Microbial transformations of steroids--XII. Progesterone hydroxylation profiles are modulated by post-translational modification of an electron transfer protein in Streptomyces roseochromogenes

When Streptomyces roseochromogenes strain 10984 was incubated with exogenous progesterone for 25 h the major monohydroxylated metabolite, 16alpha-hydroxyprogesterone was produced in 3.6 fold excess to the minor metabolite 2beta,16alpha-dihydroxyprogesterone. In a reconstituted system containing highly purified progesterone 16alpha-hydroxylase cytochrome P-450, and electron transfer proteins ferredoxin-like redoxin (roseoredoxin) and redoxin reductase (roseoredoxin reductase), both metabolites were produced but in a 10:1 ratio. When S. roseochromogenes was pre-incubated for 8 h with 0.32 mM progesterone and the purified components of the hydroxylase system incubated as before, the ratio of 16alpha-hydroxyprogesterone to 2beta,16alpha-dihydroxyprogesterone produced decreased to 2.8:1, virtually identical to the ratio in whole cell transformations. Reconstitution assays containing all combinations of hydroxylase proteins purified from progesterone pre-incubated and control cells showed that the roseoredoxin was solely responsible for the observed changes in in vitro metabolite ratios. The fact that the lower 16alpha-hydroxyprogesterone to 2beta,16alpha-dihydroxyprogesterone ratio was also obtained when S. roseochromogenes was exposed to 0.335 mM cycloheximide for 8 h prior to the progesterone pre-incubation, pointed to post-translation modification of the roseoredoxin. Separation of two isoforms of roseoredoxin by isoelectric focusing supported this proposition.     

Two catalytically distinct subforms of cytochrome P-450 3b as obtained from inbred rabbits

Cytochrome P-450 3b has been shown previously to exist in one of two catalytically and structurally distinct forms. Preparations of P-450 3b obtained from outbred New Zealand White rabbits exhibit both high-efficiency (Vmax/Km) progesterone 6 beta- and 16 alpha-hydroxylases and a low-efficiency 16 alpha-hydroxylase. In contrast, P-450 3b prepared from a genetically defined strain of rabbits, IIIVO/J, does not display the high-efficiency 6 beta- and 16 alpha-hydroxylase activities. This appears to reflect the inheritance of one of two catalytically distinct subforms of P-450 3b. In the present study, we provide information with respect to the characterization of these progesterone hydroxylases as they occur in two highly inbred strains of rabbits, B/J and III/J. The identification of these strains as sources of these subforms was achieved by utilizing a monoclonal antibody to P-450 3b that produced a distinct pattern of inhibition for each phenotype. The functional and structural attributes of these subforms of P-450 3b indicate that whereas only the low-efficiency 16 alpha-hydroxylase is expressed in B/J rabbits, both of the catalytically distinct subforms of P-450 3b are expressed in the III/J rabbits. Thus, it is unlikely that these enzymic variants reflect allomorphic forms of P-450 3b.     

Modulation of reconstituted cholesterol 7 alpha-hydroxylase by phosphatase and protein kinase

Cholesterol 7 alpha-hydroxylase activity was completely inhibited by incubation with alkaline phosphatase in a reconstituted enzyme system containing a cytochrome P-450, NADPH-cytochrome P-450 reductase and phospholipid. On the other hand, cAMP-dependent protein kinase stimulated cholesterol 7 alpha-hydroxylase activity by 2.5-fold. The modulation of cholesterol 7 alpha-hydroxylase activity was dependent on the amount of phosphatase or kinase added. The phosphatase inhibited enzyme activity was partially reversed by the treatment with protein kinase. These experiments indicate that the reconstituted cholesterol 7 alpha-hydroxylase activity is reversibly regulated by phosphorylation/dephosphorylation mechanism.     

Selective inactivation by 21-chlorinated steroids of rabbit liver and adrenal microsomal cytochromes P-450 involved in progesterone hydroxylation

The inactivation by 21-chlorinated steroids of rabbit liver cytochromes P-450 involved in the hydroxylation of progesterone has been investigated in intact microsomes encompassing two phenotypes of 21-hydroxylase activity, two phenotypes of 16 alpha-hydroxylase activity, and three phenotypes of 6 beta-hydroxylase activity. In liver microsomes from outbred New Zealand White male rabbits exhibiting a high content of cytochrome P-450 1, 21,21-dichloropregnenolone caused a time- and NADPH-dependent loss of 21-hydroxylase activity. This loss of activity exhibited a number of characteristics of mechanism-based inactivation, including irreversibility, saturation with increasing inhibitor concentrations, and protection by substrate, and was also documented with purified P-450 1 in a reconstituted system. 21,21-Dichloropregnenolone caused no time-dependent loss of 6 beta-hydroxylase activity in microsomes from the New Zealand White rabbits or from control or rifampicin-treated rabbits of the inbred B/J strain. In contrast, in the microsomes from the B/J rabbits, some inactivation of the 16 alpha-hydroxylase was observed (k = 0.04 min-1), regardless of the rifampicin treatment. The other two compounds tested, 21-chloropregnenolone and 21,21-dichloroprogesterone, were less effective than the dichloropregnenolone as inactivators of cytochrome P-450 1. On the other hand, 21,21-dichloroprogesterone, but not 21,21-dichloropregneolone, caused a rapid time-dependent loss of 21-hydroxylase activity in rabbit adrenal microsomes. The results indicate that the introduction of a dichloromethyl group into a substrate bearing a methyl group normally hydroxylated by only one or a few forms of cytochrome P-450 may be a rational means of designing selective inhibitors of the enzyme.     

Participation of two structurally related enzymes in rat hepatic microsomal androstenedione 7 alpha-hydroxylation.

Rat hepatic cytochrome P-450 form 3 (testosterone 7 alpha-hydroxylase; P-450 gene IIA1) and P-450 form RLM2 (testosterone 15 alpha-hydroxylase; P-450 gene IIA2) are 88% identical in primary structure, yet they hydroxylate testosterone with distinct and apparently unrelated regioselectivities. In this study, androstenedione and progesterone were used to assess the regioselectivity and stereospecificity of these two P-450 enzymes towards other steroid substrates. Although P-450 RLM2 exhibited low 7 alpha-hydroxylase activity with testosterone or progesterone as substrate (turnover number less than or equal to 1-2 nmol of metabolite/min per nmol of P-450), it did catalyse androstenedione 7 alpha-hydroxylation at a high rate (21 min-1) which exceeded that of P-450 3 (7 min-1). However, whereas P-450 3 exhibited a high specificity for hydroxylation of these steroids at the 7 alpha position (95-97% of total activity), P-450 RLM2 actively metabolized these compounds at four or more major sites including the nearby C-15 position, which dominated in the case of testosterone and progesterone. The observation that androstenedione is actively 7 alpha-hydroxylated by purified P-450 RLM2 suggested that this P-450 enzyme might make significant contributions to microsomal androstenedione 7 alpha-hydroxylation, an activity that was previously reported to be associated with immunoreactive P-450 3. Antibody inhibition experiments were therefore carried out in liver microsomes using polyclonal anti-(P-450 3) antibodies which cross-react with P-450 RLM2, and using a monoclonal antibody that is reactive with and inhibitory towards P-450 3 but not P-450 RLM2. P-450 3 was thus shown to catalyse only around 35% of the total androstenedione 7 alpha-hydroxylase activity in uninduced adult male rat liver microsomes, with the balance attributed to P-450 RLM2. The P-450-3-dependent 7 alpha-hydroxylase activity was increased to approximately 65% of the total in phenobarbital-induced adult male microsomes, and to greater than 90% of the total in untreated adult female rat liver microsomes. These observations are consistent with the inducibility of P-450 3 by phenobarbital and with the absence of P-450 RLM2 from adult female rat liver respectively. These findings establish that P-450 RLM2 and P-450 3 can both contribute significantly to microsomal androstenedione 7 alpha-hydroxylation, thus demonstrating that the 7 alpha-hydroxylation of this androgen does not serve as a specific catalytic monitor for microsomal P-450 3.     

Interaction between cytochrome P-450 (P-450C21) and NADPH-cytochrome P-450 reductase from adrenocortical microsomes in a reconstituted system

The interaction between P-450C21 and NADPH-cytochrome P-450 reductase, both purified from bovine adrenocortical microsomes, has been investigated in a reconstituted system with a nonionic detergent, Emulgen 913, by kinetic analysis and gel filtrations. Steady state kinetic data in progesterone 21-hydroxylation showed formation of an equimolar complex between the two enzyme proteins at low Emulgen concentration. Steady state kinetic studies on the electron transfer from NADPH to P-450C21 via the reductase showed that a stable complex formation between the two enzyme proteins was not involved in the steady state electron transfer at high Emulgen concentration. In stopped flow experiments, a time course of the P-450C21 reduction showed biphasic kinetics composed of fast and slow phases. The dependence of kinetic parameters on Emulgen concentration indicates that the fast phase corresponds to the electron transfer within the complex and the slow phase to the electron transfer through a random collision between P-450C21 and the reductase. The stable complex formation between P-450C21 and the reductase has been clearly demonstrated by gel filtration. The stable complex was composed of several molecules of the two enzyme proteins at an equimolar ratio, which was active for progesterone 21-hydroxylation and had a tendency to dissociate at high Emulgen concentration.     

Inactivation of rat liver microsomal steroid hydroxylations by 4-alkyl analogues of 3,5-diethoxycarbonyl-1,4-dihydro-2,4,6-trimethylpyridine: evidence for selectivity among steroid-inducible cytochrome P450IIIA forms

Various 4-alkyl analogues of 3,5-diethoxycarbonyl-1,4-dihydro-2,4,6- trimethylpyridine (DDC) cause mechanism-based inactivation of cytochrome P-450 (P-450) via destruction of the heme prosthetic group. This is an important component of these compounds' porphyrinogenic mechanism. In an attempt to map the P-450 isozyme selectivities of DDC analogues, we have examined the effects of these compounds on the regioselective and stereoselective hydroxylation of androstenedione (AD) and progesterone (PG) in rat liver microsomal systems. In microsomes from phenobarbital-treated male rats, DDC analogues did not cause time-dependent inactivation of AD 7 alpha-hydroxylase, AD 16 beta-hydroxylase, and PG 21-hydroxylase, selective markers for P450IIA 1/2, IIB1, and IIC6, respectively. In contrast, DDC analogues were effective inactivators of PG 2 alpha-hydroxylase and steroid 6 beta-hydroxylases, selective markers for P450IIC11 and IIIA forms, respectively. We conclude that differences in porphyrinogenicity observed with various DDC analogues are not likely to be due to the selective destruction of different P-450 isozymes by different analogues, but rather to properties of the DDC analogues themselves. 4-Ethyl DDC was found to be capable of discriminating between P450IIIA subfamily forms. In microsomes from untreated male rats, which express P450IIIA2 but not IIIA1, 4-ethyl DDC inactivated both AD and PG 6 beta-hydroxylases. However, in microsomes from dexamethasone-treated female rats, which express P450IIIA1 but not IIIA2, no inactivation of the steroid 6 beta-hydroxylases was observed. Thus, 4-ethyl DDC appears to be a potentially valuable tool for differentiating between P450IIIA forms.     

Selective reactivation of steroid hydroxylases following dissociation of the isosafrole metabolite complex with rat hepatic cytochrome P-450

In order to elucidate the isozyme specificity of complex formation between cytochrome P-450 and the isosafrole metabolite the effect of complex dissociation on different steroid hydroxylation pathways was studied in hepatic microsomal fractions. Isosafrole induction was found to increase the 16 beta- and 7 alpha-hydroxylation of androst-4-ene-3,17-dione approximately 2.8- and 1.7-fold, respectively, whereas the 16 alpha-hydroxylation pathway was decreased to about one-quarter of control activity; 6 beta-hydroxylation was unchanged from control activity. More striking changes were apparent following dissociation of the isosafrole metabolite from its complex with ferricytochrome P-450 by the steroid substrate. Thus an approximate fourfold elevation of 16 beta-hydroxylase activity was observed after displacement and 6 beta-hydroxylation increased about twofold; 7 alpha-hydroxylase activity was decreased to 0.75-fold of undisplaced activity and 16 alpha-hydroxylase activity was unchanged. These data provide convincing evidence that at least two forms of phenobarbital-inducible cytochrome P-450 (cytochromes P-450PB-B and P-450PB/PCN-E) are present to some extent in a catalytically inactive complexed state in isosafrole-induced rat hepatic microsomes. Furthermore, there is now evidence to suggest that the constitutive isozymes cytochrome P-450UT-A and cytochrome P-450UT-F are not complexed to any degree in hepatic microsomes from isosafrole-induced rats.     

Electron transport pathway for a Streptomyces cytochrome P450: cytochrome P450 105D5-catalyzed fatty acid hydroxylation in Streptomyces coelicolor A3(2)

Streptomyces and other bacterial actinomycete species produce many important natural products, including the majority of known antibiotics, and cytochrome P450 (P450) enzymes catalyze important biosynthetic steps. Relatively few electron transport pathways to P450s have been characterized in bacteria, particularly streptomycete species. One of the 18 P450s in Streptomyces coelicolor A3(2), P450 105D5, was found to bind fatty acids tightly and form hydroxylated products when electrons were delivered from heterologous systems. The six ferredoxin (Fdx) and four flavoprotein Fdx reductase (FDR) proteins coded by genes in S. coelicolor were expressed in Escherichia coli, purified, and used to characterize the electron transfer pathway. Of the many possibilities, the primary pathway was NADH --> FDR1 --> Fdx4 --> P450 105D5. The genes coding for FDR1, Fdx4, and P450 105D5 are located close together in the S. coelicolor genome. Several fatty acids examined were substrates, including those found in S. coelicolor extracts, and all yielded several products. Mass spectra of the products of lauric acid imply the 8-, 9-, 10-, and 11-hydroxy derivatives. Hydroxylated fatty acids were also detected in vivo in S. coelicolor. Rates of electron transfer between the proteins were measured; all steps were faster than overall hydroxylation and consistent with rates of NADH oxidation. Substrate binding, product release, and oxygen binding were relatively fast in the catalytic cycle; high kinetic deuterium isotope effects for all four lauric acid hydroxylations indicated that the rate of C-H bond breaking is rate-limiting in every case. Thus, an electron transfer pathway to a functional Streptomyces P450 has been established.     

Radiometric assay for cytochrome P-450-catalyzed progesterone 16 alpha-hydroxylation and determination of an apparent isotope effect

In the course of studies on the oxygenation of steroids by purified P-450 cytochromes, particularly rabbit liver microsomal cytochrome P-450 form 3b, a rapid and reliable radiometric assay has been devised for progesterone 16 alpha-hydroxylation. In view of the lack of a commercially available, suitably tritiated substrate, [1,2,6,7,16,17-3H]progesterone was treated with alkali to remove the label from potential hydroxylation sites other than the 16 alpha position. The resulting [1,7,16-3H]progesterone was added to a reconstituted enzyme system containing cytochrome P-450 form 3b, NADPH-cytochrome P-450 reductase, and NADPH, and the rate of 16 alpha-hydroxylation was measured by the formation of 3H2O. This reaction was shown to be linear with respect to time and to the cytochrome P-450 concentration. An apparent tritium isotope effect of 2.1 was observed by comparison of the rates of formation of tritium oxide and 16 alpha-hydroxyprogesterone, and the magnitude of the isotope effect was confirmed by an isotope competition assay in which a mixture of [1,7,16-3H]progesterone and [4-14C]progesterone was employed.     

A recombinant Escherichia coli whole cell biocatalyst harboring a cytochrome P450cam monooxygenase system coupled with enzymatic cofactor regeneration

A cytochrome P450cam monooxygenase (P450cam) system from the soil bacterium Pseudomonas putida requires electron transfer among three different proteins and a cofactor, nicotinamide adenine dinucleotide (NADH), for oxygenation of its natural substrate, camphor. Herein, we report a facile way to significantly enhance the catalytic efficiency of the P450cam system by the coupling of its native electron transfer system with enzymatic NADH regeneration catalyzed by glycerol dehydrogenase (GLD) in Escherichia coli whole cell biocatalysts. Recombinant E. coli harboring the P450cam system, but lacking GLD, exhibited little activity for camphor hydroxylation. In contrast, coexpression of GLD with the proteinaceous electron transfer components of P450cam resulted in about tenfold improvement in the substrate conversion, implying that the whole cell biocatalyst utilized molecular oxygen, endogenous NADH, and glycerol in the cell for catalysis. The addition of glycerol to the reaction media further promoted camphor hydroxylation, suggesting that exogenous glycerol is also available for GLD in the host cell and actively participates in the catalytic cycle. These results clearly show the utility of GLD towards functional reconstruction of the native P450cam system. The present approach may also be useful for E. coli whole cell biocatalysts with the other NADH-dependent oxygenases and oxidoreductases.     

P-450 HFLa, a form of cytochrome P-450 purified from human fetal livers, is the 16 alpha-hydroxylase of dehydroepiandrosterone 3-sulfate

In a reconstituted system containing NADPH, dilauroyl-L-3-phosphatidylcholine, and NADPH-cytochrome P-450 reductase purified from rat liver microsomes, cytochrome P-450 (P-450 HFLa) purified from human fetal livers catalyzed the 16 alpha-hydroxylation of dehydroepiandrosterone 3-sulfate (DHEA-sulfate). Addition of cytochrome b5 purified from rat liver microsomes to the reconstituted system resulted in a remarkable increase in the hydroxylase activity. The level of P-450 HFLa in liver homogenates from human fetuses highly correlated with the activity of DHEA-sulfate 16 alpha-hydroxylase. Antibodies to P-450 HFLa inhibited the 16 alpha-hydroxylation of DHEA-sulfate in a dose-dependent manner. The NH2-terminal amino acid sequence of P-450 HFLa was similar to that of P-450NF (Beaune, P. H., Umbenhauer, D. R., Bork, R. W., Lloyd, R. S., and Guengerich, F. P. (1986) Proc. Natl. Acad. Sci. U. S. A. 83, 8064-8068). We conclude that P-450 HFLa is a form of cytochrome P-450 involved in the 16 alpha-hydroxylation of DHEA-sulfate.     

Regioselective progesterone hydroxylation catalyzed by eleven rat hepatic cytochrome P-450 isozymes

Quantitative high-pressure liquid chromatographic assays were developed that separate progesterone and 17 authentic monohydroxylated derivatives. The assays were utilized to investigate the hydroxylation of progesterone by 11 purified rat hepatic cytochrome P-450 isozymes and 8 different rat hepatic microsomal preparations. In a reconstituted system, progesterone was most efficiently metabolized by cytochrome P-450h followed by P-450g and P-450b. Seven different monohydroxylated progesterone metabolites were identified. 16 alpha-Hydroxyprogesterone, formed by 8 of the 11 isozymes, was the only detectable metabolite formed by cytochromes P-450b and P-450e. 2 alpha-Hydroxyprogesterone was formed almost exclusively by cytochrome P-450h, and 6 alpha-hydroxyprogesterone and 7 alpha-hydroxyprogesterone were only formed by P-450a. 6 beta-hydroxylation of progesterone was catalyzed by four isozymes with cytochrome P-450g being the most efficient, and 15 alpha-hydroxyprogesterone was formed as a minor metabolite by cytochromes P-450g, P-450h, and P-450i. None of the isozymes catalyzed 17 alpha-hydroxylation of progesterone, and only cytochrome P-450k had detectable 21-hydroxylase activity. 16 alpha-Hydroxylation catalyzed by cytochrome P-450b was inhibited in the presence of dilauroylphosphatidylcholine (1.6-80 microM), while this phospholipid either stimulated (up to 3-fold) or had no effect on the metabolism of progesterone by the other purified isozymes. Results of microsomal metabolism in conjunction with antibody inhibition experiments indicated that cytochromes P-450a and P-450h were the sole 7 alpha- and 2 alpha-hydroxylases, respectively, and that P-450k or an immunochemically related isozyme contributed greater than 80% of the 21-hydroxylase activity observed in microsomes from phenobarbital-induced rats.     

Studies on the rate-determining factor in testosterone hydroxylation by rat liver microsomal cytochrome P-450: evidence against cytochrome P-450 isozyme:isozyme interactions

The aim of the present study was to examine a recent proposal that inhibitory isozyme:isozyme interactions explain why membrane-bound isozymes of rat liver microsomal cytochrome P-450 exert only a fraction of the catalytic activity they express when purified and reconstituted with saturating amounts of NADPH-cytochrome P-450 reductase and optimal amounts of dilauroylphosphatidylcholine. The different pathways of testosterone hydroxylation catalyzed by cytochromes P-450a (7 alpha-hydroxylation), P-450b (16 beta-hydroxylation), and P-450c (6 beta-hydroxylation) enabled possible inhibitory interactions between these isozymes to be investigated simultaneously with a single substrate. No loss of catalytic activity was observed when purified cytochromes P-450a, P-450b, or P-450c were reconstituted in binary or ternary mixtures under a variety of incubation conditions. When purified cytochromes P-450a, P-450b, and P-450c were reconstituted under conditions that mimicked a microsomal system (with respect to the absolute concentration of both the individual cytochrome P-450 isozyme and NADPH-cytochrome P-450 reductase), their catalytic activity was actually less (69-81%) than that of the microsomal isozymes. These results established that cytochromes P-450a, P-450b, and P-450c were not inhibited by each other, nor by any of the other isozymes in the liver microsomal preparation. Incorporation of purified NADPH-cytochrome P-450 reductase into liver microsomes from Aroclor 1254-induced rats stimulated the catalytic activity of cytochromes P-450a, P-450b, and P-450c. Similarly, purified cytochromes P-450a, P-450b, and P-450c expressed increased catalytic activity in a reconstituted system only when the ratio of NADPH-cytochrome P-450 reductase to cytochrome P-450 exceeded that normally found in liver microsomes. These results indicate that the inhibitory cytochrome P-450 isozyme:isozyme interactions described for warfarin hydroxylation were not observed when testosterone was the substrate. In addition to establishing that inhibitory interactions between different cytochrome P-450 isozymes is not a general phenomenon, the results of the present study support a simple mass action model for the interaction between membrane-bound or purified cytochrome P-450 and NADPH-cytochrome P-450 reductase during the hydroxylation of testosterone.     

Androgen hydroxylation catalysed by a cell line (SD1) that stably expresses rat hepatic cytochrome P-450 PB-4 (IIB1).

Androgen hydroxylation catalysed by Chinese hamster fibroblast SD1 cells, which stably express cytochrome P-450 form PB-4, the rat P450IIB1 gene product, was assessed and compared to that catalysed by purified cytochrome P-450 PB-4 isolated from rat liver. SD1 cell homogenates catalysed the NADPH-dependent hydroxylation of androstenedione and testosterone with a regioselectivity very similar to that purified by P-450 PB-4 (16 beta-hydroxylation/16 alpha-hydroxylation = 6.0-6.8 for androstenedione; 16 beta/16 alpha = 0.9 for testosterone). Homogenates prepared from the parental cell line V79, which does not express detectable levels of P-450 PB-4 or any other cytochrome P-450, exhibited no androgen 16 beta- or 16 alpha-hydroxylase activity. The hydroxylase activities catalysed by the SD1 cell homogenate were selectively and quantitatively inhibited (greater than 90%) by a monoclonal antibody to P-450 PB-4 at a level of antibody (40 pmol of antibody binding sites/mg of SD1 homogenate) that closely corresponds to the P-450 PB-4 content of the cells (48 pmol of PB-4/mg of SD1 homogenate). Fractionation of cell homogenates into cytosol and microsomes revealed that the P-450 PB-4-mediated activities are associated with the membrane fraction. Although the P-450 PB-4-specific content of the SD1 microsomes was 15% of that present in phenobarbital-induced rat liver microsomes, the P-450 PB-4-dependent androstenedione 16 beta-hydroxylase activity of the SD1 membrane fraction was only 2-3% of that present in the liver microsomes. This activity could be stimulated several-fold, however, by supplementation of SD1 microsomes with purified rat NADPH P-450 reductase. These studies establish that a single P-450 gene product (IIB1) can account for the hydroxylation of androgen substrates at multiple sites, and suggest that SD1 cells can be used to assess the catalytic specificity of P-450 PB-4 with other substrates as well.     

Levels of messenger ribonucleic acid encoding cholesterol side-chain cleavage cytochrome P-450, 17 alpha-hydroxylase cytochrome P-450, adrenodoxin, and low density lipoprotein receptor in bovine follicles and corpora lutea throughout the ovarian cycle

To investigate the molecular basis for the pattern of ovarian steroid production during the bovine estrous cycle, the relative levels of mRNA specific for cholesterol side-chain cleavage cytochrome P-450, 17 alpha-hydroxylase cytochrome P-450, adrenodoxin, and low density lipoprotein receptor were determined in ovarian antral follicles of differing size (less than 3-18 mm) and corpora lutea from the early, early-mid, late-mid, and regressionary stages. Total and poly(A)+ RNA was size-fractionated on agarose-formaldehyde gels, transferred to nylon filters and hybridized to specific 32P-labeled probes. The levels of mRNAs for the rate-limiting enzymes in the conversion of cholesterol into progesterone, namely cholesterol side-chain cleavage cytochrome P-450 and its electron donor, adrenodoxin, were higher in corpora lutea than in follicles. Conversely the levels of mRNA specific for the key regulatory enzyme in the conversion of pregnenolone or progesterone to androgen, namely 17 alpha-hydroxylase cytochrome P-450, were high in all antral follicles examined but were low in young corpora lutea and undetectable in more mature corpora lutea. Low density lipoprotein receptor mRNA was detectable in antral follicles and corpora lutea but the levels were greater in corpora lutea. These results suggest that the pattern of changes in steroid hormone biosynthesis during the bovine estrous cycle and in the ovarian content of steroidogenic enzymes is related to and probably dependent upon the pattern of change in levels of mRNAs for steroidogenic enzymes and related proteins.     

Chlorzoxazone hydroxylation in microsomes and hepatocytes from cytochrome P450 oxidoreductase‐null mice

Previous studies have demonstrated that the NADH‐dependent cytochrome b₅ electron transfer pathway can support some cytochrome P450 monooxygenases in vitro in the absence of their normal redox partner, NADPH‐cytochrome P450 oxidoreductase. However, the ability of this pathway to support P450 activity in whole cells and in vivo remains unresolved. To address this question, liver microsomes and hepatocytes were prepared from hepatic cytochrome P450 oxidoreductase‐null mice and chlorzoxazone hydroxylation, a reaction catalyzed primarily by cytochrome P450 2E1, was evaluated. As expected, NADPH‐supported chlorzoxazone hydroxylation was absent in liver microsomes from oxidoreductase‐null mice, whereas NADH‐supported activity was about twofold higher than that found in normal (wild‐type) liver microsomes. This greater activity in oxidoreductase‐null microsomes could be attributed to the fourfold higher level of CYP2E1 and 1.4‐fold higher level of cytochrome b₅. Chlorzoxazone hydroxylation in hepatocytes from oxidoreductase‐null mice was about 5% of that in hepatocytes from wild‐type mice and matched the results obtained with wild‐type microsomes, where activity obtained with NADH was about 5% of that obtained when both NADH and NADPH were included in the reaction mixture. These results argue that the cytochrome b₅ electron transfer pathway can support a low but measurable level of CYP2E1 activity under physiological conditions. © 2009 Wiley Periodicals, Inc. J Biochem Mol Toxicol 23:357–363, 2009; Published online in Wiley InterScience ( www.interscience.wiley.com ). DOI 10.1002/jbt.20299     

Cytochrome P-450(17alpha) in beta-cells of rat pancreas and its local steroidogenesis

We have found cytochrome P-450(17alpha) in the islets of Langerhans of rat pancreas. Its existence coincided with that of insulin and demarcated those of glucagon and somatostatin, demonstrating the localization in beta-cells. The enzyme has not only 17alpha-hydroxylase activity but also lyase one, which is a prerequisite for androgen biosynthesis. The pancreatic microsomes converted progesterone mainly to androstenedione with a minor production of 17alpha-hydroxyprogesterone. Due to a low activity of the built-in lyase, cytochrome P-450(17alpha) requires a sufficient electron-transfer from P-450 reductase or presence of an activator to promote the C-C bond cleavage. In beta-cells, P-450 reductase was abundant and could efficiently transfer electrons to P-450(17alpha). Actually, inhibition with anti-P-450 reductase or limitation of NADPH preferentially reduced the lyase activity. Androstenedione was accumulated when its further metabolism was suppressed. We also found localization of cytochrome P-450scc and 3beta-hydroxysteroid dehydrogenase in beta-cells. These results indicate that the immediate substrate for androgen formation, progesterone, is intracellularly produced and is converted mainly to androstenedione with support by an efficient electron supply from P-450 reductase. The product was supposed to be further metabolized to the reduced derivatives such as testosterone, 5alpha-androstanedione, and dihydrotestosterone, which would act as local steroids in the islets of Langerhans.     

Fatty acid hydroxylation in rat kidney cortex microsomes

Rat kidney microsomes have been found to catalyze the hydroxylation of medium-chained fatty acids to the omega- and (omego-1)-hydroxy derivatives. This reaction, which requires NADPH and molecular oxygen, is a function of monooxygenase system present in the kidney microsomes, containing NADPH-cytochrome c reductase and cytochrome P-450K. NADH is about half as effective as an electron donor as NADPH and there is an additive effect in the presence of both nucleotides. Cytochrome P-450K absorbs light maximally at 452-3 nm, when it is reduced and bound to carbon monoxide. The extinction coefficient of this complex is 91 mM(-1) cm(-1). Electrons from NADPH are transferred to cytochrome P-450K via the NADPH-cytochrome c reductase. The reduction rate of cytochrome P-450K is stimulated by added fatty acids and the reduction kinetics reveal the presence of endogenous substrates bound to cytochrome P-450K. Both cytochrome P-450K concentration and fatty acid hydroxylation activity in kidney microsomes are increased by starvation. On the other hand, phenobarbital treatment of the rats has no effect on either the hemoprotein or the overall hydroxylation reaction and 3,4-benzpyrene administration induces a new species of cytochrome P-450K not involved in fatty acid hydroxylation. Cytochrome P-450K shows, in contrast to liver P-450, high substrate specificity. The only substances forming enzyme-substrate complexes with cytochrome P-450K are the medium-chained fatty acids and certain derivatives of these acids. The chemical requirements for substrate binding include a carbon chain of medium length and at the end of the chain a carbonyl group and a free electron pair on a neighbouring atom. The distance between the binding site for the carbonyl group and the active oxygen is suggested to be in the order of 16 A. This distance fixes the ratio of omega- and (omega-1)-hydroxylated products formed from a certain fatty acid by the single species of cytochrome P-450K involved. The membrane microenvironment seems also to be of importance for the substrate specificity of cytochrome P-450K, since removal of the cytochrome from the membrane lowers its binding specificity to some extent. A comparison between the liver and kidney cytochrome P-450 systems suggests that the kidney cytochrome P-450K system is specialized for fatty acid hydroxylation.     

Reconstruction and study of a multi-enzyme system by 11 beta-hydroxylase steroids

The reconstitution of the steroid 11 beta-hydroxylase system based on the homogeneous proteins isolated from bovine adrenocortical mitochondria, cytochrome P-450 (P-450 (11 beta), 19-20.5 nmol of heme P-450 per 1 mg of protein), adrenodoxin (Adx) and adrenodoxin reductase (AR) was carried out. The reconstitution of the multienzyme system requires the presence of a non-ionic detergent due to the high hydrophobicity of P-450 (11 beta). Low concentrations of Tween 20 (below 0.015% or 115 microM) stimulate the reaction of steroid 11 beta-hydroxylation by improving the hemoprotein solubility. With a further increase in the detergent concentration, the reaction is inhibited due to the inactivation of the cytochrome and its impaired interaction with Adx. The electron transfer activity of adrenodoxin reductase and the dienzyme AR-Adx complex does not change within the Tween 20 concentration range of 0-0.4%. In solutions with the optimal concentration of Tween 20 (0.010-0.015%), the concentrations of AR and Adx providing for the half-maximum hydroxylation activity are 9 nM for AR and 280 nM for Adx. It was shown that in a reconstituted 11 beta-hydroxylase system, 75% of the reducing equivalents are involved in the formation of oxygen radicals, whereas 25%--in hydroxylation. 74% of the radical species are, in their turn, formed in the active site of the hemoprotein, while 26%--in the Fe2S2 center of adrenodoxin. The radical formation process predominates over the 11 beta-hydroxylation within a wide range of Adx/cytochrome ratios, i.e., 1.0-100. The hydroxylation substrate induces a 4-fold increase in the electron transfer rate by stimulating the enzymatic reduction of P-450 (11 beta), but only 35% of the additional reduced equivalents are consumed by the 11 beta-hydroxylation and 65%--by the oxygen radical formation.