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.     

Reconstitution of testosterone oxidation by purified rat cytochrome P450p (IIIA1)

Cytochrome P450p (IIIA1) has been purified from rat liver microsomes by several investigators, but in all cases the purified protein, in contrast to other P450 enzymes, has not been catalytically active when reconstituted with NADPH-cytochrome P450 reductase and dilauroylphosphatidylcholine. We now report the successful reconstitution of testosterone oxidation by cytochrome P450p, which was purified from liver microsomes from troleandomycin-treated rats. The rate of testosterone oxidation was greatest when purified cytochrome P450p (50 pmol/ml) was reconstituted with a fivefold molar excess of NADPH-cytochrome P450 reductase, an equimolar amount of cytochrome b5, 200 micrograms/ml of a chloroform/methanol extract of microsomal lipid (which could not be substituted with dilauroylphosphatidylcholine), and the nonionic detergent, Emulgen 911 (50 micrograms/ml). Testosterone oxidation by cytochrome P450p was optimal at 200 mM potassium phosphate, pH 7.25. In addition to their final concentration, the order of addition of these components was found to influence the catalytic activity of cytochrome P450p. Under these experimental conditions, purified cytochrome P450p converted testosterone to four major and four minor metabolites at an overall rate of 18 nmol/nmol P450p/min (which is comparable to the rate of testosterone oxidation catalyzed by other purified forms of rat liver cytochrome P450). The four major metabolites were 6 beta-hydroxytestosterone (51%), 2 beta-hydroxytestosterone (18%), 15 beta-hydroxytestosterone (11%) and 6-dehydrotestosterone (10%). The four minor metabolites were 18-hydroxytestosterone (3%), 1 beta-hydroxytestosterone (3%), 16 beta-hydroxytestosterone (2%), and androstenedione (2%). With the exception of 16 beta-hydroxytestosterone and androstenedione, the conversion of testosterone to each of these metabolites was inhibited greater than 85% when liver microsomes from various sources were incubated with rabbit polyclonal antibody against cytochrome P450p. This antibody, which recognized two electrophoretically distinct proteins in liver microsomes from troleandomycin-treated rats, did not inhibit testosterone oxidation by cytochromes P450a, P450b, P450h, or P450m. The catalytic turnover of microsomal cytochrome P450p was estimated from the increase in testosterone oxidation and the apparent increase in cytochrome P450 concentration following treatment of liver microsomes from troleandomycin- or erythromycin-induced rats with potassium ferricyanide (which dissociates the cytochrome P450p-inducer complex). Based on this estimate, the catalytic turnover values for purified, reconstituted cytochrome P450p were 4.2 to 4.6 times greater than the rate catalyzed by microsomal cytochrome P450p.     

Metabolism of benzo(a)pyrene,dimethylbenzanthracene and aflatoxin B1 by camel liver microsomes

The ability of camel liver microsomes to metabolise a range of common environmental carcinogens including benzo(a)pyrene, dimethylbenzanthracene and aflatoxin B1 has been investigated. The camel liver has shown the ability to metabolise benzo(a)pyrene, dimethylbenzanthracene and aflatoxin B1 to a number of metabolites. The major metabolites of benzo(a)pyrene produced by camel liver enzymes were identified as its mono-hydroxy derivatives and suggest that the metabolic detoxification pathways of carcinogen metabolism are predominant in this species. Benzo(a)pyrene metabolising activity in camel liver required NADPH and was inhibited by CO and alpha-naphthoflavone suggesting the involvement of cytochrome P450 in the metabolism of this carcinogen by camel liver. The cytochrome P450-dependent metabolism of carcinogen and other specific substrates such as ethoxyresorufin and ethoxycoumarin, by camel liver enzymes, was about 50% higher than that of rat liver enzymes. The cytochrome P450-dependent metabolism of a variety of carcinogenic and other substrates by camel liver demonstrated that there are multiple forms of cytochrome P450 enzymes involved in the metabolism of a wide array of xenobiotics and pollutants.     

An immunochemical analysis of the induction of cytochrome P-450 isoforms in the liver of fresh-water fishes by 3-methylcholanthrene, beta-naphthoflavone and aroclor 1254

The cytochrome P-450 isoforms have been studied in liver microsomes of some fish species from Lake Baikal. Using the inhibitory analysis of microsomal monooxygenase activities carried out by the specific polyclonal antibodies it has been shown that 3-methylcholanthrene, beta-naphthoflavone and arochlor 1254 induce isoforms immunologically related to cytochrome P-488c but not to the rat cytochrome P-450b in fish liver microsomes. The immunologic identity in isoforms of fish and rat cytochromes induced by methylcholanthrene has not been revealed. A possibility to use the method of the inhibitory analysis of fish microsomal activities by specific antibodies to the rat cytochrome P-450 isoforms for biomonitoring and biotesting of polycyclic hydrocarbons and polychlorinated biphenyls in aquatic systems is discussed.     

Regulation of three forms of cytochrome P-450 and epoxide hydrolase in rat liver microsomes. Effects of age, sex, and induction

A procedure for the preparation of monospecific antibody directed against rat liver microsomal cytochrome P-45-a is described. This antibody, together with monospecific antibodies to cytochromes P-450b and P-450c, has been used to show that these three forms of cytochrome P-450 are distinct and share no common antigenic determinants. These antibodies (a) give single immunoprecipitin bands with detergent-solubilized microsomes; (b) do not cross-react with the purified heterologous antigens in Ouchterlony double diffusion analyses; (c) have no effect on catalytic activity of the heterologous antigens but completely inhibit the enzymatic activity of the homologous antigens; and (d) remove only the homologous antigen from detergent-solubilized microsomes when covalently bound to a solid support. With radial immunodiffusion assay, we have quantitated these three forms of cytochrome P-450 in liver microsomes after treatment of rats with seven different inducers of cytochrome P-450. The levels of these cytochrome P-450 isozymes vary independently and are also regulated by the age and sex of the animal. The antibodies have also been used to assess the contribution of cytochromes P-450a, P-450b, and P-450c in the metabolism of xenobiotics by rat liver microsomes. A large proportion of benzo(a)pyrene metabolism and testosterone 16 alpha-hydroxylation in microsomes from untreated rats is not catalyzed by cytochromes P-450a, P-450b, and P-450c. Epoxide hydrolase, another microsomal enzyme involved in the metabolism of xenobiotics, was also quantitated by radial immunodiffusion after prior treatment of rats with microsomal enzyme inducers. The inductions of epoxide hydrolase varies independently of the induction of cytochromes P-450a, P-450b, and P-450c.     

Characterization of rat and human liver microsomal cytochrome P-450 forms involved in nifedipine oxidation, a prototype for genetic polymorphism in oxidative drug metabolism

The metabolism of the dihydropyridine calcium antagonist and vasodilator nifedipine has been reported to exhibit polymorphism among individual humans (Kleinbloesem, C. H., van Brummelen, P., Faber, H., Danhof, M., Vermeulen, N. P. E., and Breimer, D.D. (1984) Biochem. Pharmacol. 33, 3721-3724). Nifedipine oxidation has been shown to be catalyzed by cytochrome P-450 (P-450) enzymes. Reconstitution, immunoinhibition, and induction studies with rat liver indicated that the forms designated P-450UT-A and P-450PCN-E are the major contributors to microsomal nifedipine oxidation. The P-450 which oxidizes nifedipine (P-450NF) was purified to electrophoretic homogeneity from several human liver samples. Antibodies raised to P-450NF were highly specific as judged by immunoblotting analysis and inhibited greater than 90% of the nifedipine oxidase activity in human liver microsomes. A monoclonal antibody raised to the human P-450 preparation reacted with both human P-450NF and rat P-450PCN-E. Immunoblotting analysis of 39 human liver microsomal samples using anti-P-450NF antibodies revealed the same 52,000-dalton polypeptide, corresponding to P-450NF, with only one of the microsomal samples showing an additional immunoreactive protein. The level of nifedipine oxidase activity was highly correlated with the amount of P-450NF thus detected using either polyclonal (r = 0.78) or monoclonal (r = 0.65) antibodies, suggesting that the amount of the P-450NF polypeptide may be a major factor in influencing the level of catalytic activity in humans as well as rats. Cytochrome b5 enhanced the catalytic activity of reconstituted P-450NF, and anti-cytochrome b5 inhibited nifedipine oxidase activity in human liver microsomes. P-450NF also appears to be a major contributor to human liver microsomal aldrin epoxidation, d-benzphetamine N-demethylation, 17 beta-estradiol 2- and 4-hydroxylation, and testosterone 6 beta-hydroxylation, the major pathway for oxidation of this androgen in human liver microsomes.     

Rat pulmonary microsomal cytochrome P-450 enzymes involved in the activation of procarcinogens.

Rat lung microsomal cytochrome P-450 (P-450) enzymes have been characterized with regard to their catalytic specificities towards activation of several procarcinogens to genotoxic metabolites in Salmonella typhimurium TA1535/pSK1002. We first examined the roles of rat liver microsomal P-450 enzymes in the activation of benzo[a]pyrene and its 7,8-diol enantiomers to genotoxic products, and found that P-450 1A1 is a major catalyst for the activation of these potential procarcinogens in rat livers. Using lung microsomes isolated from rats treated with various P-450 inducers we obtained evidence that at least three P-450 enzymes are involved in the activation of several procarcinogens. Immunoinhibition studies support the view that benzo[a]pyrene and its 7,8-diol derivatives, other dihydrodiol derivatives of polycyclic aromatic hydrocarbons, and 3-amino-1-methyl-5H-pyrido[4,3-b]indole are activated to genotoxins mainly by rat P-450 1A1, which is inducible in rat lungs by 5,6-benzoflavone and the polychlorinated biphenyl mixture Aroclor 1254. Activation of 2-amino-3,5-dimethylimidazo[4,5-f]quinoline and 2-amino-3-methylimidazo[4,5-f]quinoline may be catalyzed by another P-450 enzyme because the activities were not induced by treatment with 5,6-benzoflavone or Aroclor 1254. The observation that both activities were inhibited by antibodies raised against P-450 1A2 and by 7,8-benzoflavone suggests a role for an enzyme of P-450 1A family, probably P-450 1A2, in rat lung microsomes. The activation of aflatoxin B1 and sterigmatocystin appears to be catalyzed by other P-450 enzyme(s) rather than the P-450 1A family as judged by the different responses of activities to the P-450 inducers and the specific antibodies in rat lung microsomes. Interestingly, lung microsomal activation of several procarcinogens was found to be suppressed in rats treated with isosafrole and pregnenolone 16 alpha-carbonitrile. Thus, the results support the roles of different P-450 enzymes in the activation of procarcinogens in rat lung microsomes.     

Catalytic properties of the human cytochrome P450 2E1 produced by cDNA expression in mammalian cells.

A full-length cDNA encoding human cytochrome P450 2E1 was expressed in mammalian cell lines using the vaccinia virus expression system. Immunoblot analysis showed that the expressed protein reacted with a polyclonal antibody against rat 2E1 and comigrated with P450 2E1 from human liver microsomes. P450 2E1 expressed in Hep G2 cells, a human cell line which contains both cytochrome b5 and NADPH:P450 oxidoreductase, was able to metabolize several known P450 2E1 substrates: N-nitrosodimethylamine (NDMA), N-nitrosomethylbenzylamine (NMBzA), p-nitrophenol, phenol, and acetaminophen. Apparent Km and Vmax values for NDMA demethylation were 22 microM and 173 pmol/min/mg microsomal protein, respectively. P450 2E1 expressed in TK-143 cells, which do not contain b5, displayed Km and Vmax values of 31 microM and 34 pmol/min/mg microsomal protein, respectively. Incorporation of purified rat liver b5 into TK-143 microsomes increased the Vmax 2.2-fold and decreased the Km to 22 microM. Addition of b5 to Hep G2 microsomes resulted in a 1.6-fold increase in Vmax, but showed no effect on the Km. P450 2E1 expressed in Hep G2 cells was shown to metabolize NMBzA with a Km of 47 microM and Vmax of 213 pmol/min/mg microsomal protein. Addition of b5 lowered the Km to 27 microM, but had no effect on Vmax. These results demonstrate conclusively that P450 2E1 is responsible for the low Km forms of NDMA demethylase and NMBzA debenzylase observed in liver microsomes and that these activities are affected by cytochrome b5.     

Purification of a new cytochrome P-450 from human liver microsomes

Using a classical methodology of purification consisting of three chromatographic steps (Octyl-Sepharose, DEAE-cellulose, CM-cellulose) we have purified a new cytochrome P-450 from human liver microsomes. It was called cytochrome P-450(9). It has been proven to be different from all precedingly purified human liver microsomal cytochrome P-450 isozymes by its immunological and electrophoretical properties. It does not cross-react with any rat liver cytochrome P-450 and anti-cytochrome P-450(9) does not recognize rat liver microsomes; thus this cytochrome P-450(9) is specific to humans. This cytochrome P-450 isozyme exists in low amounts in human liver microsomes and exhibits an important quantitative polymorphism. In reconstituted system, cytochrome P-450(9) is able to hydroxylate all substrates tested but is not specific of any; its exact role in xenobiotic metabolism in man remains to be elucidated.     

Evidence that covalent binding of metabolically activated phenol to microsomal proteins is caused by oxidised products of hydroquinone and catechol

The metabolic activation of [14C]phenol resulting in covalent binding to proteins has been studied in rat liver microsomes. The covalent binding was dependent on microsomal enzymes and NADPH and showed saturation kinetics for phenol with a Km-value of 0.04 mM. The metabolites hydroquinone and catechol were formed at rates which were 10 or 0.7 times that of the binding rate of metabolically activated phenol. The effects of cytochrome P-450 inhibitors and cytochrome P-450 inducers on the metabolism and binding of phenol to microsomal proteins, suggest that cytochrome P-450 isoenzyme(s) other than P-450 PB-B or P-450 beta NF-B catalyses the metabolic activation of phenol. Furthermore, reconstituted mixed-function oxidase systems containing cytochrome P-450 PB-B and P-450 beta NF-B were (on basis of cytochrome P-450 content) 6 and 11 times less active in catalysing the formation of hydroquinone than microsomes. The isolated metabolites hydroquinone and catechol bound more extensively to microsomal proteins than phenol and the binding of these was not stimulated by NADPH. The binding occurring during the metabolism of phenol could be predicted by the rates of formation of hydroquinone and catechol and the rates by which the isolated metabolites were bound to proteins.     

Characteristcs of microsomal enzyme controls in primary cultures of rat hepatocytes.

Cytochrome P-450, NADPH-cytochrome c reductase, biphenyl hydroxylase, and epoxide hydratase have been compared in intact rat liver and in primary hepatocyte cultures. After 10 days in culture, microsomal NADPH-cytochrome c reductase and epoxide hydratase activities declined to a third of the liver value, while cytochrome P-450 decreased to less than a tenth. Differences in the products of benzo[a]pyrene metabolism and gel electrophoresis of the microsomes indicated a change in the dominant form(s) of cytochrome P-450 in the cultured hepatocytes. Exposure of the cultured cells to phenobarbital for 5 days resulted in a threefold induction in NADPH-cytochrome c reductase and epoxide hydratase activities which was typical of liver induction of these enzymes. Exposure of the cells to 3-methylcholanthrene did not affect these activities. Cytochrome P-450 was induced over two times by phenobarbital and three to four times by 3-methylcholanthrene. The λ_max of the reduced carbon monoxide complex (450.7 nm) and analysis of microsomes by gel electrophoresis showed that the phenobarbital-induced cytochrome P-450 was different from the species induced by 3-methylcholanthrene (reduced carbon monoxide λ_max = 447.9 nm). However, metabolism of benzo[a]pyrene (specific activity and product distribution) was similar in microsomes of control and phenobarbital- and 3-methylcholan-threne-induced hepatocytes and the specific activity per nmole of cytochrome P-450 was higher than in liver microsomes. The activities for 2- and 4-hydroxylation of biphenyl were undetectable in all hepatocyte microsomes even though both activities were induced by 3-methylcholanthrene in the liver. Substrate-induced difference spectra and gel electrophoresis indicated an absence in phenobarbital-induced hepatocytes of most forms of cytochrome P-450 which were present in phenobarbital-induced rat liver microsomes. It is concluded that the control of cytochrome P-450 synthesis in these hepatocytes is considerably different from that found in whole liver, while other microsomal enzymes may be near to normal. Hormonal deficiencies in the culture medium and differential hormonal control of the various microsomal enzymes provide a likely explanation of these effects.     

Subfractionation of rat liver microsomes by immunoprecipitation and immunoadsorption methods.

Rabbit antisera were prepared against cytochrome b5 and NADPH-cytochrome c reductase [EC 1.6.2.4] purified from rat liver microsomes, and utilized in examining the distribution of these and other membrane-bound enzymes among the vesicles of rat liver microsomal preparations by immunoprecipitation and immunoadsorption methods. Smooth microsomes with an average vesicular size of 200 nm (diameter) and sonicated smooth microsomes with an average diameter of 40-60 nm were used in subfractionation experiments. Immunoprecipitation of microsomal vesicles with anti-cytochrome b5 immunoglobulin failed to show any separation of the microsomes into fractions having different enzyme compositions. Cytochrome b5 was apparently distributed among all vesicles even when sonicated microsomes were used. When the antibody against NADPH-cytochrome c reductase was used, however, immunoadsorption of microsomes on Sepharose-bound antibody produced some separation of NADPH-cytochrome c reductase and cytochrome P-450 from NADH-cytochrome b5 reductase and cytochrome b5. The separation was more pronounced when sonicated microsomes were used. These results indicate microheterogeneity of the microsomal membrane, and suggest the clustering of NADPH-cytochrome c reductase and cytochrome P-450 molecules in the membrane.     

The phenobarbital-type induction of rat liver microsomal monooxygenases by perfluorodecalin

Induction of perfluorodecalin (PFD) of the liver microsomal system of metabolism of xenobiotics has been studied and compared with the inductions by phenobarbital (PB) and 3-methylcholanthrene (MC). It has been shown that PFD increases the content of cytochrome P-450, NADPH-cytochrome c reductase activity. Like PB, PFD induces the activities of benzphetamine-N-demethylase, aldrine-epoxidase, 16 beta-androstendion-hydroxylase. Using specific antibodies against cytochromes P-450b and P-450c (which are the main isoenzymes of cytochrome P-450 in the PB- and MC-microsomes respectively), an immunological identity of the cytochrome P-450 isoforms during PFD and PB induction has been found. According to the rocket immunoelectrophoresis the content of cytochrome P-450 in PFD-microsomes, which is immunologically indistinguishable from P-450b, was approximately 70% of the total cytochrome P-450. Two forms of cytochrome P-450 were isolated from the liver microsomes of PFD-induced rats and purified to homogeneity. A comparison of these forms with cytochromes P-450b and P-450e obtained from the PB-induced rat liver microsomes revealed their similarity in a number of properties, e.g., chromotographic behavior on DEAE-Sephacel column, molecular weight determined by sodium dodecyl sulphate (SDS) electrophoresis in polyacrylamide gel, immunoreactivity, peptide mapping, catalytic activity. The data presented demonstrate that PFD induced in rat liver microsomes the cytochrome P-450 forms whose immunological properties and substrate specificity correspond to those of the PB-type cytochrome P-450. These findings suggest that PFD and PB, which differ in their chemical structure, induce in the rat liver microsomes identical forms of cytochrome P-450.     

Regulation of arachidonic acid metabolism by cytochrome P-450 in rabbit kidney.

Renal microsomal cytochrome P-450-dependent arachidonic acid metabolism was correlated with the level of cytochrome P-450 in the rabbit kidney. Cobalt, an inducer of haem oxygenase, reduced cytochrome P-450 in both the cortex and medulla in association with a 2-fold decrease in aryl-hydrocarbon hydroxylase, an index of cytochrome P-450 activity, and a similar decrease in the formation of cytochrome P-450-dependent arachidonic acid metabolites by renal microsomes (microsomal fractions). Formation of the latter was absolutely dependent on NADPH addition and was prevented by SKF-525A, an inhibitor of cytochrome P-450-dependent enzymes. Arachidonate metabolites of cortical microsomes were identified by g.c.-m.s. as 20- and 19-hydroxyeicosatetraenoic acid, 11,12-epoxyeicosatrienoic acid and 11,12-dihydroxyeicosatrienoic acid. The profile of arachidonic acid metabolites was the same for the medullary microsomes. Induction of cytochrome P-450 by 3-methylcholanthrene and beta-naphthoflavone increased cytochrome P-450 content and aryl-hydrocarbon hydroxylase activity by 2-fold in the cortex and medulla, and this correlated with a 2-fold increase in arachidonic acid metabolites via the cytochrome P-450 pathway. These changes can also be demonstrated in cells isolated from the medullary segment of the thick ascending limb of the loop of Henle, which previously have been shown to metabolize arachidonic acid specifically via the cytochrome P-450-dependent pathway. The specific activity for the formation of arachidonic acid metabolites by this pathway is higher in the kidney than in the liver, the highest activity being in the outer medulla, namely 7.9 microgram as against 2.5 micrograms of arachidonic acid transformed/30 min per nmol of cytochrome P-450 for microsomes obtained from outer medulla and liver respectively. These findings are consistent with high levels of cytochrome P-450 isoenzyme(s), specific for arachidonic acid metabolism, primarily localized in the outer medulla.     

Activation of the microsomal glutathione S-transferase by metabolites of alpha-methyldopa

Rat liver microsomes contain a membrane-bound GSH S-transferase (GSH-tr), an enzyme that is involved in the detoxication of xenobiotics. Also located on rat liver microsomes is the cytochrome P450 system, an enzyme complex that catalyzes the conversion of several xenobiotics into reactive intermediates. In this study, it was demonstrated that reactive products from alpha-methyldopa formed by the cytochrome P450 system are able to stimulate microsomal GSH-tr. Also, products formed from alpha-methyldopa that are generated by H2O2-horseradish peroxidase and tyrosinase are able to stimulate the activity of microsomal GSH-tr. GSH was able to prevent the activation of microsomal GSH-tr. Our results indicate that the ortho-quinone or semi-ortho-quinone radical of alpha-methyldopa is responsible for the stimulation of microsomal GSH-tr, probably via arylation of the free sulfhydryl group of microsomal GSH-tr. This conclusion was supported by the observation that 4-methyl-ortho-quinone itself was able to stimulate microsomal GSH-tr via sulfhydryl arylation. Our results are in conformity with the hypothesis that reactive products formed by the cytochrome P450 complex are able to stimulate microsomal GSH-tr and possibly in this way enhance their detoxication.     

Target organ-specific inactivation of drug metabolizing enzymes in kidney of hamsters treated with estradiol

Chronic treatment of hamsters with estradiol for several months has previously been shown to decrease the specific content of cytochrome P450 in the kidney, a target of hormonal carcinogenesis, but not in liver. The reason for this decrease in metabolic enzyme activity is unknown and has been examined in this investigation. We now report that the decrease in specific content of renal cytochrome P450 by 73% in response to estradiol was not affected by co-treatment with tamoxifen for 1 month. The subcutaneous infusion of 250 μg/day estradiol for 7 days lowered renal cytochrome P450 by 71% from control values and was therefore used for further mechanistic studies. This treatment decreased renal activities of estradiol 2- or 4-hydroxylase by 77 to 80%, of 7-ethoxycoumarin-O-deethylase by 66% of control values, respectively, and completely eliminated aryl hydrocarbon hydroxylase activities, whereas liver enzymes remained unaffected. After 7 days of infusion of estradiol, fluorescent products of lipid peroxidation were more than doubled in hamster kidney but remained unchanged in liver. The possibility of enzyme destruction by binding of estradiol 2,3-quinone to metabolizing enzymes was investigatedin vitro. In the presence of 2-hydroxyestradiol, cumene hydroperoxide, and microsomes, conditions known to favor the oxidation of the steroid to quinone, the binding of catechol estrogen metabolite to microsomal protein increased 60 fold over control values in the absence of cofactor. Purified rat liver cytochrome P450c also oxidized 2-hydroxyestradiol to 2,3-estradiol quinone. The rate of oxidation was linear for the first 2–3 min, but thereafter decreased with time. Under these incubation conditions, irreversible binding of catechol estrogen metabolite to cytochrome P450c increased for the first 2–3 min and then remained at this plateau level. It was concluded that enzyme destruction by a reactive estrogen metabolite or by lipid peroxides may be a major reason for the organ-specific decrease in cytochrome P450 enzymes in kidneys of estrogen-treated hamsters.     

Cytochrome P-450 and oxygen toxicity. Oxygen-dependent induction of ethanol-inducible cytochrome P-450 (IIE1) in rat liver and lung

The ethanol-inducible form of cytochrome P-450 (P-450IIE1) has previously been shown to exhibit an unusually high rate of oxidase activity with the subsequent formation of reactive oxygen species, e.g., hydrogen peroxide, and to be the main contributor of microsomal oxidase activity in liver microsomes from acetone-treated rats [Ekstr?m & Ingelman-Sundberg (1989) Biochem. Pharmacol. (in press)]. The results here presented indicate that oxygen exposure of rats causes an about 4-fold induction of P-450IIE1 in rat liver and lung microsomes. The induction in liver was not accompanied by any measurable increase in the P-450IIE1 mRNA levels, but the enhanced amount of P-450IIE1 accounted for 60% of the net 50% increase in the level of hepatic P-450 as determined spectrophotometrically. The induction of P-450IIE1 was maximal after 60 h of O2 exposure, and concomitant increases in the rates of liver microsomal CCl4-dependent lipid peroxidation, O2 consumption, NADPH oxidation, O2- formation, H2O2 production, and NADPH-dependent microsomal lipid peroxidation were seen. Liver microsomes from oxygen-treated rats had very similar properties to those of microsomes isolated from acetone-treated rats with respect to the P-450IIE1 content and catalytic properties, but different from those of thyroxine-treated animals. Treatment of rats with the P-450IIE1 inducer acetone in combination with oxygen exposure caused a potentiation of the NADPH-dependent liver and lung microsomal lipid peroxidation and decreased the survival time of the rats. The results reached indicate a role for cytochrome P-450 and, in particular, for cytochrome P-450IIE1 in oxygen-mediated tissue toxicity.     

Hydroxylation of 5 alpha-androstane-3 beta,17 beta-diol by rat prostate microsomes: effects of antibodies and chemical inhibitors of cytochrome P450 enzymes.

The purpose of the present study was to test the hypothesis that rat prostate microsomes contain a single cytochrome P450 enzyme responsible for the conversion of 5 alpha-androstane-3 beta,17 beta-diol to a series of trihydroxylated products. The three major metabolites formed by in vitro incubation of 5 alpha-[3H]androstane-3 beta,17 beta-diol with rat prostate microsomes were apparently 5 alpha-androstane-3 beta,6 alpha,17 beta-triol, 5 alpha-androstane-3 beta,7 alpha,17 beta-triol, and 5 alpha-androstane-3 beta,7 beta,17 beta-triol, which were resolved and quantified by reverse-phase HPLC with a flow through radioactivity detector. The ratio of the three metabolites remained constant as a function of incubation time, microsomal protein concentration, ionic strength, and substrate concentration. The ratio of the three metabolites was dependent on pH, apparently because the hydroxylation of 5 alpha-androstane-3 beta,17 beta-diol shifted from the 6 alpha- to the 7 alpha-position with increasing pH (6.8-8.0). The V(max) values were 380, 160, and 60 pmol/mg microsomal protein/min for the rate of 6 alpha-, 7 alpha-, and 7 beta-hydroxylation, respectively. Similar Km values (0.5-0.7 microM) were measured for enzymatic formation of all three metabolites, which suggests that formation of all three metabolites was catalyzed by a single, high-affinity enzyme. Testosterone, 5 alpha-dihydrotestosterone, and 5 alpha-androstane-3 alpha,17 beta-diol did not appreciably inhibit the hydroxylation of 5 alpha-androstane-3 beta,17 beta-diol, suggesting that this enzyme exhibits a high degree of substrate specificity. Formation of all three metabolites was inhibited by antibody against rat liver NADPH-cytochrome P450 reductase (85%) and by a 9:1 mixture of carbon monoxide and oxygen (60%). Several chemical inhibitors of cytochrome P450 enzymes, especially the antimycotic drug clotrimazole, also inhibited the formation of all three metabolites. Polyclonal antibodies that recognize liver cytochrome P450 1A, 2A, 2B, 2C, and 3A enzymes did not inhibit 5 alpha-androstane-3 beta,17 beta-diol hydroxylase activity. Overall, these results are consistent with the hypothesis that the 6 alpha-, 7 alpha-, and 7 beta-hydroxylation of 5 alpha-androstane-3 beta,17 beta-diol by rat prostate microsomes is catalyzed by a single, high-affinity P450 enzyme. This cytochrome P450 enzyme appears to be structurally distinct from those in the 1A, 2A, 2B, 2C, and 3A gene families.     

Catalytic activity and substrate specificity of the flavin-containing monooxygenase in microsomal systems: characterization of the hepatic, pulmonary and renal enzymes of the mouse, rabbit, and rat

Inhibitory antibodies against NADPH-cytochrome P-450 reductase, detergent solubilization to dissociate functional interaction between the reductase and cytochrome P-450, and selective trypsin degradation have been used to characterize flavin-containing monooxygenase activity in microsomes from different tissues and species. A comparison of assay methods is reported. The native microsome-bound flavin-containing monooxygenase of mouse, rabbit, and rat liver, lung, and kidney can metabolize compounds containing thiol, sulfide, thioamide, secondary and tertiary amine, hydrazine, and phosphine substituents. Therefore, this enzyme from these common experimental animals has catalytic capabilities similar to those of the well-characterized porcine liver enzyme. True allosteric activation by n-octylamine does not appear to be a property of either the mouse, rabbit, or rat liver enzymes, but is a property of the pig liver and mouse lung enzymes. The microsomal pulmonary flavin-containing monooxygenase of the rabbit has some unique substrate preferences which differ from the mouse lung enzyme. Both the rabbit and mouse pulmonary enzymes have recently been shown to be distinct enzyme forms. However, the rat pulmonary flavin-containing monooxygenase appears to be catalytically identical to the rat liver enzyme, and does not have any of the unusual catalytic properties of either the rabbit or mouse lung enzymes. Enzyme activity of mouse, rabbit, and rat kidney microsomes is qualitatively similar to the hepatic activities. Substrates which saturate the microsome-bound flavin-containing monooxygenase at 1.0 mM, including thiourea, thioacetamide, methimazole, cysteamine, and thiobenzamide, are metabolized at common maximal velocities. This suggests that the kinetic mechanism of the native enzyme is similar to that established for the isolated porcine liver enzyme in that the rate-limiting step of catalysis occurs after substrate binding, and that all substrates capable of saturating the microsomal enzyme should be metabolized at a common maximal velocity.     

Purification and characterization of the dog hepatic cytochrome P-450 isozyme responsible for the metabolism of 2,2',4,4',5,5'-hexachlorobiphenyl

The biochemical basis for the marked difference in the rate of the hepatic metabolism of 2,2',4,4',5,5'-hexachlorobiphenyl (245-HCB) by Beagle dogs and Sprague-Dawley rats has been investigated. Control dog liver microsomes metabolize this substrate 15 times faster than control rat liver microsomes. Upon treatment with phenobarbital (PB), at least two cytochrome P-450 isozymes are induced in the dog, and the hepatic microsomal metabolism of 245-HCB is increased on both a per nanomole P-450 basis (twofold) and a per milligram protein basis (fivefold). One of the PB-induced isozymes, PBD-2, has been purified to a specific content of 17-19 nmol/mg protein and to less than 95% homogeneity, as evidenced by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In a reconstituted system containing cytochrome b5, this isozyme shows an activity toward 245-HCB which is greater than threefold that seen in intact liver microsomes from PB-induced dogs. A reconstituted system containing the major isozyme induced by PB in the rat (PB-B) metabolizes 245-HCB at 1/10 the rate observed with purified PBD-2. Antibody inhibition studies have shown that PBD-2 accounts for greater than 90% of the hepatic microsomal metabolism of 245-HCB in control and PB-induced dogs, while PB-B only accounts for about half of the metabolism of this compound by microsomes obtained from PB-treated rats. Immunoblot analysis has revealed that the level of PBD-2 in dog liver microsomes increases nearly sixfold with PB treatment, and this increase correlates well with the fivefold increase in the rate of hepatic microsomal metabolism of 245-HCB by dogs. Together these data support a primary role for isozyme PBD-2 in the hepatic metabolism of 245-HCB in control and PB-induced dogs. In addition, these results suggest that, in contrast to rats, dogs can readily metabolize 245-HCB as a result of the presence of a cytochrome P-450 isozyme with efficient 245-HCB metabolizing activity.