Hydroxylation of testosterone by bacterial cytochromes P450 using the Escherichia coli expression system

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 2alpha-, 2beta-, 6beta-, 7beta-, 11beta-, 12beta-, 15beta-, 16alpha-, 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 2alpha-, 2beta-, 6beta-, 11beta-, 15beta-, 16alpha-, and 17-hydroxylation are reactions common to both human and bacterial P450s. Most of the testosterone hydroxylation catalyzed by bacterial P450s is on the beta face.     

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.     

Biotransformation XXXIX. Metabolism of testosterone, androstenedione, progesterone and testosterone derivatives in Absidia coerulea culture

The strain of Absidia coerulea was used to investigate the transformations of testosterone, androstenedione, progesterone and testosterone derivatives with additional C1–C2 double bond and/or 17-methyl group. All the examined substrates were transformed, mainly hydroxylated. It was found that the position and stereochemistry of the introduced hydroxyl group, as well as the yield of products, depended on the structure of the substrate. The first three substrates (hormones) underwent hydroxylation at C-14, and additional hydroxylation at 7 was observed in progesterone. The presence of the double bond (C1–C2) in 1-dehydrotestosterone did not influence the position of hydroxylation, but the product with additional C14–C15 double bond (at the same site as hydroxylation) was formed. 17-Methyltestosterone was hydroxylated at the 7 position, and also the dehydrogenated product (at the same site, with C6–C7 double bond) was obtained. The testosterone derivative with both C1–C2 double bond and 17-methyl group underwent hydroxylation at the 7 or 11β position, and a little amount of 14, 15 epoxide was formed.     

Human liver microsomal steroid metabolism: identification of the major microsomal steroid hormone 6 beta-hydroxylase cytochrome P-450 enzyme

Cytochrome P-450-dependent steroid hormone metabolism was studied in isolated human liver microsomal fractions. 6 beta hydroxylation was shown to be the major route of NADPH-dependent oxidative metabolism (greater than or equal to 75% of total hydroxylated metabolites) with each of three steroid substrates, testosterone, androstenedione, and progesterone. With testosterone, 2 beta and 15 beta hydroxylation also occurred, proceeding at approximately 10% and 3-4% the rate of microsomal 6 beta hydroxylation, respectively, in each of the liver samples examined. Rates for the three steroid 6 beta-hydroxylase activities were highly correlated with each other (r = 0.95-0.97 for 25 individual microsomal preparations), suggesting that a single human liver P-450 enzyme is the principal microsomal 6 beta-hydroxylase catalyst with all three steroid substrates. Steroid 6 beta-hydroxylase rates correlated well with the specific content of human P-450NF (r = 0.69-0.83) and with its associated nifedipine oxidase activity (r = 0.80), but not with the rates for debrisoquine 4-hydroxylase, phenacetin O-deethylase, or S-mephenytoin 4-hydroxylase activities or the specific contents of their respective associated P-450 forms in these same liver microsomes (r less than 0.2). These correlative observations were supported by the selective inhibition of human liver microsomal 6 beta hydroxylation by antibody raised to either human P-450NF or a rat homolog, P-450 PB-2a. Anti-P-450NF also inhibited human microsomal testosterone 2 beta and 15 beta hydroxylation in parallel to the 6 beta-hydroxylation reaction. This antibody also inhibited rat P-450 2a-dependent steroid hormone 6 beta hydroxylation in uninduced adult male rat liver microsomes but not the steroid 2 alpha, 16 alpha, or 7 alpha hydroxylation reactions catalyzed by other rat P-450 forms. Finally, steroid 6 beta hydroxylation catalyzed by either human or rat liver microsomes was selectively inhibited by NADPH-dependent complexation of the macrolide antibiotic triacetyloleandomycin, a reaction that is characteristic of members of the P-450NF gene subfamily (P-450 IIIA subfamily). These observations establish that P-450NF or a closely related enzyme is the major catalyst of steroid hormone 6 beta hydroxylation in human liver microsomes, and furthermore suggest that steroid 6 beta hydroxylation may provide a useful, noninvasive monitor for the monooxygenase activity of this hepatic P-450 form.     

Transformations of steroids by Beauveria bassiana

The course of transformations of testosterone and its derivatives, including compounds with an additional C1,C2 double bond and/or a 17alpha-methyl group, a 17beta-acetyl group or without a 19-methyl group, by a Beauveria bassiana culture was investigated. The fungi promoted hydroxylation of these compounds at position 11alpha, oxidation of the 17beta-hydroxyl group, reduction of the C1,C2 or C4,C5 double bonds and degradation of the progesterone side-chain, leading to testosterone. The structure of 4-ene-3-oxo-steroids had no influence on regio- and stereochemistry of hydroxylation. In a similar manner, dehydroepiandrosterone was hydroxylated by Beauveria bassiana at position 11alpha, however, a small amount of 7alpha-hydroxylation product was also formed.     

Mechanism of androstenedione formation from testosterone and epitestosterone catalyzed by purified cytochrome P-450b

A purified rat hepatic monooxygenase system containing cytochrome P-450b oxidizes testosterone to androstenedione and 16 alpha- and 16 beta-hydroxytestosterone at approximately equal rates. The metabolism of epitestosterone by the same system is characterized by a marked stereoselectivity in favor of 16 beta-hydroxylation (4- to 5-fold relative to 16 alpha-hydroxylation), formation of 15 alpha-hydroxyepitestosterone, and a rate of androstenedione formation which is three to five times higher than that observed with testosterone. Apparent Km values for 16 alpha- and 16 beta-hydroxylation and androstenedione formation are 20-30 microM with either substrate. Mass spectral analysis of the androstenedione formed from [16,16-2H2]testosterone and [16,16-2H2] epitestosterone indicates essentially complete retention of deuterium, thereby ruling out a mechanism of androstenedione formation via C-16 hydroxylation followed by loss of water and rearrangement. Mass spectral analysis of the C-16 hydroxylation products from incubations of testosterone or epitestosterone in 18O2 shows essentially complete incorporation of 18O (greater than 95%). Androstenedione formed from testosterone is enriched in 18O only 2-fold (5-8%) over background, while the androstenedione formed from epitestosterone shows 84% enrichment. Kinetic experiments utilizing [17-2H]testosterone and [17-2H]epitestosterone as substrates indicate that cleavage of the C-17 carbon-hydrogen bond is involved in a rate-limiting step in the formation of androstenedione from both substrates. Taken together, our results indicate that androstenedione formation from epitestosterone proceeds exclusively through the gem-diol pathway, while androstenedione formation from testosterone may proceed through a combination of gem-diol and dual hydrogen abstraction pathways.     

Testosterone metabolism by microsomal cytochrome P-450 in liver of rats treated with some inducers

1. The stereoselective hydroxylation of testosterone by microsomal cytochrome P-450 and the changes in level of components participated in the microsomal electron transport system were observed in the microsomes induced unique P-450 isozymes. 2. Flavone- and hesperetin-inducible P-450 catalyzed the hydroxylation of testosterone more effectively than other chemicals-inducible ones. 3. The P-450 in all the microsomal preparations tested most rapidly oxidized testosterone to 6 beta-monohydroxy form. 4. Particularly, MC- and BNF-inducible P-450 showed high stereoselectivity on C6-position of testosterone, and PB-, flavone- and hesperetin-inducible one showed that on C2-position of this compound, respectively. 5. This specificity of two flavonoid-inducible P-450 for the formation of 2 alpha- and 2 beta-epimer of monohydroxytestosterone was opposite to each other. 6. The content of P-450 and the activity of NADPH-cytochrome P-450 reductase were high in PB-, MC- and BNF-microsomes, whereas NADH-cytochrome b5 reductase activity was high in two flavonoid-microsomes and the content of cytochrome b5 was not changed except the PB-treated rats. 7. It is suggested that the increasing activities of testosterone hydroxylases in flavonoid-microsomes seems to be closely related to NADH-cytochrome b5 reductase.     

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.     

Cytochrome P450 3A4-catalyzed testosterone 6beta-hydroxylation stereochemistry, kinetic deuterium isotope effects, and rate-limiting steps

Testosterone 6beta-hydroxylation is a prototypic reaction of cytochrome P450 (P450) 3A4, the major human P450. Biomimetic reactions produced a variety of testosterone oxidation products with 6beta-hydroxylation being only a minor reaction, indicating that P450 3A4 has considerable control over the course of steroid hydroxylation because 6beta-hydroxylation is not dominant in a thermodynamically controlled oxidation of the substrate. Several isotopically labeled testosterone substrates were prepared and used to probe the catalytic mechanism of P450 3A4: (i) 2,2,4,6,6-(2)H(5); (ii) 6,6-(2)H(2); (iii) 6alpha-(2)H; (iv) 6beta-(2)H; and (v) 6beta-(3)H testosterone. Only the 6beta-hydrogen was removed by P450 3A4 and not the 6alpha, indicating that P450 3A4 abstracts hydrogen and rebounds oxygen only at the beta face. Analysis of the rates of hydroxylation of 6beta-(1)H-, 6beta-(2)H-, and 6beta-(3)H-labeled testosterone and application of the Northrop method yielded an apparent intrinsic kinetic deuterium isotope effect ((D)k) of 15. The deuterium isotope effects on k(cat) and k(cat)/K(m) in non-competitive reactions were only 2-3. Some "switching" to other hydroxylations occurred because of 6beta-(2)H substitution. The high (D)k value is consistent with an initial hydrogen atom abstraction reaction. Attenuation of the high (D)k in the non-competitive experiments implies that C-H bond breaking is not a dominant rate-limiting step. Considerable attenuation of a high (D)k value was also seen with a slower P450 3A4 reaction, the O-dealkylation of 7-benzyloxyquinoline. Thus P450 3A4 is an enzyme with regioselective flexibility but also considerable regioselectivity and stereoselectivity in product formation, not necessarily dominated by the ease of C-H bond breaking.     

Covalent alteration of the CYP3A4 active site: evidence for multiple substrate binding domains.

The inhibition of CYP3A4-mediated oxidation of triazolam and testosterone was assessed in the presence of a selection of known CYP3A4 substrates and inhibitors. Under experimental conditions where the Michaelis-Menten model predicts substrate-independent inhibition ([S] = K(m)), results yielded substrate-dependent inhibition. Moreover, when the same experimental design was extended to a group of structurally similar flavonoids it was observed that flavanone, flavone, 3-hydroxyflavone, and 6-hydroxyflavone (10 microM) activated triazolam metabolism, but inhibited testosterone hydroxylation. In additional studies, residual CYP3A4 activity toward testosterone and triazolam hydroxylation was measured after pretreatment with the CYP3A4 mechanism based inhibitor, midazolam. After midazolam preincubation, CYP3A4 6 beta-hydroxylase activity was reduced by 47% while, in contrast, triazolam hydroxylation was reduced by 75%. These results provide physical evidence, which supports the hypothesis that the active site of CYP3A4 contains spatially distinct substrate-binding domains within the enzyme active site.     

Testosterone oxidation by rat liver microsomes: Effects of phenobarbital pretreatment and the detection of seven metabolites by HPLC

The oxidation products of testosterone catalyzed by microsomes from untreated and phenobarbital pretreated adult male rats have been analyzed by reverse-phase high performance liquid chromatography (HPLC). The major products formed by control microsomes are 2α- and 16α-hydroxytestosterone followed by and drostenedione, 6β- and 7α- and negligible quantities of 2β- and 16β-hydroxytestosterone. The hydroxylation of testosterone at carbon-2 yields mainly 2α- and not 2β-hydroxytestosterone. Pretreatment with phenobarbital resulted in a qualitatively similar but quantitatively different metabolite pattern. Specifically, the formation of 2β-, 6β-, 7α- and 16β-hydroxytestosterone is increased whereas that of 2α- and 16α-hydroxytestosterone is decreased.     

The importance of SRS-1 residues in catalytic specificity of human cytochrome P450 3A4

The structural basis for the regioselective hydroxylation of Delta-4-3-ketosteroids by human CYP3A4 was investigated. Prior studies had suggested that the chemical reactivity of the allylic 6beta-position might have a greater influence than steric constraints by the enzyme. Six highly conserved CYP3A residues from substrate recognition site 1 were examined by site-directed mutagenesis. F102A and A117L showed no spectrally detectable P450. V101G and T103A exhibited a wild-type progesterone metabolite profile. Of five mutants at residue N104, only N104D yielded holoenzyme and exhibited the same steroid metabolite profile as wild-type. Of four mutants at position S119 (A, L, T, V), the three hydrophobic ones produced 2beta-OH rather than 6beta-OH progesterone or testosterone as the major metabolite. Kinetic analysis showed S(50) values similar to wild-type for S119A (progesterone) and S119V (testosterone), whereas the V(max) values for 2beta-hydroxysteroid formation were increased in both cases. All four mutants exhibited an altered product profile for 7-hexoxycoumarin side-chain hydroxylation, whereas the stimulation of steroid hydroxylation by alpha-naphthoflavone was similar to the wild-type. The results indicate that the highly conserved residue S119 is a key determinant of CYP3A4 specificity and reveal an important role of the active site topology in steroid 6beta-hydroxylation.     

Mechanistic studies with N-benzyl-1-aminobenzotriazole-inactivated CYP2B1: differential effects on the metabolism of 7-ethoxy-4-(trifluoromethyl)coumarin, testosterone, and benzphetamine

Mechanistic studies with N-benzyl-1-aminobenzotriazole (BBT)-inactivated cytochrome P450 2B1 were conducted to determine which step(s) in the reaction cycle had been compromised. Stopped-flow studies, formation of the oxy-ferro intermediate, and analysis of products suggested that the reductive process was slower with the BBT-modified enzyme. The reduced rate of reduction alone could not account for the loss in 7-ethoxy-4-(trifluoromethyl)coumarin (EFC) O-deethylation or testosterone hydroxylation activity. Surprisingly, the ability of the BBT-modified enzyme to generate formaldehyde from benzphetamine was much less affected. Benzphetamine metabolite analysis by electrospray ionization-mass spectrometry showed that the BBT-modified enzyme had a slightly greater propensity towards aromatic hydroxylation together with reduced levels of N-demethylation and little change in the N-debenzylation of benzphetamine. Orientation of substrates within the active site of the BBT-inactivated enzyme may be affected such that the more flexible benzphetamine can be metabolized, whereas metabolism of rigid, planar molecules such as EFC and testosterone is hindered.     

The N-terminus of the Qcr7 protein of the cytochrome bc(1) complex in S. cerevisiae may be involved in facilitating stability of the subcomplex with the Qcr8 protein and cytochrome b

The role of the hydrophobic membrane-binding segments of NADPH-cytochrome P450 reductase (CPR) and cytochrome b(5) remain undefined. We have expressed four different recombinant flavocytochromes containing b(5) linked to CPR with different hydrophobic segments as linkers. These fusion proteins have been expressed in Escherichia coli and purified and some of their physical properties and electron transfer activities described in the accompanying paper. Of interest is the presence of internal "membrane-binding" hydrophobic segments in these flavocytochromes. This paper describes the ability of these flavocytochromes to reconstitute in vitro two P450 activities that have been reported to be stimulated by the addition of b(5) (the 17,20-lyase activity of CYP17A and the 6 beta hydroxylation of testosterone catalyzed by CYP3A4) and two P450 reactions that do not respond to the presence of b(5) (the 17 alpha-hydroxylation of progesterone catalyzed by CYP17A and the omega hydroxylation of lauric acid catalyzed by CYP4A1). The present study shows that a hydrophobic "membrane-binding" segment must be present in the artificial flavocytochromes in order to successfully reconstitute in vitro hydroxylation activities with P450s. Differences in the effectiveness of the different flavocytochromes to reconstitute enzymatic activities depends on the P450 tested and the nature of the hydrophobic linker segment present in the purified recombinant flavocytochromes. The hypothesis is proposed that differences in the surface topology of a P450 may dictate differences in their docking with the CPR or b(5) component of a fusion protein, resulting in differences in the rates of electron transfer to the P450.     

Active site substitution A82W improves the regioselectivity of steroid hydroxylation by cytochrome P450 BM3 mutants as rationalized by spin relaxation nuclear magnetic resonance studies

Cytochrome P450 BM3 from Bacillus megaterium is a monooxygenase with great potential for biotechnological applications. In this paper, we present engineered drug-metabolizing P450 BM3 mutants as a novel tool for regioselective hydroxylation of steroids at position 16β. In particular, we show that by replacing alanine at position 82 with a tryptophan in P450 BM3 mutants M01 and M11, the selectivity toward 16β-hydroxylation for both testosterone and norethisterone was strongly increased. The A82W mutation led to a ≤42-fold increase in V(max) for 16β-hydroxylation of these steroids. Moreover, this mutation improves the coupling efficiency of the enzyme, which might be explained by a more efficient exclusion of water from the active site. The substrate affinity for testosterone increased at least 9-fold in M11 with tryptophan at position 82. A change in the orientation of testosterone in the M11 A82W mutant as compared to the orientation in M11 was observed by T(1) paramagnetic relaxation nuclear magnetic resonance. Testosterone is oriented in M11 with both the A- and D-ring protons closest to the heme iron. Substituting alanine at position 82 with tryptophan results in increased A-ring proton-iron distances, consistent with the relative decrease in the level of A-ring hydroxylation at position 2β.     

Improved sample preparation for the testosterone hydroxylation assay using disposable extraction columns

The preparation of samples for injection into a high-performance liquid chromatography from assay mixtures for the determination of cytochrome P-450-dependent testosterone hydroxylation has been substantially facilitated. By replacing the multiple cumbersome extraction steps of the conventional method with a single column extraction the time for sample preparation was reduced from hours to minutes. The new procedure also yields better recoveries for most of the testosterone metabolites than the original protocol. The use of extraction columns for sample preparation allows the simultaneous treatment of a large number of samples or even the automation of the whole assay procedure. The modified procedure is a straightforward, easy-to-perform method that should greatly facilitate the implementation of the testosterone hydroxylation assay for sharply discriminating between many individual cytochrome P-450 species in routine enzyme diagnostics.     

Mechanism of "uncoupled" tetrahydropterin oxidation by phenylalanine hydroxylase

Phenylalanine hydroxylase can catalyze the oxidation of its tetrahydropterin cofactor without concomitant substrate hydroxylation. We now report that this "uncoupled" tetrahydropterin oxidation is mechanistically distinct from normal enzyme turnover. Tetrahydropterins are oxygenated to 4a-carbinolamines only during catalytic events involving substrate hydroxylation. In the absence of hydroxylation tetrahydropterins are oxidized directly to quinonoid dihydropterins. Stoichiometry studies define a ratio of two tetrahydropterins oxidized per O2 consumed in uncoupled enzyme turnover, thus indicating the complete reduction of O2 to H2O. Complementary results establish the lack of H2O2 production by the enzyme when uncoupled and define a tetrahydropterin oxidase activity for the enzyme. Thus, the hydroxylating intermediate of phenylalanine hydroxylase may be discharged in two ways, by substrate hydroxylation or by electron abstraction. A mechanism is proposed for the uncoupled oxidation of tetrahydropterins by phenylalanine hydroxylase, and the significance of these findings is discussed.     

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.     

Sequence requirements for cytochromes P450IIA1 and P450IIA2 catalytic activity: evidence for both specific and non-specific substrate binding interactions through use of chimeric cDNAs and cDNA expression

Cytochrome P450s IIA1 and IIA2, encoded by the CYP2A1 and CYP2A2 genes, display 88% amino acid sequence similarities. The dissimilarities of sequence between these two enzymes are primarily localized within four discrete regions of the polypeptides that are separated by regions of absolute sequence identity. IIA1 specifically hydroxylates the prototype substrate testosterone at the 7 alpha and 6 alpha position with a predominance of 7 alpha metabolite. IIA2, on the other hand, hydroxylates this steroid at eight positions on the molecule, with one of the most abundant metabolites being 15 alpha-hydroxytestosterone. To determine those amino acids responsible for the difference in testosterone hydroxylation specificities, chimeras were constructed between IIA1 and IIA2 cDNAs and expressed in cell culture using vaccinia-virus-mediated cDNA expression. Chimeras, in which the first 355 amino acids correspond to a single enzyme, maintain the specificity associated with that enzyme. Of six chimeras which have substitutions between amino acids 161 and 276, two are inactive and the remaining four give similar metabolite profiles, in which both 7 alpha and 15 alpha hydroxylation specificities have been lost. Two of these four chimeras are diametric apposites, suggesting that modification of either the N-terminal or central regions of the enzymes results in conformational changes that prevent the specific binding interactions responsible for the narrow regioselectivity associated with IIA1 and 15 alpha-hydroxytestosterone formation associated with IIA2.     

Decrease in the levels of a constitutive cytochrome P-450 (RLM5) in hepatic microsomes of diabetic rats

Cytochrome P-450 dependent hydroxylation of testosterone has been measured in hepatic microsomes of control, diabetic and insulin-treated diabetic rats. The observed decrease in testosterone 16 alpha-hydroxylase activity in diabetes, an activity previously shown to be largely due to RLM5, was accompanied by a dramatic decrease in immunodetectable RLM5. Diabetic rats which received insulin had elevated testosterone 16 alpha-hydroxylase activity relative to the diabetic animals, which was accompanied by a corresponding increase in the levels of RLM5. These results provide evidence that specific constitutive cytochrome P-450 enzymes are altered in the diabetic state and that these changes are not permanent since they can be overcome, at least partially, by insulin replacement therapy.