Stereoselective metabolism of the optical isomers of trans-1,2-dihydroxy-1,2-dihydrophenanthrene to bay-region diol epoxides by rat liver microsomes

Enantiomerically pure isomers of trans-1,2-dihydroxy-1,2-dihydrophenanthrene have been obtained by chromatographic separation of their diastereomeric bis esters with (?)-α-methoxy-α-trifluoromethylphenylacetic acid. Liver microsomes from control rats, as well as rats treated with phenobarbital or 3-methylcholanthrene, metabolize these dihydrodiols to a pair of diastereomerically related bay-region 1,2-diol-3,4-epoxides in which the benzylic hydroxyl group and the epoxide oxygen are either cis (isomer-1) or trans (isomer-2) to each other. In general, diol epoxide-1 was the major metabolite of the (+)-(1S,2S)-dihydrodiol, whereas diol epoxide-2 was the major metabolite of the (?)-(1R-2R)-dihydrodiol. The extent of this stereoselectivity is dependent on the source of the microsomes and is greatest for liver microsomes from 3-methylcholanthrene-treated rats; the ratio of diol epoxide-1 relative to diol epoxide-2 was 5.6 : 1 with the (+)-enantiomer as substrate and 1 : 5.5 with the (?)-enantiomer as substrate. For a given microsomal preparation, rates of metabolism were independent of the enantiomer composition of the substrate. Relative to microsomes from control animals, treatment of rats with 3-methylcholanthrene enhanced rates of metabolism by about 40%, whereas treatment with phenobarbital decreased rates to a similar extent when the amounts of metabolites formed per nanomole of cytochrome P?450 were compared. The failure of treatment by 3-methylcholanthrene to enhance markedly the rate of metabolism of a polycyclic aromatic hydrocarbon substrate is unusual.     

Stereoselective metabolism of the (+)-(S,S)- and (-)-(R,R)-enantiomers of trans-3,4-dihydroxy-3,4-dihydrobenzo[c]-phenanthrene by rat and mouse liver microsomes and by a purified and reconstituted cytochrome P-450 system

Metabolism of (+)-, (-)-, and (+/-)-trans-3,4-dihydroxy-3, 4-dihydrobenzo[c]phenanthrenes by liver microsomes from rats and mice and by a purified monooxygenase system reconstituted with cytochrome P-450c has been examined. Bay-region 3,4-diol 1,2-epoxides are minor metabolites of both enantiomers of the 3,4-dihydrodiol with liver microsomes from 3-methylcholanthrene-treated rats or with the reconstituted system (less than 10% of total metabolites). Microsomes from control and phenobarbital-treated rats and from control mice form higher percentages of these diol epoxides (13-36% of total metabolites). Microsomes from 3-methylcholanthrene-treated rats and cytochrome P-450c in the reconstituted system form exclusively the diol expoxide-1 diastereomer, in which the benzylic hydroxyl group and oxirane oxygen are cis to each other, from the (+)-(3S,4S)-dihydrodiol. The same enzymes selectively form the diol expoxide-2 diastereomer, with its oxirane oxygen and benzylic hydroxyl groups trans to each other, from the (-)-(3R,4R)-dihydrodiol (77% of the total diol epoxides). Liver microsomes from control rats show similar stereoselectivity whereas liver microsomes from phenobarbital-treated rats and from control mice are less stereoselective. Three bis-dihydrodiols and three phenolic dihydrodiols are also formed from the enantiomeric 3,4-dihydrodiols of benzo[c]phenanthrene. A single diastereomer of one of these bis-dihydrodiols with the newly introduced dihydrodiol group at the 7,8-position accounts for 79-88% of the total metabolites of the (-)-(3R,4R)-dihydrodiol formed by liver microsomes from 3-methylcholanthrene-treated rats or by the reconstituted system containing epoxide hydrolase. In contrast, the (+)-(3S,4S)-dihydrodiol is metabolized to two diastereomers of this bis-dihydrodiol, a third bis-dihydrodiol, and two phenolic dihydrodiols.     

Dealkylation of 7-methoxycoumarin as assay for measuring constitutive and phenobarbital-inducible cytochrome P450s

Six alkyl ethers of 7-hydroxycoumarin, ranging from methoxy- to hexoxycoumarin, were studied for their NADPH-dependent metabolism by liver microsomes of male rats treated with phenobarbital (PB) or 3-methyl-cholanthrene (MC). The six alkyl ethers were metabolized by both types of microsomes, forming 7-hydroxycoumarin as the major product. Among the test compounds, 7-methoxycoumarin was unusual in that its dealkylation was inducible only by PB and not by MC. PB increased 7-methoxycoumarin-O-demethylase (MOCD) activity about four- to eightfold. Metyrapone strongly inhibited MOCD in PB-treated microsomes but not in MC-treated microsomes. Similarly, monoclonal antibodies directed toward PB-induced cytochrome P450s selectively suppressed MOCD in PB-treated microsomes. MOCD activity was observed in preparations of SD1 cells containing only cytochrome P450IIB1, while it was not found in preparations of XEM1 cells containing only cytochrome P450IA1. Demethylation of 7-methoxycoumarin was also mediated by the constitutive cytochrome P450 form(s) of liver, lung, small intestine, and kidney (in decreasing order). PB increased MOCD activity of small intestine by 40% but was without effect on the dealkylation activity of lung and kidney. MOCD activity was also detectable in differentiated rat hepatoma lines H4IIEC3 and 2sFou. The studies indicate that dealkylation of 7-methoxycoumarin is a highly sensitive, simple, and practical assay for estimating constitutive and PB-inducible cytochrome P450-dependent monooxygenase activities.     

The proximate carcinogen trans-3,4-dihydroxy-3,4-dihydro-dibenz[c,h]acridine is oxidized stereoselectively and regioselectively by cytochrome 1A1, epoxide hydrolase and hepatic microsomes from 3-methylcholanthrene-treated rats.

Metabolism of the proximate carcinogen trans-3,4-dihydroxy-3,4-dihydrodibenz[c,h]acridine has been examined with rat liver enzymes. The dihydrodiol is metabolized at a rate of 2.4 nmol/nmol of cytochrome P450 1A1/min with microsomes from 3-methylcholanthrene-treated rats, a rate more than 10-fold higher than that observed with microsomes from control or phenobarbital-treated rats. Major metabolises consisted of a diastereomeric pair of bis-dihydrodiols (68-83%), where the new dihydrodiol group has been introduced at the 8,9-position, tetraols derived from bay region 3,4-diol-1,2-epoxides (15-23%), and a small amount of a phenolic dihydrodiol(s) where the new hydroxy group is at the 8,9-position of the substrate. A highly purified monooxygenase system reconstituted with cytochrome P450 1A1 and epoxide hydrolase (17 nmol of metabolites/nmol of cytochrome P450 1A1/min) gave a metabolite profile very similar to that observed with liver microsomes from 3-methylcholanthrene-treated rats. Study of the stereoselectivity of these microsomes established that the (+)-(3S,4S)-dihydrodiol gave mainly the diol epoxide-1 diastereomer, in which the benzylic 4-hydroxyl group and epoxide oxygen are cis. The (-)-(3R,4R)-dihydrodiol gave mainly diol epoxide-2 where these same groups are trans. The major enantiomers of the diastereomeric bis-dihydrodiols are shown to have the same absolute configuration at the 8,9-position. Correlations of circular dichroism spectra suggest this configuration to be (8R,9R). The (8R,9S)-oxide may be their common precursor.     

Metabolism of (−)-trans-(3R,4R)-dihydroxy-3,4-dihydrochrysene to diol epoxides by liver microsomes

Metabolism of biosynthetic (?)-trans-(3R,4R)-dihydroxy-3,4-dihydrochrysene by liver microsomes from control, phenobarbital-treated and 3-methylcholanthrene-treated rats was investigated. Although previous studies of the metabolism of related benzo[a]pyrene and benzo[e]pyrene dihydrodiols which also prefer the diaxial conformation had indicated that diol epoxides were minor metabolites, the diastereomeric chrysene 3,4-diol-1,2-epoxides-$\text{1}$ and $\text{?2}$ were major metabolites (66–90%). All three types of microsomes metabolized the chrysene 3,4-dihydrodiol at low but essentially similar rates (0.5–0.7 nmol substrate/nmol cytochrome P-450/min).     

Effects of a 6-fluoro substituent on the metabolism of benzo(a)pyrene 7,8-dihydrodiol to bay-region diol epoxides by rat liver enzymes

Metabolism of trans-7,8-dihydroxy-7,8-dihydro-6-fluorobenzo(a)pyrene by liver microsomes from 3-methylcholanthrene-treated rats and by a highly purified monooxygenase system, reconstituted with cytochrome P-450c, has been examined. Although both the fluorinated and unfluorinated 7,8-dihydrodiol formed from benzo(a)pyrene by liver microsomes share (R,R)-absolute configuration, the fluorinated dihydrodiol prefers the conformation in which the hydroxyl groups are pseudodiaxial due to the proximate fluorine. The fluorinated 4,5- and 9,10-dihydrodiols are also greater than 97% the (R,R)-enantiomers. For benzo(a)pyrene, metabolism of the (7R,8R)-dihydrodiol to a bay-region 7,8-diol-9,10-epoxide in which the benzylic hydroxyl group and epoxide oxygen are trans constitutes the only known pathway to an ultimate carcinogen. With the microsomal and the purified monooxygenase system, this pathway accounts for 76-82% of the total metabolites from the 7,8-dihydrodiol. In contrast, only 32-49% of the corresponding diol epoxide is obtained from the fluorinated dihydrodiol and this fluorinated diol epoxide has altered conformation in that its hydroxyl groups prefer to be pseudodiaxial. Much smaller amounts of the diastereomeric 7,8-diol-9,10-epoxides in which the benzylic hydroxyl groups and the epoxide oxygen are cis are formed from both dihydrodiols. As the fluorinated diol epoxides are weaker mutagens toward bacteria and mammalian cells relative to the unfluorinated diol epoxides, conformation appears to be an important determinant in modulating the biological activity of diol epoxides. One of the more interesting metabolites of 6-fluorinated 7,8-dihydrodiol was a relatively stable arene oxide, probably the 4,5-oxide, which is resistant to the action of epoxide hydrolase.     

Metabolism of benzo[c]phenanthrene by rat liver microsomes and by a purified monooxygenase system reconstituted with different isozymes of cytochrome P-450

Metabolism of the environmental pollutant and weak carcinogen benzo[c]-phenanthrene (B[c]Ph) by rat liver microsomes and by a purified and reconstituted cytochrome P-450 system is examined. B[c]Ph proved to be one of the best polycyclic aromatic hydrocarbon substrates for rat liver microsomes. It is metabolized by microsomes from control rats and by rats treated with phenobarbital or 3-methylcholanthrene at 3.9, 4.2 and 7.8 nmol/nmol cytochrome P-450/min, respectively. Principal metabolites are dihydrodiols along with small amounts (less than 10%) of phenols. The K-region 5,6-dihydrodiol is the major metabolite and accounts for 77-89% of the total metabolites. The 3,4-dihydrodiol with a bay-region 1,2-double bond is formed in much smaller amounts and accounts for only 6-17% of the total metabolites, the highest percentage being formed by microsomes from control rats. Highly purified monooxygenase systems reconstituted with cytochrome P-450a, P-450b and P-450c and epoxide hydrolase form predominantly the 5,6-dihydrodiol (95-97% of total metabolites) and only a small percentage of the 3,4-dihydrodiol (3-5% of total metabolites). The 3,4-dihydrodiol is formed with higher enantiomeric purity by microsomes from 3-methylcholanthrene-treated rats (88%) than by microsomes from control rats (78%) or phenobarbital-treated rats (60%). In each case the (3R,4R)-enantiomer predominates. B[c]Ph 5,6-dihydrodiol formed by all three microsomal preparations is nearly racemic.     

Differential stereoselectivity on metabolism of triphenylene by cytochromes P-450 in liver microsomes from 3-methylcholanthrene- and phenobarbital-treated rats

Metabolism of triphenylene by liver microsomes from control, phenobarbital(PB)-treated rats and 3-methylcholanthrene(MC)-treated rats as well as by a purified system reconstituted with cytochrome P-450c in the absence or presence of purified microsomal epoxide hydrolase was examined. Control microsomes metabolized triphenylene at a rate of 1.2 nmol/nmol of cytochrome P-450/min. Treatment of rats with PB or MC resulted in a 40% reduction and a 3-fold enhancement in the rate of metabolism, respectively. Metabolites consisted of the trans-1,2-dihydrodiol as well as 1-hydroxytriphenylene, and to a lesser extent 2-hydroxytriphenylene. The (-)-1R,2R-enantiomer of the dihydrodiol predominated (70 to 92%) under all incubation conditions. Incubation of racemic triphenylene 1,2-oxide with microsomal epoxide hydrolase produced dihydrodiol which was highly enriched (80%) in the (-)-1R,2R-enantiomer. Experiments with 18O-enriched water showed that attack of water was exclusively at the allylic 2-position of the arene oxide, indicating that the 1R,2S-enantiomer of the oxide was preferentially hydrated by epoxide hydrolase. Thiol trapping experiments indicated that liver microsomes from MC-treated rats produced almost exclusively (greater than 90%) the 1R,2S-enantiomer of triphenylene 1,2-oxide whereas liver microsomes from PB-treated rats formed racemic oxide. The optically active oxide has a half-life for racemization of only approximately 20 s under the incubation conditions. This study may represent the first attempt to address stereochemical consequences of a rapidly racemizing intermediary metabolite.     

Characterization of a phenobarbital-inducible dog liver cytochrome P450 structurally related to rat and human enzymes of the P450IIIA (steroid-inducible) gene subfamily

A cytochrome P450 called PBD-1 isolated from liver microsomes of an adult male Beagle dog treated with phenobarbital (PB) is structurally and functionally similar to members of the P450IIIA gene subfamily in rat and human liver microsomes. The sequence of the first 28 amino-terminal residues of PBD-1 is identical in 15 and 20 positions, respectively, to the P450IIIA forms P450p from rat and P450NF (and HLp) from human. Upon immunoblot analysis, anti-PBD-1 IgG recognizes PCNa (P450p) and PCNb (PB/PCN-E) from rat, P450NF from human, and two proteins in liver microsomes from both untreated and PB-treated dogs. Similarly, anti-PCNb IgG cross-reacts with PBD-1 and with at least one protein in microsomes from untreated dogs and two proteins in microsomes from PB-treated dogs. P450IIIA-form marker steroid 6 beta-hydroxylase activities increase 2.5-fold upon PB-treatment of dogs and are selectively inhibited by anti-PBD-1 IgG. NADPH-dependent triacetyloleandomycin (TAO) complex formation and erythromycin demethylase, also marker activities for P450IIIA forms from rats and humans, increase 4- and 5-fold in dog liver microsomes upon PB treatment, whereas immunochemically reactive PBD-1 is induced 3-fold. In microsomes from PB-treated dogs, 5 mg anti-PBD-1 IgG/nmol P450 inhibits greater than 75 and 50% of TAO complex formation and erythromycin demethylase activity, respectively. TAO complex formation is not inhibited by chloramphenicol, a selective inhibitor of the major PB-inducible dog liver cytochrome P450, PBD-2. These data suggest that PBD-1 or another immunochemically related form is responsible for a major portion of macrolide antibiotic metabolism by microsomes from PB-treated dogs and for steroid 6 beta-hydroxylation by microsomes from both untreated and PB-treated dogs. Major species differences were noted, however, in the apparent Km for 6 beta-hydroxylation of androstenedione by liver microsomes from untreated rats (24 microM), humans (380 microM), and untreated dogs (4700 microM).     

Metabolism of halazepam by rat liver microsomes: stereoselective formation and N-dealkylation of 3-hydroxyhalazepam

Metabolism of halazepam [7-chloro-1,3-dihydro-5-phenyl-1-(2,2,2-trifluoroethyl)-2H-1,4-benzod iazepin- 2-one, HZ] was studied by incubation with liver microsomes prepared from untreated, phenobarbital (PB)-treated, and 3-methylcholanthrene (3MC)-treated male Sprague-Dawley rats. Metabolites of HZ were separated by normal-phase HPLC. Relative rates of HZ metabolism by liver microsomes prepared from untreated and treated rats were PB-treated much greater than untreated greater than 3MC-treated at low concentration of microsomal enzymes (0.25 mg protein per ml of incubation mixture) and PB-treated much greater than 3MC-treated approximately untreated at high concentration of microsomal enzymes (2 mg protein per ml of incubation mixture). The relative amounts of major metabolites were found to be 3-hydroxy-HZ (3-OH-HZ) greater than N-desalkylhalazepam (NDZ, also known as N-desmethyldiazepam and nordiazepam) much greater than oxazepam (OX) for all three rat liver microsomal preparations and the distribution of metabolites was independent of microsomal enzyme concentrations. Enantiomers of 3-OH-HZ were resolved by HPLC on a Chiralcel OC column (cellulose trisphenylcarbamate coated on silica gel, particle size 10 microns). 3-OH-HZ enantiomeres have racemization half-lives of approximately 150 min in pH 4, 7.5, and 10 aqueous solutions. 3-OH-HZ formed in the metabolism of HZ by liver microsomes prepared from untreated and treated rats were found to have 3R/3S enantiomer ratios of 37/63 (untreated), 55/45 (PB-treated), and 36/64 (3MC-treated), respectively. N-dealkylation of 3-OH-HZ by liver microsomes from PB-treated rats was substrate enantioselective; the 3R-enantiomer was N-dealkylated faster than 3S-enantiomer.(ABSTRACT TRUNCATED AT 250 WORDS)     

Catalysis of the oxidation of steroid and stilbene estrogens to estrogen quinone metabolites by the beta-naphthoflavone-inducible cytochrome P450 IA family.

Diethylstilbestrol (DES) or catecholestrogens are metabolized by microsomal enzymes to quinones, DES Q or catecholestrogen quinones, respectively, which have been shown to bind covalently to DNA and to undergo redox cycling. The isoforms of cytochrome P450 catalyzing this oxidation of estrogens to genotoxic intermediates were not known and have been identified in this study by (a) using microsomes of rats treated with various inducers of cytochrome P450; (b) using purified cytochrome P450 isoforms; and (c) examining the peroxide cofactor concentrations necessary for this oxidation by microsomes or pure isoenzymes. The highest rate of oxidation of DES to DES Q was obtained using beta-naphthoflavone-induced microsomes (14.0 nmol DES Q/mg protein/min) or cytochrome P450 IA1 (6.4 pmol DES Q/min/pmol P450). Isosafrole-induced microsomes or cytochrome P450 IA2 oxidized DES to quinone at one-third or one-fifth of that rate, respectively. Low or negligible rates of oxidation were measured when oxidations were catalyzed by microsomal rat liver enzymes induced by phenobarbital, ethanol, or pregnenolone-16 alpha-carbonitrile or by pure cytochromes P450 IIB1, IIB4, IIC3, IIC6, IIE1, IIE2, IIG1, or IIIA6. Cytochrome P450 IA1 also catalyzed the oxidation of 2- or 4-hydroxyestradiol to their corresponding quinones. The beta-naphthoflavone-induced microsomes and cytochrome P450 IA1 had the highest "affinity" for cumene hydroperoxide cofactor (Km = 77 microM). Cofactor concentrations above 250 microM resulted in decreased rates of oxidation. The other cytochrome P450 isoforms required much higher cofactor concentrations and were not inactivated at high cofactor concentrations. The data demonstrate that beta-naphthoflavone-inducible cytochrome P450 IA family enzymes catalyze most efficiently the oxidation of estrogenic hydroquinones to corresponding quinones. This oxidation may represent a detoxification pathway to keep organic hydroperoxides at minimal concentrations. The resulting quinone metabolites may be detoxified by other pathways. However, in cells with decreased detoxifying enzyme activities, quinones metabolites may accumulate and initiate carcinogenesis or cell death by covalent arylation of DNA or proteins.     

Oxidative metabolism of the carcinogen 6-fluorobenzo[c]phenanthrene. Effect of a K-region fluoro substituent on the regioselectivity of cytochromes P-450 in liver microsomes from control and induced rats

Oxidative metabolism of the carcinogen 6-fluorobenzo[c]phenanthrene (6-FB[c]Ph) was compared with that of benzo[c]phenanthrene (B[c]Ph) to elucidate the enhancement of carcinogenicity of B[c]Ph by the 6-fluoro substituent. Liver microsomes from untreated (control), phenobarbital-treated, and 3-methylcholanthrene-treated rats metabolized 6-FB[c]Ph at rates of 3.5, 1.5, and 7.7 nmol of products/nmol of cytochrome P-450/min, respectively. The rates of metabolism of B[c]Ph by the same microsomes were 2.9, 1.6, and 5.5 nmol of products/nmol of cytochrome P-450/min, respectively. Whereas the K-region 5,6-dihydrodiol was the major metabolite of B[c]Ph, the major metabolite of 6-FB[c]Ph was the K-region 7,8-oxide, which underwent slow rearrangement to an oxepin. Thus, the 6-fluoro substituent blocks oxidation at the 5,6-double bond and inhibits hydration of the K-region 7,8-oxide by epoxide hydrolase. Substitution with fluorine at C-6 caused an almost 2.5-fold increase in the percentages of the putative proximate carcinogens, i.e. benzo-ring dihydrodiols with bay-region double bonds, when liver microsomes from 3-methylcholanthrene-treated rats were used. Little or no increase was observed in their formation by liver microsomes from control or phenobarbital-treated rats. Interestingly, liver microsomes from control rats formed almost 3-fold as much 3,4-dihydrodiol as isosteric 9,10-dihydrodiol. The R,R-enantiomers of the 3,4- and 9,10-dihydrodiols and the S,S-enantiomer of the 7,8-dihydrodiol were predominantly formed by all three microsomal preparations.     

Monoclonal antibody-directed characterization of rat hepatic P450 catalyzing the omega-1 and omega-2 hydroxylation of prostaglandins

Previous studies have demonstrated that methylcholanthrene (MC) treatment of rats increases 10-fold the omega-2 hydroxylation of prostaglandin E2 (PGE2) by liver microsomes (K. A. Holm, R. J. Engell, and D. Kupfer (1985) Arch. Biochem. Biophys. 237, 477-489). The current study identifies the cytochrome P450 form, which catalyzes a major portion of the omega-2 hydroxylation of prostaglandins in liver microsomes of MC-treated rats (MC-microsomes) and examines whether the same enzyme catalyzes this reaction in microsomes from untreated rats (control microsomes). Three monoclonal antibodies (MAbs), MC 1-7-1, 1-31-2, and 1-36-1, raised against the major liver P450 from MC-treated rats were used. MAb 1-7-1 binds P450(57K) and P450(56K) (P450c and P450d, respectively); MAb 1-31-2 binds primarily P450(57K); and 1-36-1 binds solely P450(57k). MAb 1-7-1 inhibited omega-2 and omega-1 PGE2 hydroxylations in MC-microsomes by 70 and 45%, respectively. By contrast, MAb 1-31-2 and 1-36-1 were not inhibitory. MAb 1-7-1 did not inhibit PGE2 omega-2 hydroxylation in control or in microsomes from phenobarbital-treated rats (PB-microsomes). Since MAb 1-7-1 binds to both P450c and P450d, and 1-31-2 and 1-36-1 bind to P450c but are not inhibitory, these findings did not permit the determination of whether in MC microsomes a single isozyme (P450c or P450d) or both isozymes catalyze the omega-2 hydroxylation. This question was partially resolved by the observation that immunoaffinity-isolated P450c, supplemented with purified NADPH-P450 reductase, catalyzes effectively the omega-2 hydroxylation and to a lesser extent the omega-1 hydroxylation. There was no activity in the absence of reductase. The P450 antibody complex exhibits characteristics similar to those of the omega-2 hydroxylating activity in intact MC-microsomes supported by H2O2, by demonstrating a much higher activity when H2O2 is used instead of reductase and NADPH. Furthermore, a reconstituted monooxygenase composed of rat liver reductase and P450c, purified by conventional means, hydroxylated PGE2 at the omega-2 and omega-1 sites at a ratio of 2.8, similar to that obtained with the P450-antibody complex. These findings demonstrate that a major portion of the omega-2 hydroxylation of PGs in MC-microsomes is catalyzed by P450c; however, the possibility that some omega-2 hydroxylating activity is due to P450d was not ruled out.(ABSTRACT TRUNCATED AT 400 WORDS)     

Uroporphyrinogen oxidation catalyzed by reconstituted cytochrome P450IA2.

Previous work suggested that the oxidation of uroporphyrinogen to uroporphyrin is catalyzed by cytochrome P450IA2. Here we determined whether purified reconstituted mouse P450IA1 and IA2 oxidize uroporphyrinogen. Cytochromes P450IA1 and IA2 were purified from hepatic microsomes from 3-methylcholanthrene (MC)-treated C57BL/6 mice, using a combination of affinity chromatography and high performance liquid chromatography. Reconstituted P450IA1 was more active than P450IA2 in catalyzing ethoxyresorufin-O-deethylase (EROD) activity, whereas P450IA2 was more active than P450IA1 in catalyzing uroporphyrinogen oxidation (UROX). Both reactions required NADPH, NADPH-cytochrome P450 reductase, and either P450IA1 or IA2. Ketoconazole competitively inhibited both EROD and UROX activities, in microsomes from MC-treated mice. Ketoconazole also inhibited UROX catalyzed by reconstituted P450IA2. In contrast, ketoconazole did not inhibit UROX catalyzed by xanthine oxidase in the presence of iron-EDTA. Superoxide dismutase, catalase, and mannitol inhibited UROX catalyzed by xanthine oxidase/iron-EDTA, but did not affect UROX catalyzed by either microsomes or reconstituted P450IA2. These results suggest that UROX catalyzed by P450IA2 in microsomes and reconstituted systems does not involve free reactive oxygen species. Two known substrates of cytochrome P450IA2, 2-amino-3,4-dimethylimidazole[4,5-f]quinoline and phenacetin, were shown to inhibit the microsomal UROX reaction, suggesting that uroporphyrinogen binds to a substrate-binding site on the cytochrome P450.     

Functional characteristics of cytochromes P-4501A1 and P-4501A2 in rodent liver

Antibodies to mouse liver cytochrome P3-450 (anti-P3-450) and antibodies to rat liver cytochrome P-450d (anti-P-450d-c) inhibit the 0-deethylation of 7-ethoxyresorufin (ER) in liver microsomes of benz(a)pyrene-induced (BP) mice but do not inhibit the 0-deethylase activity in liver microsomes of BP-induced rats. Anti-P3-450 and anti-P-450c inhibit BP-hydroxylation in BP-induced mouse liver microsomes by 20%, but they do not inhibit this reaction at all in BP-induced rat liver microsomes. In a reconstituted monooxygenase system isolated cytochrome P3-450 metabolized 7-ER and BP. In contrast, its homologue, cytochrome P-450d, did not metabolize these substrates. The fraction containing cytochrome P1-450 metabolized 7-ER at a low rate and BP at a rate of 3.6 nmol product/min/nmol cytochrome. Western blot analysis with anti-P-450c + d revealed two bands in SDS-PAGE gels containing BP-induced mouse liver microsomes. The interaction of mouse liver BP-microsomes with anti-P3-450 and anti-P-450d-c was accompanied by the appearance of a single band (cytochrome P3-450).     

In vitro metabolism of FK-506 in rat, rabbit, and human liver microsomes: identification of a major metabolite and of cytochrome P450 3A as the major enzymes responsible for its metabolism.

The metabolism of the immunosuppressant FK-506 was shown to be catalyzed primarily by cytochrome P450 isozymes of the P450 3A subfamily. Antibodies against rat P450 3A inhibited FK-506 metabolism by 82% in rat liver microsomes and by 35-56% in liver microsomes from humans, dexamethasone-induced rats, and erythromycin-induced rabbits. Poor species cross-reactivity of the antibodies, metabolic switching, and/or some metabolism by P450 isozymes other than P450 3A may be responsible for the incomplete inhibition observed. Besides anti-rat P450 3A, antibodies against rat P450 1A also appeared to have some inhibitory effect implicating these particular cytochrome P450 isozymes as having a minor role in FK-506 metabolism. The formation of 13-desmethyl FK-506, identified here as a major metabolite of FK-506 in all types of microsomes examined, was inhibited completely by anti-P450 3A in liver microsomes from dexamethasone-induced rats and erythromycin-induced rabbits but only partially in human and control rat liver microsomes.     

Hepatic microsomal mixed function oxygenase: enzyme multiplicity for the metabolism of carcinogens to DNA-binding metabolites

Microsome-mediated metabolic activation of aflatoxin B₁ (AFB₁) and benzo[a]-pyrene (BP), as determined by the $\text{in vitro}$ formation of DNA binding metabolites, was studied, using hepatic microsomes from untreated, phenobarbital (PB)-treated and 3-methylcholanthrene (MC)-treated male rats. Contrasting results were obtained for the two substrates: in the case of AFB₁, microsomes from PB-treated rats were twice as active as microsomes from untreated and MC-treated rats, whereas, in the case of BP, microsomes from MC-treated rats were several fold more active than microsomes from untreated and PB-treated rats. These data strongly suggests enzyme multiplicity of microsomal mixed function oxygenase for the activation of carcinogens, especially AFB₁ and BP whose reactive metabolites are believed to be epoxides.     

CYP3A induction aggravates endotoxemic liver injury via reactive oxygen species in male rats

We carried out this experiment to evaluate the relationship between isoforms of cytochrome P450 (P450) and liver injury in lipopolysaccharide (LPS)-induced endotoxemic rats. Male rats were intraperitoneally administered phenobarbital (PB), a P450 inducer, for 3 days, and 1 day later, they were intravenously given LPS. PB significantly increased P450 levels (200% of control levels) and the activities (300-400% of control) of the specific isoforms (CYP), CYP3A2 and CYP2B1, in male rats. Plasma AST and ALT increased slightly more in PB-treated rats than in PB-nontreated (control) rats with LPS treatment. Furthermore, either troleandomycin or ketoconazole, specific CYP3A inhibitors, significantly inhibited LPS-induced liver injury in control and PB-treated male rats. To evaluate the oxidative stress in LPS-treated rats, in situ superoxide radical detection using dihydroethidium (DHE), hydroxy-2-nonenal (HNE)-modified proteins in liver microsomes and 8-hydroxydeoxyguanosine (8-OHdG) in liver nuclei were measured in control and PB-treated rats. DHE signal intensity, levels of HNE-modified proteins, and 8-OHdG increased significantly in PB-treated rats. LPS further increased DHE intensity, HNE-modified proteins, and 8-OHdG levels in normal and PB-treated groups. CYP3A inhibitors also inhibited the increases in these items. Our results indicate that the induction or preservation of CYP isoforms further promotes LPS-induced liver injury through mechanisms related to oxidative stress. In particular, CYP3A2 of P450 isoforms made an important contribution to this LPS-induced liver injury.     

Identification of cytochrome P450a (P450IIA1) as the principal testosterone 7 alpha-hydroxylase in rat liver microsomes and its regulation by thyroid hormones

In the preceding paper, evidence was presented that rat liver microsomes contain two structurally related isozymes of cytochrome P450, namely cytochromes P450a and P450m, that can both catalyze the 7 alpha-hydroxylation of testosterone. The aim of the present study was to determine the extent to which these two P450 isozymes are responsible for the 7 alpha-hydroxylation of testosterone catalyzed by rat liver microsomes. Four monoclonal antibodies against cytochrome P450a, designated A2, A4, A5, and A7, were prepared in BALB/c mice. Monoclonal antibodies A2 (an IgM), A4 (an IgG2b), and A5 (an IgG1) were determined to be distinct immunoglobulins, whereas A7 could not be distinguished from A5. All of the antibodies were highly specific for cytochrome P450a; none cross-reacted with cytochrome P450m or with 10 other P450 isozymes purified from rat liver microsomes. Competition experiments between unlabeled and horseradish peroxidase-conjugated antibodies revealed that each of the monoclonal antibodies recognized the same epitope on cytochrome P450a. None of the monoclonal antibodies bound to denatured cytochrome P450a, suggesting that they each bound to a spatial epitope. A monospecific, polyclonal antibody against cytochrome P450a was also prepared, as described in the preceding paper. The levels of cytochrome P450a in liver microsomes were determined by single radial immunodiffusion, Western immunoblot (with polyclonal antibody), and enzyme-linked immunosorbent assay with monoclonal antibody. The levels of cytochrome P450a declined with age in male but not female rats, and were inducible up to 10-fold by treatment of rats with various xenobiotics. The levels of cytochrome P450a (but not cytochrome P450m) were also elevated (approximately 3-fold) by thyroidectomy of mature male rats. Near normal levels of cytochrome P450a were restored by treatment of athyroid rats with triiodothyronine, whereas treatment with thyroxine was less effective in this regard. These changes in the levels of cytochrome P450a were highly correlated (r = 0.995) with changes in testosterone 7 alpha-hydroxylase activity. None of the monoclonal antibodies inhibited the catalytic activity of cytochrome P450a when reconstituted with NADPH-cytochrome P450 reductase and lipid. In contrast, the polyclonal antibody not only inhibited the catalytic activity of purified cytochrome P450a, but also completely inhibited (greater than 96%) the 7 alpha-hydroxylation of testosterone catalyzed by liver microsomes from immature and mature rats of both sexes and by liver microsomes from male rats treated with a variety of cytochrome P450 inducers.(ABSTRACT TRUNCATED AT 400 WORDS)     

Aflatoxin B1 metabolism by 3-methylcholanthrene-induced hamster hepatic cytochrome P-450s

We have studied the activation of aflatoxin B1 by hamster liver microsomes and purified hamster cytochrome P-450 isozymes using a umu mutagen test. The hamster liver microsomes or S-9 fractions were much more active than rat liver microsomes or S-9 fractions in the activation of umu gene expression by aflatoxin B1 metabolites. 3-Methyl-cholanthrene treatment increased aflatoxin B1 activation by hamster liver microsomes. Two major 3-methylcholanthrene-inducible cytochrome P-450 isozymes, P-450 MC1 (IIA) and P-450 MC4 (IA2), were purified from 3-methylcholanthrene-treated hamster liver microsomes, and the metabolism of aflatoxin B1 by these two cytochromes was studied. In the reconstituted enzyme system, both P-450 MC1 and P-450 MC4 were highly active in the activation of aflatoxin B1, and antibodies against these P-450s specifically inhibited these activities. Antibody against P-450 MC1 inhibited the activation of aflatoxin B1 by 20% in the presence of 3-methyl-cholanthrene-treated hamster liver microsomes. In contrast, antibody against P-450 MC4 stimulated the activity by 175%. These results indicated that hamster P-450 MC1 might convert aflatoxin B1 to more toxic metabolite(s), whereas P-450 MC4 might convert aflatoxin B1 to less toxic metabolite(s), than aflatoxin B1 in liver microsomes. The metabolite(s) produced by both hamster cytochrome P-450 MC1 and MC4 were genotoxic in the umu mutagen test.