formed after incubation with CYP1A2. The two major product peaks after incubation of tangeretin with human microsomes were identical with 4'-hydroxy-5,6,7,8-tetramethoxyflavone and 5,6-dihydroxy-4',7,8-trimethoxyflavone, previously identified in rat urine in our laboratory. By comparison with UV spectra and LC/MS fragmentation patterns of previously obtained standards, the remaining metabolites eluting after 14, 17 and 20 min. were found to be demethylated at the 4',7-, 4',6-positions or hydroxylated at the 3'- and demethylated at the 4'-positions, respectively. Metabolism of tangeretin by recombinant CYP1A2, 3A4, 2D6 and 2C9 resulted in metabolic profiles that qualitatively were identical to those observed in the human microsomes. Inclusion of the CYP1A2 inhibitor fluvoxamine in the incubation mixture with human liver microsomes resulted in potent inhibition of tangeretin and genistein metabolism. Other isozymes-selective CYP inhibitors had only minor effects on tangeretin or genistein metabolism. Overall the presented observations suggest major involvement of CYP1A2 in the hepatic metabolism of these two flavonoids.     

Stereo- and regioselectivity account for the diversity of dehydroepiandrosterone (DHEA) metabolites produced by liver microsomal cytochromes P450.

The purpose of this study was to quantify the oxidative metabolism of dehydroepiandrosterone (3beta-hydroxy-androst-5-ene-17-one; DHEA) by liver microsomal fractions from various species and identify the cytochrome P450 (P450) enzymes responsible for production of individual hydroxylated DHEA metabolites. A gas chromatography-mass spectrometry method was developed for identification and quantification of DHEA metabolites. 7alpha-Hydroxy-DHEA was the major oxidative metabolite formed by rat (4.6 nmol/min/mg), hamster (7.4 nmol/min/mg), and pig (0.70 nmol/min/mg) liver microsomal fractions. 16alpha-Hydroxy-DHEA was the next most prevalent metabolite formed by rat (2.6 nmol/min/mg), hamster (0.26 nmol/min/mg), and pig (0.16 nmol/min/mg). Several unidentified metabolites were formed by hamster liver microsomes, and androstenedione was produced only by pig microsomes. Liver microsomal fractions from one human demonstrated that DHEA was oxidatively metabolized at a total rate of 7.8 nmol/min/mg, forming 7alpha-hydroxy-DHEA, 16alpha-hydroxy-DHEA, and a previously unidentified hydroxylated metabolite, 7beta-hydroxy-DHEA. Other human microsomal fractions exhibited much lower rates of metabolism, but with similar metabolite profiles. Recombinant P450s were used to identify the cytochrome P450s responsible for DHEA metabolism in the rat and human. CYP3A4 and CYP3A5 were the cytochromes P450 responsible for production of 7alpha-hydroxy-DHEA, 7beta-hydroxy-DHEA, and 16alpha-hydroxy-DHEA in adult liver microsomes, whereas the fetal/neonatal form CYP3A7 produced 16alpha-hydroxy and 7beta-hydroxy-DHEA. CYP3A23 uniquely formed 7alpha-hydroxy-DHEA, whereas other P450s, CYP2B1, CYP2C11, and CYP2D1, were responsible for 16alpha-hydroxy-DHEA metabolite production in rat liver microsomal fractions. These results indicate that the stereo- and regioselectivity of hydroxylation by different P450s account for the diverse DHEA metabolites formed among various species.     

Oxidation and rearrangements of flavanones by mammalian cytochrome P450

To clarify the metabolic pathways of flavanones in mammals, the metabolism of (+/-)-flavanone and (+/-)-4'-methoxyflavanone by rat liver microsomes and recombinant human P450s in which structural changes are readily identifiable were examined. The beta-nicotinamide adenine dinucleotide phosphate (NADPH)-dependent formation of flavone plus (+/-)-2,3-trans-flavanonol and of 4'-methoxyflavone plus (+/-)-2,3-trans-4'-methoxyflavanonol, respectively, by rat liver microsomes was observed. The same metabolites were generated by recombinant human P450s in addition to the formation of isoflavone from (+/-)-flavanone. The kinetic isotope effects in these reactions were examined using deuterated (+/-)-flavanone and (+/-)-4'-methoxyflavanone. There was a strong isotope effect in the production of flavanonols, but the isotope effect in the production of flavones was small. The results indicated that the P450-mediated conversion of (+/-)-flavanone and of (+/-)-4'-methoxyflavanone to the corresponding metabolites proceeded via abstraction of a hydrogen radical from the C-2- or C-3-position of the flavanone skeleton. The antioxidant properties of flavanone and its metabolites were examined by measuring superoxide-scavenging activity in a xanthine-xanthine oxidase-cytochrome c system. (+/-)-2,3-trans-Flavanonol had higher activity than that of other flavonoids. Flavanones are metabolized by mammalian P450s, providing important information relevant to the metabolism and pharmacological action of dietary flavanones.     

Oxidation of midazolam and triazolam by human liver cytochrome P450IIIA4

The metabolism of midazolam and triazolam to their 1'-hydroxy and 4-hydroxy metabolites was studied in microsomes of 15 human livers. The formation of both metabolites was inhibited by more than 90% by an antiserum directed against a pregnenolone 16 alpha-carbonitrile-inducible cytochrome P450 (P450PCN1) of rat liver. Moreover, midazolam hydroxylase activity was immunoprecipitated from solubilized human microsomes with polyclonal antibodies against rat P450PCN1 and the closely related human isozyme P450NF. A close correlation was observed between the amount of protein detected in immunoblots with these antibodies and the midazolam or triazolam hydrxylase activity. The formation of both metabolites of midazolam was inhibited by triacetyloleandomycin, a known inhibitor of cytochromes P450 of the IIIA family. Direct evidence that P450IIIA4 catalyzes the metabolism of midazolam was provided through the use of cDNA-directed expression. Monkey COS cells transfected with human P450PCN1 cDNA were able to catalyze both the 1'- and the 4-hydroxylation of midazolam. We conclude that the metabolism of midazolam and triazolam in human liver is predominantly mediated by cytochrome P450IIIA4. Two of 15 human livers expressed a second immunoreactive microsomal protein of higher apparent Mr and were more active in midazolam 1'-hydroxylation. Our data also provide evidence that the marked interindividual variation in the response to these widely used benzodiazepine drugs is due to variable hepatic metabolism.     

Bioactivation of tamoxifen by recombinant human cytochrome p450 enzymes

Tamoxifen is a major drug used for adjuvant chemotherapy of breast cancer; however, its use has been associated with a small but significant increase in risk of endometrial cancer. In rats, tamoxifen is a hepatocarcinogen, and DNA adducts have been observed in both rat and human tissues. Tamoxifen has been shown previously to be metabolized to reactive products that have the potential to form protein and DNA adducts. Previous studies have suggested a role for P450 3A4 in protein adduct formation in human liver microsomes, via a catechol intermediate; however, no clear correlation was seen between P450 3A4 content of human liver microsomes and adduct formation. In the present study, we investigated the P450 forms responsible for covalent drug-protein adduct formation and the possibility that covalent adduct formation might occur via alternative pathways to catechol formation. Recombinant P450 3A4 catalyzed adduct formation, and this correlated with the level of uncoupling in the P450 incubation, consistent with a role of reactive oxygen species in potentiating adduct formation after enzymatic formation of the catechol metabolite. Whereas P450s 1A1, 2D6, and 3A5 generated catechol metabolite, no covalent adduct formation was observed with these forms. By contrast, P450 2B6, 2C19, and rat liver microsomes catalyzed drug-protein adduct formation but not catechol formation. Drug protein adducts formed specifically with P450 3A4 in incubations using membranes isolated from bacteria expressing P450 3A4 and reductase, as well as in reconstitutions of purified 3A4, suggesting that the electrophilic species reacted preferentially with the P450 enzymes concerned.     

Mechanism-based inactivation of cytochrome P450s 1A2 and 3A4 by dihydralazine in human liver microsomes.

Dihydralazine is known to induce immunoallergic hepatitis. Since anti-liver microsome (anti-LM) autoantibodies found in the serum of the patients react with P450 1A2, it is suggested that dihydralazine is biotransformed into a reactive metabolite, which covalently binds to cytochrome P450 1A2 and triggers an immunological response as a neoantigen. We investigated inactivation of P450 enzymes, including P450 1A2, during the metabolism of dihydralazine to evaluate the selectivity of P450 1A2 as a catalyst and a target of dihydralazine. Human liver microsomes or microsomes from lymphoblastoid cells expressing P450 enzymes were preincubated with dihydralazine in the presence of NADPH, followed by an assay of several monooxygenase activities. Preincubation of human liver microsomes with dihydralazine in the presence of NADPH resulted in decreases in phenacetin O-deethylase activity (an indicator of P450 1A2 activity) and testosterone 6beta-hydroxylase activity (P450 3A4), but not in diclofenac 4'-hydroxylase activity (P450 2C9), an indication of inactivation of P450s 1A2 and 3A4 during the dihydralazine metabolism. The inactivation of both of the P450s followed pseudo-first-order kinetics and was saturable with increasing dihydralazine concentrations. Similar time-dependent decreases in the activities were obtained in the case for use in microsomes expressing P450 1A2 and P450 3A4 instead of the human liver microsomes. The data presented here demonstrated that dihydralazine was metabolically activated not only by P450 1A2 but also by P450 3A4, and the chemically reactive metabolite bound to and inactivated the enzyme themselves, suggesting that dihydralazine is a mechanism-based inactivator of P450s 1A2 and 3A4. The data support the postulated covalent binding of a reactive metabolite of dihydralazine to P450 1A2 as a step in the formation of anti-LM antibodies in dihydralazine hepatitis, but it is not the unique factor for determining the specificity of the autoantibodies.     

Coumarin metabolism by rat esophageal microsomes and cytochrome P450 2A3

The rat esophagus is strikingly sensitive to tumor induction by nitrosamines, and it has been hypothesized that this tissue contains cytochrome P450 enzymes (P450s) which catalyze the metabolic activation of these carcinogens. The metabolic capacity of the esophagus is not well characterized. In the study described here, the products of 14C-coumarin metabolism by rat esophageal microsomes were identified and quantified. Metabolite characterization was by LC/MS/MS and GC/MS and comparison to standards, quantification was by radioflow HPLC. The coumarin metabolites formed by rat esophageal microsomes were compared to those formed by P450 2A3. The major metabolites formed by esophageal microsomes were 8-hydroxycoumarin, o-hydroxyphenylacetaldehyde (o-HPA), and o-hydroxyphenylacetic acid (o-HPAA). A smaller amount of 5-hydroxycoumarin, about one-third the 8-hydroxycoumarin, was also formed. o-HPA and o-HPAA are products of coumarin 3,4-epoxidation. The relative rates of coumarin 8-hydroxylation and 3,4-epoxidation were similar. Coumarin 8-hydroxylation has not previously been reported as a major pathway in any tissue, and no P450s have yet been reported to catalyze this reaction. P450 2A3 catalyzed both the 7-hydroxylation and 3,4-epoxidation of coumarin. P450 2A3 was previously characterized as a coumarin 7-hydroxylase, however, in this study, we report that it catalyzes the formation of o-HPA more efficiently. The Km and Vmax were 1.3 +/- 0.35 microM and 0.65 +/- 0.06 nmol/min/nmol P450 for coumarin 7-hydroxylation and 1.4 +/- 0.58 microM and 3.1 +/- 0.46 nmol/min/nmol P450 for o-HPA formation.     

Bioactivation and toxicity in vitro of HCFC-123 and HCFC-141b: role of cytochrome P450.

The bioactivation and cytotoxicity in vitro of 1,1-dichloro-2,2,2-trifluoroethane (HCFC-123) and 1,1-dichloro-1-fluoroethane (HCFC-141b), two replacements for some ozone-depleting chlorofluorocarbons (CFC), were investigated in rat liver microsomes and isolated rat hepatocytes. Both compounds were activated by cytochrome P450 to reactive metabolites, as indicated by: (i) the depletion of exogenous and cellular glutathione, (ii) the increased LDH release from hepatocytes, (iii) the loss of microsomal P450 content and activities, and (iv) the formation of free radical species observed in the presence of the two compounds. Moreover, the formation of two stable metabolites and an increased production of conjugated dienes, a marker of lipid peroxidation, were observed for both HCFC-123 and HCFC-141b. The biotransformation of both compounds by pyridine- and phenobarbital-induced rat liver microsomes and the inhibition of LDH release by 4-methylpyrazole and troleandomycin indicate that P450 2E1, 2B and, possibly, also 3A are the isoforms involved in the bioactivation and toxicity of HCFC-123 and HCFC-141b in the rat.