Evidence for the involvement of a distinct form of cytochrome p450 3a in the oxidation of digitoxin by rat liver microsomes

The preceding paper (B. Gemzik, D. Greenway, C. Nevins, and A. Parkinson (1992). Regulation of two electrophoretically distinct proteins recognized by antibody against rat liver cytochrome P450 3A1. J. Biochem. Toxicol, 7 (43–52).) described the regulation of two rat liver microsomal proteins (50- and 51-kDa) recognized by antibody against P450 3A1. It was also shown that changes in the levels of the 51-kDa 3A protein were usually paralleled by changes in the rate of testosterone 2β-, 6β-, and 15β-hydroxylation. The present study demonstrates that age- and sex-dependent changes in the 50-kDa protein were paralleled by changes in the rate of digitoxin oxidation to digitoxigenin bisdigitoxoside. Induction or suppression of the 50-kDa protein by treatment of rats with various xenobiotics were also paralleled by changes in the rate of digitoxin oxidation. These results suggest that, contrary to previous assumptions, the conversion of digitoxin to digitoxigenin bisdigitoxoside and the conversion of testosterone to 2β-, 6β- and 15β-hydroxytestosterone are primarily catalyzed by different forms of P450 3A. Further evidence for this coclusion was obtained from studies in which the suicide inhibitor, chloramphenicol, was administered to mature female rats previously treated with pregnenolone-16α-carbonitrile (PCN), which induces both the 50-kDa and the 51-kDa protein. Treatment of mature female rats with PCN alone caused a marked increase (16- to 18-fold) in the 6β-hydroxylation of testosterone and the rate of digitoxin oxidation. Treatment of PCN-induced rats with chloramphenicol caused a ～70% decrease in liver microsomal testosterone 6β-hydroxylation, but had no effect on the rate of conversion of digitoxin to digitoxigenin bisdigitoxoside. The oxidation of testosterone by purified 3A1 (a 51-kDa protein) was also inhibited by chloramphenicol in a time- and reduced nicotinamite adenine dinucleotide phosphate (NADPH)-dependent manner. In addition to testosterone and chloramphenicol, purified 3A1 also metabolized trole-andomycin, but it was unable to convert digitoxin to digitoxigenin bisdigitoxoside. Testosterone inhibited the microsomal oxidation of digitoxin, but digitoxin did not inhibit testosterone oxidation. This suggests that testosterone is a substrate for the 3A enzyme that metabolizes digitoxin, but that this form of P450 3A does not contribute significantly to testosterone oxidation by rat liver microsomes. We propose that the 2SbT-, 6β-, and 15β-hydroxylation of testosterone by rat liver microsomes is primarily catalyzed by the 51-kDa 3A proteins (either 3A1 or 3A2 depending on the source of microsomes), whereas digitoxin oxidation is primarily catalyzed by the 50-kDa protein.     

Regulation of two electrophoretically distinct proteins recognized by antibody against rat liver cytochrome P450 3A1.

We recently reported that antibody against purified P450 3A1 (P450p) recognizes two electrophoretically distinct proteins (50 and 51 kDa) in liver microsomes from male and female rats, as determined by Western immunoblotting. Depending on the source of the liver microsomes, the 51-kDa protein corresponded to 3A1 and/or 3A2 which could not be resolved by sodium dodecyl sulfate (SDS)polyacrylamide gel electrophoresis. The other protein (50 kDa) appears to be another member of the P450 IIIA gene family. Both proteins were markedly intensified in liver microsomes from male or female rats treated with pregnenolone-16 alpha-carbonitrile, dexamethasone, troleandomycin, or chlordane. In contrast, treatment of male or female rats with phenobarbital intensified only the 51-kDa protein. Treatment of male rats with Aroclor 1254 induced the 51-kDa protein, but suppressed the 50-kDa form. In addition to their changes in response to inducers, the 50- and 51-kDa proteins also differed in their developmental expression. For example, the 50-kDa protein was not expressed until weaning (3 weeks), whereas the 51-kDa protein was expressed even in 1-week-old rats. At puberty (between weeks 5 and 6), the levels of the 50-kDa and 51-kDa proteins markedly declined in female but not in male rats, which introduced a large sex difference (male greater than female) in the levels of both proteins. Changes in the level of the 51-kDa protein were paralleled by changes in the rate of testosterone 2 beta-, 6 beta-, and 15 beta-hydroxylation. In male rats, the marked increase in the levels of the 50-kDa protein between weeks 2 and 3 coincided with a three- to four fold increase in the rate of testosterone 2 beta-, 6 beta-, and 15 beta-hydroxylation, which suggests that the 50-kDa protein catalyzes the same pathways of testosterone oxidation as the 51-kDa protein. However, this developmental increase in testosterone oxidation may have resulted from an activation of the 51-kDa 3A protein. These results indicate that the two electrophoretically distinct proteins recognized by antibody against P450 3A1 are regulated in a similar but not identical manner, and suggest that the 51-kDa 3A protein is the major microsomal enzyme responsible for catalyzing the 2 beta-, 6 beta-, and 15 beta-hydroxylation of testosterone.     

Reversible and time-dependent inhibition of the hepatic cytochrome P450 steroidal hydroxylases by the proestrogenic pesticide methoxychlor in rat and human

Methoxychlor, a currently used pesticide, is demethylated and hydroxylated by several hepatic microsomal cytochrome P450 enzymes. Also, methoxychlor undergoes metabolic activation, yielding a reactive intermediate (M*) that binds irreversibly and apparently covalently to microsomal proteins. The study investigated whether methoxychlor could inhibit or inactivate certain liver microsomal P450 enzymes. The regioselective and stereoselective hydrox-ylation of testosterone and the 2-hydroxylation of estradiol (E₂) were utilized as markers of the P450 enzymes inhibited by methoxychlor. Both reversible and time-dependent inhibition were examined. Coincubation of methoxychlor and testosterone with liver microsomes from phenobarbital treated (PB-microsomes) male rats, yielded marked diminution of 2α- and 16α-testosterone hydroxylation, indicating strong inhibition of P4502C11 (P450h). Methoxychlor moderately inhibited 2β-, 7α-, 15α-, 15β-, and 16β-hydroxylation and androstenedi-one formation. There was only a weak inhibition of 6β-ydroxylation of testosterone. The methox-ychlor-mediated inhibition of 6β-hydroxylation was competitive. By contrast, when methoxychlor was permitted to be metabolized by PB-microsomes or by liver microsomes from pregnenolone-16α-car-bonitrile treated rats (PCN-microsomes) prior to addition of testosterone, a pronounced time-dependent inhibition of 6β-hydroxylation was observed, suggesting that methoxychlor inactivates the P450 3A isozyme(s). The di-demethylated methoxychlor (bis-OH-M) and the tris-hydroxy (ca-techol) methoxychlor metabolite (tris-OH-M) inhibited 6β-hydroxylation in PB-microsomes competitively and noncompetitively, respectively; however, these methoxychlor metabolites did not exhibit a time-dependent inhibition. Methoxychlor inhibited competitively the formation of 7α-hydroxytestosterone (7α-OH-T) and 16α-hydroxy-testosterone (16α-OH-T) but exhibited little or no time-dependent inhibition of generation of these metabolites, indicating that P450s 2A1, 2B1/B2, and 2C11 were inhibited but not inactivated. Methoxychlor inhibited in a time-dependent fashion the 2-hydroxylation of E2 in PB-microsomes. However, bis-OH-M exhibited solely reversible inhibition of the 2-hydroxylation, supporting our conclusion that the inactivation of P450s does not involve participation of the demethylated metabolites. Both competitive inhibition and time-dependent inactivation of human liver P450 3A (6β-hydroxylase) by methoxychlor, was observed. As with rat liver microsomes, the human 6β-hydroxylase was inhibited by bis-OH-M and tris-OH-M competitively and noncompetitively, respectively. Testosterone and estradiol strongly inhibited the irreversible binding of methoxychlor to microsomal proteins. This might explain the “clean” competitive inhibition by methoxychlor of the 6β-OH-T formation when the compounds were coin-cubated. Glutathione (GSH) has been shown to interfere with the irreversible binding of methoxychlor to PB-microsomal proteins. The finding that the coincubation of GSH with methoxychlor partially diminishes the time-dependent inhibition of 6β-hydroxylation provides supportive evidence that the inactivation of P450 3A isozymes by methoxychlor is related to the formation of M*.     

Evidence for the involvement of a distinct form of cytochrome P450 3A in the oxidation of digitoxin by rat liver microsomes.

The preceding paper (B. Gemzik, D. Greenway, C. Nevins, and A. Parkinson (1992). Regulation of two electrophoretically distinct proteins recognized by antibody against rat liver cytochrome P450 3A1. J. Biochem. Toxicol., 7 (43-52).) described the regulation of two rat liver microsomal proteins (50- and 51-kDa) recognized by antibody against P450 3A1. It was also shown that changes in the levels of the 51-kDa 3A protein were usually paralleled by changes in the rate of testosterone 2 beta-, 6 beta-, and 15 beta-hydroxylation. The present study demonstrates that age- and sex-dependent changes in the 50-kDa protein were paralleled by changes in the rate of digitoxin oxidation to digitoxigenin bisdigitoxoside. Induction or suppression of the 50-kDa protein by treatment of rats with various xenobiotics were also paralleled by changes in the rate of digitoxin oxidation. These results suggest that, contrary to previous assumptions, the conversion of digitoxin to digitoxigenin bisdigitoxoside and the conversion of testosterone to 2 beta-, 6 beta-, and 15 beta-hydroxytestosterone are primarily catalyzed by different forms of P450 3A. Further evidence for this conclusion was obtained from studies in which the suicide inhibitor, chloramphenicol, was administered to mature female rats previously treated with pregnenolone-16 alpha-carbonitrile (PCN), which induces both the 50-kDa and the 51-kDa protein. Treatment of mature female rats with PCN alone caused a marked increase (16- to 18-fold) in the 6 beta-hydroxylation of testosterone and the rate of digitoxin oxidation. Treatment of PCN-induced rats with chloramphenicol caused a approximately 70% decrease in liver microsomal testosterone 6 beta-hydroxylation, but had no effect on the rate of conversion of digitoxin to digitoxigenin bisdigitoxoside. The oxidation of testosterone by purified 3A1 (a 51-kDa protein) was also inhibited by chloramphenicol in a time- and reduced nicotinamide adenine dinucleotide phosphate (NADPH)-dependent manner. In addition to testosterone and chloramphenicol, purified 3A1 also metabolized troleandomycin, but it was unable to convert digitoxin to digitoxigenin bisdigitoxoside. Testosterone inhibited the microsomal oxidation of digitoxin, but digitoxin did not inhibit testosterone oxidation. This suggests that testosterone is a substrate for the 3A enzyme that metabolizes digitoxin, but that this form of P450 3A does not contribute significantly to testosterone oxidation by rat liver microsomes.(ABSTRACT TRUNCATED AT 400 WORDS)     

Age-dependent exression of cytochrome P-450s in rat liver

Age-related changes in the levels of multiple forms of cytochrome P-450 as well as in the testosterone hydroxylation activities of hepatic microsomes of male and female rats of different ages from 1 week to 104 weeks (24 months) were investigated. The total cytochrome P-450 measured photometrically did not change much with age in either male and female rats. Testosterone 2α-, 2β-, 15α-, 16α-, and 16β-hydroxylation activities of male rats were much higher than those in female rats and were induced developmentally. These activities in male rats declined with aging to the very low level in female rats by 104 weeks of age. Testosterone 7α-hydroxylation activity was maximum at 3 weeks of age in rats of both sexes. The levels of individual cytochrome P-450s were measured by immunoblotting. P450IA1 and IA2 (3-methylcholanthrene-inducible forms) and P450IIB1 and IIB2 (phenobarbital-inducible form) were detected at low levels in rats of both sexes at all ages. P450IIA2, IIC11 and IVA2 were detected in male rats only and were induced developmentally. These male-specific forms disappeared in male rat liver at 104 weeks of age. P450IIC12, a typical female-specific form, was induced developmentally in female rats and was also detected in male rats at 3 and 104 weeks of age. P450IIIA2 (testosterone 6β-hydroxylase) was induced developmentally in male rats, but disappeared when the rats were 104 weeks of age. In female rats, P450IIIA2 was detected only at 1 and 3 weeks of age. P450IIA1, IIC6, IIE1 and IVA3 were detected in rats of both sexes at any age. P450IIC6 and IVA3 were induced developmentally and detected at a similar level in rats of both sexes. The level of P450IIA1 was maximum at 3 weeks of age in rats of both sexes. The changes in the level of P450IIE1 during aging were small compared with the changes in other cytochrome P-450s used in this study. These observations provide concrete evidence to our earlier hypothesis that each of the forms of cytochrome P-450 in male rats alter with aging in different patterns resulting in a practical feminization of over-all cytochrome P-450 composition at old age.     

Glutathione Oxidase from Bovine Skim Milk Membranes: Its Copurification with γ-Glutamyltransferase

Two hundred thirteen cytochrome P450 (P450) genes were collected from bacteria and expressed based on an Escherichia coli expression system to test their hydroxylation ability to testosterone. Twenty-four P450s stereoselectively monohydroxylated testosterone at the 2α-, 2β-, 6β-, 7β-, 11β-, 12β-, 15β-, 16α-, and 17-positions (17-hydroxylation yields 17-ketoproduct). The hydroxylation site usage of the P450s is not the same as that of human P450s, while the 2α-, 2β-, 6β-, 11β-, 15β-, 16α-, and 17-hydroxylation are reactions common to both human and bacterial P450s. Most of the testosterone hydroxylation catalyzed by bacterial P450s is on the β face.     

Hormonal regulation of rat renal cytochrome P450s by androgen and the pituitary.

The hormonal regulation of rat renal cytochrome P450s, P450 4A2 (K-5) and K-2, was investigated. The level of P450 4A2 in male rats was five times that in female rats and accounted for some 90% of total cytochrome P450, measured photometrically. Lauric acid omega- and (omega-1)-hydroxylation activities of renal microsomes of male rats were also higher than those of female rats. The sex differences in lauric acid hydroxylation activity seemed to arise from the differences in P450 4A2 concentrations, according to an immunochemical study. P450 K-2 was a female-dominant form in rat kidneys. The level of P450 K-2 in renal microsomes of male rats was one-tenth that of P450 4A2. Castration of male rats decreased the levels of P450 4A2 and treatment of castrated male rats with testosterone reversed the decrease. The castration of male rats decreased the lauric acid hydroxylation of the renal microsomes to the level of female rats. The administration of testosterone to castrated male rats reversed the decrease. Hypophysectomy of male rats decreased the level of P450 4A2 and the administration of growth hormone reversed the decrease when intermittent injections mimicking the male secretory pattern were given, although continuous administration mimicking the female secretory pattern did not. Castration of male rats did not affect the level of P450 K-2, but testosterone decreased its level. Hypophysectomy of male rats increased the level of P450 K-2 and growth hormone decreased its level in hypophysectomized rats. These results suggested that the expression of P450 4A2 was regulated by androgen or growth hormone and regulation of P450 4A2 was different from that of P450 K-2. To explore the regulation of renal cytochrome P450 further, testosterone was given to control (intact) or hypophysectomized adult female rats. P450 4A2 was induced in the kidneys of both control and hypophysectomized female rats to close to the level of male rats. Thus, P450 4A2 was directly regulated by testosterone as well as growth hormone, and the regulation of the male-dominant form in rat kidneys was different from that of the male-specific form in the rat liver, which is regulated mostly by growth hormone.     

Oxidation of Dihydrotestosterone by Human Cytochromes P450 19A1 and 3A4

Dihydrotestosterone is a more potent androgen than testosterone and plays an important role in endocrine function. We demonstrated that, like testosterone, dihydrotestosterone can be oxidized by human cytochrome P450 (P450) 19A1, the steroid aromatase. The products identified include the 19-hydroxy- and 19-oxo derivatives and the resulting Δ(1,10)-, Δ(5,10)-, and Δ(9,10)-dehydro 19-norsteroid products (loss of 19-methyl group). The overall catalytic efficiency of oxidation was ～10-fold higher than reported for 3α-reduction by 3α-hydroxysteroid dehydrogenase, the major enzyme known to deactivate dihydrotestosterone. These and other studies demonstrate the flexibility of P450 19A1 in removing the 1- and 2-hydrogens from 19-norsteroids, the 2-hydrogen from estrone, and (in this case) the 1-, 5β-, and 9β-hydrogens of dihydrotestosterone. Incubation of dihydrotestosterone with human liver microsomes and NADPH yielded the 18- and 19-hydroxy products plus the Δ(1,10)-dehydro 19-nor product identified in the P450 19A1 reaction. The 18- and 19-hydroxylation reactions were attributed to P450 3A4, and 18- and 19-hydroxydihydrotestosterone were identified in human plasma and urine samples. The change in the pucker of the A ring caused by reduction of the Δ(4,5) bond is remarkable in shifting the course of hydroxylation from the 6β-, 2β-, 1β-, and 15β-methylene carbons (testosterone) to the axial methyl groups (18, 19) in dihydrotestosterone and demonstrates the sensitivity of P450 3A4, even with its large active site, to small changes in substrate structure.     

Cytochrome P-450C-M/F, a new constitutive form of microsomal cytochrome P-450 in male and female rat liver with estrogen 2- and 16 alpha-hydroxylase activity

A new cytochrome P-450 isozyme, P-450C-M/F, has been purified from untreated rat liver microsomes. The purified preparation was electrophoretically homogeneous and contained 12-15 nmol of P450/mg of protein and had a minimum molecular weight of 48,500. The NH2-terminal amino acid sequence of P-450C-M/F was different from that of other P-450's. Immunoblot analysis of microsomes demonstrated that P-450C-M/F was present in the liver of untreated male as well as female rats. Treatment of rats with phenobarbital, 3-methylcholanthrene, or beta-naphthoflavone did not induce P-450C-M/F. Cytochrome P-450C-M/F exhibited little activities of 7-ethoxycoumarin and 7-ethoxyresorufin O-deethylation or hydroxylation of arylhydrocarbon, testosterone, androstenedione, and progesterone. In contrast, it was highly active in N-demethylation of ethylmorphine and benzphetamine and in 2- and 16 alpha-hydroxylation of estrogens, particularly that of estradiol. These studies establish that cytochrome P-450C-M/F is constitutively present in both male and female rats and suggest that it may be involved in the oxidative metabolism of estradiol, particularly in the formation of estriol, the uterotropic metabolite of estradiol.     

Cytochrome P450 isozymes catalyzing 4-hydroxylation of parkinsonism-related compound 1,2,3,4-tetrahydroisoquinoline in rat liver microsomes.

Microsomal 4-hydroxylase of 1,2,3,4-tetrahydroisoquinoline (TIQ), a possible candidate for causing Parkinson disease, was characterized by using rat hepatic microsomes and purified P450 isozymes. Kinetic analysis revealed that Km and Vmax values (mean +/- SE) for hepatic microsomal TIQ 4-hydroxylase of male Wistar rats were 319.6 +/- 26.8 microM and 12.13 +/- 1.43 pmol.min-1.mg-1 protein, respectively. When TIQ 4-hydroxylase activity was compared in Wistar (an animal model of extensive debrisoquine metabolizers) and Dark Agouti (an animal model of poor debrisoquine metabolizers) rats, significant strain (Wistar greater than Dark Agouti) and sex (male greater than female) differences were observed. The microsomal activity toward TIQ 4-hydroxylation was increased by pretreatment of male Wistar rats with P448 inducers (beta-naphthoflavone and sudan I), but not with phenobarbital. Pretreatment with propranolol, an inhibitor of P450 isozymes belonging to the P450 IID gene subfamily, decreased TIQ 4-hydroxylase activity. P450 BTL, a P450 isozyme belonging to the IID subfamily, showed TIQ 4-hydroxylase activity of 64.1 pmol.min-1.nmol P450(-1), which was 3.2-fold that of microsomes (20.9 pmol.min-1.nmol P450(-1)). Antibody (IgG) against this isozyme suppressed microsomal TIQ 4-hydroxylase activity concentration-dependently. A male-specific P450 ml (P450IIC11) catalyzed this reaction to a much lesser extent (10.0 pmol.min-1.nmol P450(-1)), and its antibody did not affect the microsomal activity. These results suggest that TIQ 4-hydroxylation in hepatic microsomes are catalyzed predominantly by a P450 isozyme (or isozymes) belonging to the IID gene subfamily in non-treated rats and its immunochemically related P450 isozyme (or isozymes), and that a P450 isozyme (or isozymes) belonging to the IA subfamily also participates in TIQ 4-hydroxylation in rats pretreated with P448-inducers.     

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.     

Cytochrome P450 activities in pure and co-cultured rat hepatocytes. Effects of model inducers

Summary The stability and inducibility of several P450 activities (namely, P450 1A1, 2A1, 2B1/2, 2C11, and 3A1) were studied in rat hepatocytes co-cultured with the MS epithelial cell line derived from monkey kidney. The results revealed that these monooxygenase activities were systematically higher in co-cultures than in conventional hepatocyte cultures. Pure cultures showed a rapid loss of monooxygenase activities, which were undetectable after 5 days. In contrast, all isozymes assayed were measurable in co-cultured hepatocytes on Day 7 (about 15 to 40% of the initial activities of Day 0 of culture). The beneficial effects of the co-culture system seemed to be more selective for certain cytochrome P450 isoforms, with P450 1A1 and 3A1 being the best stabilized isozymes after 1 wk. A clear response to inducers was observed in co-cultures, each isozyme showing a different induction pattern. 3-Methylcholanthrene produced a strong increase in P450 1A1 (7-ethoxyresorufin O-deethylase) activity and a low increase in P450 2A1 (testosterone 7α-hydroxylation), whereas no changes were observed in the other activities. Phenobarbital treatment resulted in increases in P450 2B1/2 (7-pentoxyresorufin O-depentylase and 16α- and 16β-hydroxylation of testosterone) activities, while minor effects were observed on P450 3A1 (testosterone 6β-hydroxylation) activity. Dexamethasone markedly increased P450 3A1 (testosterone 6β- and 15β-hydroxylation) activity and, to a lesser extent, P450 2B1/2 (16β-hydroxylation).     

6α-Hydroxylation of taurochenodeoxycholic acid and lithocholic acid by CYP3A4 in human liver microsomes

The aim of the present study was to identify the enzymes in human liver catalyzing hydroxylations of bile acids. Fourteen recombinant expressed cytochrome P450 (CYP) enzymes, human liver microsomes from different donors, and selective cytochrome P450 inhibitors were used to study the hydroxylation of taurochenodeoxycholic acid and lithocholic acid. Recombinant expressed CYP3A4 was the only enzyme that was active towards these bile acids and the enzyme catalyzed an efficient 6α-hydroxylation of both taurochenodeoxycholic acid and lithocholic acid. The V_max for 6α-hydroxylation of taurochenodeoxycholic acid by CYP3A4 was 18.2 nmol/nmol P450/min and the apparent K_m was 90 μM. Cytochrome b₅ was required for maximal activity. Human liver microsomes from 10 different donors, in which different P450 marker activities had been determined, were separately incubated with taurochenodeoxycholic acid and lithocholic acid. A strong correlation was found between 6α-hydroxylation of taurochenodeoxycholic acid, CYP3A levels (r²=0.97) and testosterone 6β-hydroxylation (r²=0.9). There was also a strong correlation between 6α-hydroxylation of lithocholic acid, CYP3A levels and testosterone 6β-hydroxylation (r²=0.7). Troleandomycin, a selective inhibitor of CYP3A enzymes, inhibited 6α-hydroxylation of taurochenodeoxycholic acid almost completely at a 10 μM concentration. Other inhibitors, such as α-naphthoflavone, sulfaphenazole and tranylcypromine had very little or no effect on the activity. The apparent K_m for 6α-hydroxylation of taurochenodeoxycholic by human liver microsomes was high (716 μM). This might give an explanation for the limited formation of 6α-hydroxylated bile acids in healthy humans. From the present results, it can be concluded that CYP3A4 is active in the 6α-hydroxylation of both taurochenodeoxycholic acid and lithocholic acid in human liver.     

Purification of two isozymes of rat liver microsomal cytochrome P450 with testosterone 7 alpha-hydroxylase activity

Cytochrome P450a was purified to electrophoretic homogeneity from liver microsomes from immature male Long-Evans rats treated with Aroclor 1254. Rabbit polyclonal antibody raised against cytochrome P450a cross-reacted with cytochromes P450b, P450e, and P450f (which are structurally related to cytochrome P450a). The cross-reacting antibodies were removed by passing anti-P450a over an N-octylamino-Sepharose column containing these heterologous antigens. The immunoabsorbed antibody recognized only a single protein (i.e., cytochrome P450a) in liver microsomes from immature male rats treated with Aroclor 1254 (i.e., the microsomes from which cytochrome P450a was purified). However, the immunoabsorbed antibody recognized three proteins in liver microsomes from mature male rats, as determined by Western immunoblot. As expected, one of these proteins (Mr 48,000) corresponded to cytochrome P450a. The other two proteins did not correspond to cytochromes P450b, P450e, or P450f (as might be expected if the antibody were incompletely immunoabsorbed), nor did they correspond to cytochromes P450c, P450d, P450g, P450h, P450i, P450j, P450k, or P450p. One of these proteins was designated cytochrome P450m (Mr approximately 49,000), the other cytochrome P450n (Mr approximately 50,000). Like cytochrome P450a, cytochrome P450n was present in liver microsomes from both male and female rats. However, whereas cytochrome P450a was detectable in liver microsomes from 1-week-old rats, cytochrome P450n was barely detectable until the rats were at least 3 weeks old. Furthermore, in contrast to cytochrome P450a, the levels of cytochrome P450n did not decline appreciably with age in postpubertal male rats. Cytochrome P450m was detectable only in liver microsomes from postpubertal (greater than 4 week-old) male rats. Cytochromes P450m and P450n were isolated from liver microsomes from mature male rats and purified to remove cytochrome P450a. When reconstituted with NADPH-cytochrome P450 reductase and lipid, cytochrome P450n exhibited little testosterone hydroxylase activity, whereas cytochrome P450m catalyzed the 15 alpha-, 18-, 6 beta-, and 7 alpha-hydroxylations of testosterone at 10.8, 4.6, 2.0, and 1.9 nmol/nmol P450/min, respectively. The ability of cytochrome P450m to catalyze the 7 alpha-hydroxylation of testosterone was not due to contamination with cytochrome P450a, which catalyzed this reaction at approximately 25 nmol/nmol P450a/min. Cytochrome P450m also converted testosterone to several minor metabolites, including androstenedione and 15 beta-, 14 alpha-, and 16 alpha-hydroxytestosterone.(ABSTRACT TRUNCATED AT 400 WORDS)     

Regulation of testosterone hydroxylation by rat liver microsomal cytochrome P-450

The pathways of testosterone oxidation catalyzed by purified and membrane-bound forms of rat liver microsomal cytochrome P-450 were examined with an HPLC system capable of resolving 14 potential hydroxylated metabolites of testosterone and androstenedione. Seven pathways of testosterone oxidation, namely the 2 alpha-, 2 beta-, 6 beta-, 15 beta-, 16 alpha-, and 18-hydroxylation of testosterone and 17-oxidation to androstenedione, were sexually differentiated in mature rats (male/female = 7-200 fold) but not in immature rats. Developmental changes in two cytochrome P-450 isozymes largely accounted for this sexual differentiation. The selective expression of cytochrome P-450h in mature male rats largely accounted for the male-specific, postpubertal increase in the rate of testosterone 2 alpha-, 16 alpha, and 17-oxidation, whereas the selective repression of cytochrome P-450p in female rats accounted for the female-specific, postpubertal decline in testosterone 2 beta-, 6 beta-, 15 beta-, and 18-hydroxylase activity. A variety of cytochrome P-450p inducers, when administered to mature female rats, markedly increased (up to 130-fold) the rate of testosterone 2 beta-, 6 beta-, 15 beta-, and 18-hydroxylation. These four pathways of testosterone hydroxylation were catalyzed by partially purified cytochrome P-450p, and were selectively stimulated when liver microsomes from troleandomycin- or erythromycin estolate-induced rats were treated with potassium ferricyanide, which dissociates the complex between cytochrome P-450p and these macrolide antibiotics. Just as the testosterone 2 beta-, 6 beta-, 15 beta-, and 18-hydroxylase activity reflected the levels of cytochrome P-450p in rat liver microsomes, so testosterone 7 alpha-hydroxylase activity reflected the levels of cytochrome P-450a; 16 beta-hydroxylase activity the levels of cytochrome P-450b; and 2 alpha-hydroxylase activity the levels of cytochrome P-450h. It is concluded that the regio- and stereoselective hydroxylation of testosterone provides a functional basis to study simultaneously the regulation of several distinct isozymes of rat liver microsomal cytochrome P-450.     

A gel-free MS-based quantitative proteomic approach accurately measures cytochrome P450 protein concentrations in human liver microsomes

The human cytochrome P450 (P450) superfamily consists of membrane-bound proteins that metabolize a myriad of xenobiotics and endogenous compounds. Quantification of P450 expression in various tissues under normal and induced conditions has an important role in drug safety and efficacy. Conventional immunoquantification methods have poor dynamic range, low throughput, and a limited number of specific antibodies. Recent advances in MS-based quantitative proteomics enable absolute protein quantification in a complex biological mixture. We have developed a gel-free MS-based protein quantification strategy to quantify CYP3A enzymes in human liver microsomes (HLM). Recombinant protein-derived proteotypic peptides and synthetic stable isotope-labeled proteotypic peptides were used as calibration standards and internal standards, respectively. The lower limit of quantification was approximately 20 fmol P450. In two separate panels of HLM examined (n = 11 and n = 22), CYP3A, CYP3A4 and CYP3A5 concentrations were determined reproducibly (CV or=0.87) and marker activities (r(2)>or=0.88), including testosterone 6beta-hydroxylation (CYP3A), midazolam 1'-hydroxylation (CYP3A), itraconazole 6-hydroxylation (CYP3A4) and CYP3A5-mediated vincristine M1 formation (CYP3A5). Taken together, our MS-based method provides a specific, sensitive and reliable means of P450 protein quantification and should facilitate P450 characterization during drug development, especially when specific substrates and/or antibodies are unavailable.     

Generation of specific antibodies and their use to characterize sex differences in four rat P450 3A enzymes following vehicle and pregnenolone 16alpha-carbonitrile treatment

The purpose of this study was to identify isozyme-specific antibodies and use them to determine the expression levels of four P450 3A enzymes in the livers of vehicle- and pregnenolone 16alpha-carbonitrile (PCN)-treated rats of both sexes, since previous work on mRNA levels has shown considerable sexual dimorphism. Using Western blot analysis with four isozyme-specific antibodies, we show that P450 3A1, 3A2, and 3A9 were expressed in vehicle-treated adult female rats at very low levels whereas P450 3A18 was not detected. PCN treatment of females strongly induced the expression of P450 3A1 in the livers with protein product increases of 214-, 3-, and 5-fold for P450 3A1, 3A2, and 3A9, respectively, and P450 3A18 was induced to 3.7 pmol/mg protein. In contrast, all four P450 3As were detected in livers of vehicle-treated males, in the order of 3A2 > 3A18 > 3A9 approximately = 3A1. The protein product increases induced by PCN treatment of male rats were 92-, 3-, 6-, and 16-fold for P450 3A1, 3A2, 3A9, and 3A18, respectively.     

Expression of four phenobarbital-inducible cytochrome P-450s in liver, kidney, and lung of rats

Specific antibodies were prepared against cytochromes P450 PB-1, PB-2, PB-4, and PB-5 purified from hepatic microsomes of male rats treated with phenobarbital. With these antibodies, the levels of these four cytochrome P450s in hepatic, renal, and pulmonary microsomes of male rats that were untreated, treated with phenobarbital, or treated with 3-methylcholanthrene were examined. P450 PB-1 and PB-2 were present in moderate amounts in hepatic microsomes of untreated male rats and were induced 2- to 3-fold with phenobarbital. Also, the expression of these forms was suppressed by 3-methylcholanthrene. These forms were not detected in the renal or pulmonary microsomes of untreated rats or rats treated with phenobarbital or 3-methylcholanthrene. P450 PB-4 and PB-5 were found in the hepatic microsomes of untreated male rats at a low level but were induced with phenobarbital more than 50-fold. P450 PB-4 and PB-5 were not detected in renal microsomes; only P450 PB-4 or a closely related form was present in the pulmonary microsomes of untreated male rats, and its level was not changed by phenobarbital treatment. The constitutive presence of P450 PB-4 in pulmonary microsomes was confirmed by the investigation of testosterone metabolism. Purified P450 PB-4 had high testosterone 16 alpha- and 16 beta-hydroxylation activity in a reconstituted system. The testosterone 16 beta-hydroxylation activity of hepatic microsomes was induced with phenobarbital, and more than 90% of the testosterone 16 beta-hydroxylation activity of hepatic microsomes from rats treated with phenobarbital was inhibited by anti-P450 PB-4 antibody.(ABSTRACT TRUNCATED AT 250 WORDS)     

Purification and characterization of two distinct forms of rat adrenal cytochrome P450(11) beta: functional and structural aspects

It is generally accepted that the last three steps of aldosterone biosynthesis are catalyzed by a single enzyme, i.e., cytochrome P450(11) beta (P450XIB). We have previously reported that rat adrenal mitochondria may be capable of producing two forms of P450(11) beta which differ in molecular weight (49 and 51 kDa). In the present study we describe the purification, the enzymatic activities, and some structural properties of these two proteins. Using zona fasciculata mitochondria, the 51-kDa protein was purified to electrophoretic homogeneity by means of octyl-Sepharose chromatography. In a reconstituted system the protein catalyzed 18- and 11 beta-hydroxylation of deoxycorticosterone, but exhibited no 18-hydroxylation or 18-hydroxydehydrogenation of corticosterone. The 49-kDa protein was isolated from zona glomerulosa mitochondria of rats kept on a low-sodium, high-potassium regimen. Using octyl-Sepharose chromatography, it could be separated from the 51-kDa protein. A reconstituted eluate fraction, containing the 49-kDa protein, converted deoxycorticosterone not only to 18-OH-deoxycorticosterone and corticosterone, but also to 18-OH-corticosterone and aldosterone. These findings indicate that the rat adrenal cortex is capable of producing two distinct forms of active cytochrome P450(11) beta. A structural relationship of the 49- and 51-kDa proteins was indicated by experiments involving limited proteolysis. Thus, digestion with alpha-chymotrypsin and V8-protease yielded very similar peptide maps for both proteins. During potassium repletion of potassium-deficient rats, the disappearance of the active 51-kDa protein coincided with the appearance of the 49-kDa protein. These results are suggestive of a post-translational processing mechanism converting the 51-kDa protein into the smaller 49-kDa form. However, the 49-kDa protein might also be encoded by a distinct gene, regulated separately depending on the physiological conditions.