The topology of the mitochondrial 11β-hydroxylase system in bovine adrenal cortex

Binding of deoxycorticosterone to cytochrome P-450 of the 11β-hydroxylase system in adrenal cortex mitochondria was inhibited by the nonpenetrating protein reagent diazobenzenesulfonate in damaged but not in intact mitochondria. The slowly penetrating hydrophilic substrate deoxycorticosterone 21-sulfate showed a slow binding to cytochrome P-450 as compared to the hydrophobic nonesterified steroid. In contrast, the esterified and nonesterified steroids bound equally fast in sonicated, aged or lysolecithin-treated mitochondria. These data imply that the steroid substrates must penetrate the inner mitochondrial membrane to interact with the 11β-hydroxylase system.     

Topological studies of cytochromes P-450scc and P-45011 beta in bovine adrenocortical inner mitochondrial membranes. Effects of controlled tryptic digestion.

The topology of the steroid hydroxylase complexes in bovine adrenocortical mitochondria were studied by using controlled digestion with trypsin of purified inner mitochondrial membranes. Inhibition of steroid hydroxylase activity by trypsin was only observed in inner mitochondrial membranes which had been disrupted by various techniques. The steroid hydroxylase activity of intact inner membranes was not inhibited by trypsin. The effect of tryptic digestion was monitored by measuring 11 beta-hydroxylase and cholesterol side chain cleavage activities, as well as cytochrome P-450 reduction. The effect of trypsin on the steroid-induced difference spectra using pregnenolone, 20 alpha-hydroxycholesterol, and deoxycorticosterone was also measured. The results were similar regardless of which procedure was utilized and strongly suggest that both cytochrome P-45011 beta and cytochrome P-450scc are located on the matrix side of the mitochondrial inner membrane.     

Mitochondrial steroid metabolism in the inner and outer zones of the guinea-pig adrenal cortex

Previous investigations have demonstrated that cells isolated from the outer zone (zona fasciculata + zona glomerulosa) of the guinea-pig adrenal cortex produce far more cortisol than those from the inner zone (zona reticularis). Studies were carried out to compare mitochondrial steroid metabolism in the two zones. Protein and cytochrome P-450 concentrations were similar in outer and inner zone mitochondria. However, the rate of 11 beta-hydroxylation was significantly greater in the outer zone despite the fact that substrates for 11 beta-hydroxylation (11-deoxycortisol, 11-deoxycorticosterone) produced larger type I spectral changes in inner zone mitochondria. The apparent affinities of 11-deoxycortisol and 11-deoxycorticosterone for mitochondrial cytochrome(s) P-450 were similar in the two zones. In both inner and outer zone mitochondria, 11 beta-hydroxylation was inhibited by metyrapone but unaffected by aminoglutethimide. Cholesterol sidechain cleavage activity, measured as the rate of conversion of endogenous cholesterol to pregnenolone, was far greater in outer than inner zone mitochondria. Addition of exogenous cholesterol or 25-hydroxycholesterol to the mitochondrial preparations did not affect pregnenolone production in either zone. Addition of pregnenolone to outer zone mitochondria produced a reverse type I spectral change (delta A 420-390 nm), suggesting displacement of endogenous cholesterol from cytochrome P-450. In inner zone mitochondria, pregnenolone induced a difference spectrum (delta A 425-410 nm) similar to the reduced vs oxidized cytochrome b5 spectrum. A b5-like cytochrome was found to be present in the mitochondrial preparations. Prior reduction of the cytochrome with NADH eliminated the pregnenolone-induced spectral change in inner zone mitochondria but had no effect in outer zone preparations. The results suggest that differences in mitochondrial steroid metabolism between the inner and outer adrenocortical zones account in part for the differences in cortisol production by cells in each zone.     

Differential effects of adrenocorticotropic hormone on steroid hydroxylase activities in the inner and outer zones of the guinea pig adrenal cortex.

We have studied the effects of ACTH treatment on steroid hydroxylase activities in the inner (zona reticularis) and outer (zona fasciculata plus zona glomerulosa) zones of the guinea pig adrenal cortex. Animals received 5 or 10 U of ACTH daily for 6 days and enzyme activities were then assessed in isolated microsomal or mitochondrial preparations. In control animals, microsomal cytochrome P-450 concentrations were greater in the inner than outer zone, but mitochondrial P-450 levels were similar in the two zones. Microsomal 17 alpha-hydroxylase and mitochondrial 11 beta-hydroxylase activities were greater in the outer than inner zone, but microsomal 21-hydroxylase activity was greater in the inner zone. ACTH treatment decreased cytochrome P-450 concentrations in inner but not outer zone microsomes; mitochondrial P-450 levels were unaffected in both zones. ACTH caused a dose-dependent increase in inner zone 17 alpha-hydroxylase activity and decrease in 21-hydroxylase activity without affecting the activity of either enzyme in outer zone microsomes. ACTH also decreased 11 beta-hydroxylase activity in outer but not inner zone mitochondrial preparations. The net effect of ACTH treatment was to diminish the differences in steroid metabolism between the two zones. The results indicate that the effects of ACTH on steroid hydroxylase activities are both zone- and enzyme-dependent, suggesting the existence of multiple and independent regulatory mechanisms.     

CYP11A1 stimulates the hydroxylase activity of CYP11B1 in mitochondria of recombinant yeast in vivo and in vitro.

In mammals, hydrocortisone synthesis from cholesterol is catalyzed by a set of five specialized enzymes, four of them belonging to the superfamily of cytochrome P-450 monooxygenases. A recombinant yeast expression system was recently developed for the CYP11B1 (P45011beta) enzyme, which performs the 11beta hydroxylation of steroids such as 11-deoxycortisol into hydrocortisone, one of the three mitochondrial cytochrome P-450 proteins involved in steroidogenesis in mammals. This heterologous system was used to test the potential interaction between CYP11B1 and CYP11A1 (P450scc), the mitochondrial cytochrome P-450 enzyme responsible for the side chain cleaving of cholesterol. Recombinant CYP11B1 and CYP11A1 were targeted to Saccharomyces cerevisiae mitochondria using the yeast cytochrome oxidase subunit 6 mitochondrial presequence fused to the mature form of the two proteins. In yeast, the presence of CYP11A1 appears to improve 11beta hydroxylase activity of CYP11B1 in vivo and in vitro. Fractionation experiments indicate the presence of the two proteins in the same membrane fractions, i.e. inner membrane and contact sites of mitochondria. Thus, yeast mitochondria provide interesting insights to study some molecular and cellular aspects of mammalian steroid synthesis. In particular, recombinant yeast should permit a better understanding of the mechanism permitting the synthesis of steroids (sex steroids, mineralocorticoids and glucocorticoids) with a minimal set of enzymes at physiological level, thus avoiding disease states.     

Inhibition of mitochondrial electron transport by hydrophilic metal chelators. Determination of dehydrogenase topography

The topography of the inner mitochondrial membrane was investigated using inhibitors of electron transport on preparations of beef heart mitochondria and electron transport particles of opposite orientation. Reductions of juglone, ferricyanide, indophenol, coenzyme Q, duroquinone, and cytochrome c by NADH are inhibited to different extents on both sides of the membrane by the impermeant hydrophilic chelators bathophenanthroline sulfonate and orthophenanthroline. The extent of inhibition for each acceptor increased in the order given. At least two chelator-sensitive sites are present on each membrane face between the flavoprotein and coenzyme Q and a chelator-sensitive site is present on the matrix face between the sites of coenzyme Q and duroquinone interaction. Duroquinol oxidation in mitochondria only is stimulated by bathophenanthroline sulfonate. Juglone reduction is stimulated in electron transport particles (only) by p-hydroxymercuribenzenesulfonate, but after mercurial treatment, juglone reduction in both particles and mitochondria is more sensitive to bathophenanthroline sulfonate.Succinate dehydrogenase components are inhibited by hydrophilic orthophenanthroline or bathophenanthroline sulfonate in mitochondria only. Electron flow between the dehydrogenases of succinate and NADH occurs via a chelator-sensitive site located on the matrix face of the membrane. Inter-complex electron flow is prevented by rotenone or thenoyltrifluoroacetone. The lack of succinate-indophenol reductase inhibition by bathophenanthroline sulfonate in the presence of rotenone or thenoyltrifluoroacetone indicates that the rotenone-sensitive site may be located on the matrix face and demonstrates that electrons flow between the NADH and succinate dehydrogenases via a hydrophilic chelator and rotenone-thenoyltrifluoroacetone-sensitive site on the matrix face of the membrane. Inhibition by hydrophilic chelators only in mitochondria indicates that succinate dehydrogenase as well as NADH dehydrogenase has a transmembranous orientation.     

Hepatic mitochondrial cytochrome P-450 system. Identification and characterization of a precursor form of mitochondrial cytochrome P-450 induced by 3-methylcholanthrene

Hepatic mitoplasts from 3-methylcholanthrene-treated rats contain cytochrome P-450 which can metabolize polycyclic aromatic hydrocarbons like benzo(a)pyrene. Mitochondrial cytochrome P-450 was partially purified and reconstituted in vitro using adrenodoxin and the adrenodoxin reductase electron transfer system and [3H]benzo(a)pyrene as the substrate. A polyclonal antibody to purified microsomal P-450c (a major 3-methylcholanthrene-inducible form) inhibited the activity of mitochondrial enzyme in a concentration-dependent manner and also reacted with a 54-kDa protein on the immunoblots. A monoclonal antibody having exclusive specificity for P-450c, on the other hand, did not inhibit the aryl hydrocarbon hydroxylase activity of the mitochondrial enzyme and showed no detectable cross-reaction with the 54-kDa mitochondrial protein. Similarly, two-dimensional analysis and immunodetection using the polyclonal antibody showed distinct molecular properties of the mitochondrial enzyme different from the similarly induced microsomal P-450c with respect to the isoelectric pH. In vitro translation of free polysomes from 3-methylcholanthrene-induced liver, transport of precursor proteins by isolated mitochondria in vitro, and immunoprecipitation with the polyclonal antibody showed the presence of a 57-kDa putative precursor which is transported and processed into mature 54-kDa species. These results present evidence for the true intramitochondrial location of the P-450c-antibody reactive isoform detected in 3-methylcholanthrene-induced rat liver mitochondria.     

Effect of calcium(ion) uptake by rat adrenal mitochondria on pregnenolone formation and spectral properties of cytochrome P-450.

The effect of calcium on pregnenolone formation from endogenous precursors has been studied in mitochondria from rat decapsulated and capsular adrenal glands. In the presence of succinate, addition of calcium chloride in the concentration range 20-150 muM caused an inhibition of pregnenolone formation in both decapsulated and capsular adrenal mitochondria. 11beta-hydroxylation of added deoxycosticosterone in decapsulated adrenal mitochondria was also inhibited. Under these conditions, calcium inhibited the reduction of adrenodoxin, a component of the cytochrome P-450 reductase system, presumably because uptake of calcium by the mitochondria competes with energy-linked transhydrogenase for high-energy intermediates. For this reason, incubations were carried out in the presence of succinate plus isocitrate plus NADP+. Under these conditions, calcium chloride in the concentration range 120-875 muM caused a 2-4-fold stimulation of pregnenolone formation, but had no effect on corticosterone formation from added deoxycorticosterone. The effect of calcium on the optical spectra of cytochrome P-450 has also been examined in mitochondria from decapsulated and capsular rat adrenals. In the presence of succinate, calcium induced a spectral change resembling a type I difference spectrum of cytochrome P-450. Thus it appears that uptake of calcium by adrenal mitochondria can stimulate pregnenolone formation by increasing the interaction of mitochondrial cytochrome P-450 with endogenous substrate.     

Alterations of heme, cytochrome P-450, and steroid metabolism by mercury in rat adrenal

The treatment of male rats with Hg2+ resulted in significant alterations in heme and hemoprotein metabolism in the adrenal gland which, in turn, were reflected in abnormal steroidogenic activities and steroid output. Twenty-four hours after the administration of 30 mumol of HgCl2/kg (sc) the mitochondrial heme and cytochrome P-450 concentrations increased by approximately 50%. Also, Hg2+ treatment stimulated a porphyrinogenic response which included an 11-fold increase in the activity of delta-aminolevulinate synthetase. The increase in mitochondrial cytochrome P-450 content was reflected in elevated steroid 11 beta-hydroxylase and cholesterol side-chain cleavage activities. In contrast, Hg2+ treatment resulted in decreased concentrations of microsomal cytochrome P-450 (-75%) and heme (-45%). Similarly, the reduction in the microsomal cytochrome P-450 content was accompanied by reduced steroid 21 alpha-hydroxylase and benzo[alpha]pyrene hydroxylase activities. The mechanisms responsible for the loss of the microsomal cytochrome P-450 content appeared to involve a selective impairment of formation of the holocytochrome as well as an enhanced rate of heme degradation. This suggestion is made on the basis of findings that (a) the decrease in the microsomal cytochrome P-450 content was accompanied by a sevenfold increase in the activity of adrenal heme oxygenase, (b) no decrease in apocytochrome P-450 could be detected in sodium dodecyl sulfate-gel electrophoresis of the solubilized microsomal fractions stained for heme, and (c) the concentration of adrenal microsomal cytochrome b5 was significantly increased in the Hg2+-treated animals. It is suggested that Hg2+ directly caused a defect in adrenal steroid biosynthesis by inhibiting the activity of 21 alpha-hydroxylase. The apparent physiological consequences of this effect included lowered plasma levels of corticosterone and elevated concentrations of progesterone and dehydroepiandrosterone. This abnormal plasma steroid profile is indicative of a 21 alpha-hydroxylase impairment.     

Cytochrome P-45011 beta and P-450scc in adrenal cortex: zonal distribution and intramitochondrial localization by the horseradish peroxidase-labeled antibody method

In an attempt to elucidate the regulation mechanism(s) of adrenocortical steroidogenesis, cytochrome P-450scc and cytochrome P-45011 beta were localized in bovine adrenal glands by the direct peroxidase-labeled antibody method. At the light microscopic level, parenchymal cells of the zona fasciculata and the zona reticularis stained heavily for both cytochromes, while the parenchymal cells of zona glomerulosa stained lightly for both. At the electron microscopic level, these two cytochromes were associated with the matrix side of the inner mitochondrial membranes of parenchymal cells from all three zones of the adrenal cortex. The association of cytochrome P-450 with the inner mitochondrial membrane, in a manner similar to that previously reported for adrenodoxin and adrenodoxin reductase (F Mitani, Y Ishimura, S Izumi, K Watanabe, Acta Endocrinol 90:317, 1979), establishes that the steroid monooxygenase systems exist at this site. The degree of immunocytochemical staining within a single cell varied from one mitochondrion to another: some stained intensely along the entire inner membrane, including the cristae, some stained only along segments of the inner membrane, and some did not stain at all. This heterogeneity in staining was observed in mitochondria stained in situ as well as in isolated mitochondria. These findings suggest that there is a heterogeneity in steroidogenesis among mitochondria contained within a single cell of the adrenal cortex.     

A transmembranous NADH-dehydrogenase in human erythrocyte membranes

Evidence is presented for a transmembranous NADH-dehydrogenase in human erythrocyte plasma membrane. We suggest that this enzyme is responsible for the ferricyanide reduction by intact cells. This NADH-dehydrogenase is distinctly different from the NADH-cytochromeb ₅ reductase on the cytoplasmic side of the membrane. Pretreatment of erythrocytes with the nonpenetrating inhibitor diazobenzene sulfonate (DABS) results in a 35% loss of NADH-ferricyanide reductase activity in the isolated plasma membrane. Since NADH and ferricyanide are both impermeable, the transmembrane enzyme can only be assayed in open membrane sheets with both surfaces exposed, and not in closed vesicles. The transmembrane dehydrogenase has affinity constants of 90 µM for NADH and 125 µM for ferricyanide. It is inhibited byp-chloromercuribenzoate, bathophenanthroline sulfonate, and chlorpromazine.     

Modification of enzymatic activity and difference spectra of cytochrome P-450 from various sources by cholesterol side chain cleavage inhibitors

Several groups of compounds were tested for their ability to inhibit cholesterol side chain cleavage and induce spectral change in cytochrome P-450 from bovine corpus luteum, bovine adrenal cortex, and human placental mitochondria. The substances tested include: steroids, pyridines, glutarimides, anilines and imidazoles. Good correlation was found between spectral change and enzymatic inhibition, especially in the corpus luteum which has only a single P-450-linked steroid hydroxylase. The cholesterol side chain cleavage enzyme systems from each of the three sources appear to have similar affinities for the inhibitors, which adds further support to the concept that these cytochrome P-450s are functionally identical.     

Integration of purified adrenocortical cytochrome P-45011β into phospholipid vesicles

Cytochrome P-450 supporting steroid 11β hydroxylase activity (cyt P-450_11β) was purified from bovine adrenal cortex mitochondria using a procedure, which included an octyl-sepharose adsorption step and elution of the protein in the presence of phosphatidyl-choline. Purified cyt P-450_11β could then be included into phosphatidyl choline-phosphatidyl ethanolamine (1 : 1) spherical vesicles (20–50 nm in diameter) during their formation upon gel filtration, as demonstrated by the protein refractoriness to trypsin hydrolysis. After inclusion into the phospholipid vesicles, cyt P-450_11β remained stable and expressed full 11β hydroxylase activity in a reconstituted system including purified adrenodoxin and adrenodoxin reductase.     

Spectrophotometric study of cytochrome P-450 (11 beta) interaction with physiological effectors

Using the optical absorbance spectroscopy method, the interaction of a number of biospecific ligands (steroids, adrenodoxin) with homogeneous cytochrome P-450 (11 beta) from bovine adrenal mitochondria was investigated. The parameters of the steroid-protein interaction in a number of substrates and products of the 11 beta- and 18 (19)-hydroxylation with the active site of cytochrome P-450 (11 beta) were determined. A sharp decrease in the cytochrome affinity for steroids upon the insertion of the first hydroxy group was observed, which provides for a predominant formation of monohydroxylated products from the substrate and minimum amounts of dihydroxylated ones, despite the presence of more than one position for the substrate hydroxylation by cytochrome P-450 (11 beta). Some structural elements of the steroid molecule were determined as any alterations in these strongly affect the enzyme affinity for the steroid. These structures are: 1) delta 4-3-oxo structure; 2) either 21-hydroxy group of pregnen steroids or the one fulfilling its functions, 17 beta-hydroxy or 17-oxo group of androsten steroids, and 3) the 11th position of all the substrates under study. It was shown that the binding of various substrates into stoichiometric (1:1) steroid-protein complexes provides a transition to high spin state from 30-40% (cortisol, corticosterone) to 90-95% (11-deoxycorticosterone) of hemoprotein iron. Using the experimental system containing individual cytochrome P-450 (11 beta) and adrenodoxin, as well as the steroid and nonionic detergent Tween 20, it was shown that the parameters of substrate binding and hemoprotein spin equilibrium did not differ from the corresponding parameters of the cytochrome-adrenodoxin dienzyme complex. The peculiarities of the multiligand interactions in the 11 beta-hydroxylase system, involving cytochrome, substrates and ferredoxin demonstrate some analogy with a bacterial camphor hydroxylase system and some differences from the mitochondrial system for the side chain cleavage of cholesterol.     

Molecular organization (topography) of cytochrome P-450(11)beta in mitochondrial membrane and phospholipid vesicles as studied by trypsinolysis

Cytochrome P-450(11)beta from adrenal cortex is an intrinsic membrane protein embedded in the inner mitochondrial membrane. Topography of the protein inside a phospholipid bilayer was examined using controlled proteolysis of purified cytochrome P-450(11)beta following its integration into artificial liposomes. Inclusion of the protein into phospholipid vesicles led to a marked stabilization of the cytochrome activity. Trypsin treatment of the liposome-integrated cytochrome resulted in the rapid disappearance of the native protein moiety (47 kDa), while a major 34 kDa peptide component was formed. This peptide core retained the heme moiety and part of the cytochrome steroid-11 beta hydroxylase activity. Very similar observations were obtained when inside-out vesicles prepared from isolated adrenocortical mitoplasts were examined with the same approach. It is thus suggested that adrenocortical cytochrome P-450(11)beta is embedded in the inner mitochondrial membrane as well as in artificial liposomes by a major hydrophobic domain associated with the heme moiety while a limited domain remains accessible on the matrix side of the membrane surface. The previous described phosphorylation of the cytochrome P-450(11)beta on a serine residue, by the cAMP-dependent protein kinase is suggested to occur in the protein domain oriented toward the membrane surface, the phosphorylation site being lost under mild proteolytic digestion of the membrane-integrated protein.     

The reoxidation of cytochrome P-450 by paraquat inhibits aldosterone biosynthesis from 18-hydroxycorticosterone

Paraquat is an artificial electron carrier that captures electrons from reduced cytochrome P-450 instead of the natural acceptors, thus decreasing the concentration of reduced mitochondrial cytochrome P-450. In the present study, paraquat inhibited the biosynthesis of aldosterone from 18-hydroxycorticosterone by mitochondria from duck adult adrenal gland, under aerobic conditions. Since paraquat did not induce any change in the absorption spectrum of highly purified cytochrome P-450 11 beta, the possibility of a displacement of steroid by the drug is ruled out. Moreover, paraquat did not affect oxidative phosphorylating chain nor did it alter by itself the chemical structure of 18-hydroxycorticosterone. In our conditions, the inhibitory role of paraquat seems restricted to a capture of electrons from reduced cytochrome P-450. Under the same conditions metopirone and spironolactone, known to bind cytochrome P-450 11 beta at the steroid binding site, also inhibited the reaction. Altogether these results show that for aldosterone synthesis from 18-hydroxycorticosterone to take place, the steroid binding site on cytochrome P-450 must be accessible to 18-hydroxycorticosterone and that the cytochrome P-450 must be the direct donor of reducing equivalents. Hence, cytochrome P-450 appears as the final linking point between 18-hydroxycorticosterone and the reducing equivalents provided by NADPH.     

Regulation of the biosynthesis of steroidogenic enzymes

Recombinant DNA technology can permit study of the regulation of steroid hydroxylase gene expression at three levels. The first of these is cAMP-regulated gene expression. In the adrenal, ACTH, via cAMP, increases the expression of the genes for all of the cytochrome P-450 species involved in the steroid biosynthetic pathway, as well as the iron-sulfur protein, adrenodoxin. This action of cAMP is inhibited by cycloheximide, suggestive of the involvement of a regulatory protein factor in mediating this action of cAMP. The second level is tissue-specific regulation of steroid hydroxylase gene expression. An example of this which we have studied is the expression of cholesterol side-chain cleavage cytochrome P-450 (P-450sec) and 17 alpha-hydroxylase cytochrome P-450 (P-450(17) alpha) in the bovine ovary. P-450sec is expressed at high levels in the corpus luteum but at low levels in follicles, whereas P-450(17)alpha is expressed in follicles, but is undetectable in the corpus luteum. The third level is fetal imprinting. A number of the cytochrome P-450 species involving in the steroidogenic pathway are expressed in the fetal adrenal at a time when exposure of the gland to ACTH is very low, suggestive that factor(s) other than pituitary ACTH mediate this expression in fetal life.     

Import and processing of the precursor of cytochrome P-450(SCC) by bovine adrenal cortex mitochondria

Isolated bovine adrenal cortex mitochondria imported in vitro synthesized pre-P-450(SCC) and processed it to the mature form. Partial radio-sequencing of the processed P-450(SCC) gave a result identical with that for authentic P-450(SCC). Rat liver mitochondria also imported pre-P-450(SCC) and processed it to the mature form, whereas bovine heart mitochondria were unable to import and process pre-P-450(SCC) although both mitochondrial preparations imported and processed pre-adrenodoxin. The pre-P-450(SCC) processing activity of bovine adrenal cortex mitochondria was associated with the matrix side surface of the inner membrane. The processing protease could be solubilized by sodium cholate and partially purified by ammonium sulfate fractionation. The partially purified processing protease cleaved pre-P-450(SCC) at the correct position. It was also active in processing pre-P-450(11 beta) but inactive toward pre-adrenodoxin. Bovine heart mitochondria lacked the processing activity to pre-P-450(SCC). The localization of pre-P-450(SCC) and mature P-450(SCC) in bovine adrenal cortex mitochondria was examined. Mature P-450(SCC) processed by the mitochondria was found associated with the matrix-side surface of the inner membrane, which is the correct location of P-450(SCC) in the cell. In the presence of o-phenanthroline, pre-P-450(SCC) was imported into the organelles without being processed and remained soluble in the matrix. The incorporation of newly processed mature P-450(SCC) into the inner membrane was also observed when pre-P-450(SCC) was incubated with inner membrane vesicles. Mature P-450(SCC) generated in vitro from pre-P-450(SCC) by the partially purified processing protease was incorporated not only into the inner membrane vesicles but also into bovine adrenal cortex microsomes. These findings suggested that the processing of pre-P-450(SCC) occurred prior to the incorporation of mature-P-450(SCC) into the inner membrane.     

Adrenocortical cytochrome P-450 responsible for cholesterol side chain cleavage (P-450scc) is phosphorylated by the calcium-activated, phospholipid-sensitive protein kinase (protein kinase C)

Purified bovine adrenocortical cytochrome P-450scc (specific for cholesterol side chain cleavage in the inner mitochondrial membrane) was selectively phosphorylated in vitro by a Ca2+-activated, phospholipid-sensitive protein kinase (protein kinase C) preparation, whereas cyclic AMP dependent and two cyclic nucleotide independent kinases were ineffective. Cytochrome P-450scc incorporated a maximum of 4 mol of phosphate in the presence of protein kinase C within 15 min at 30 degrees C, with apparent Km and Vmax of 0.14 mumol and 0.76 pmol/min, respectively. Serine and threonine were the two target aminoacids phosphorylated in a ratio of about 1:1. In the presence of 1 microM Ca2+, a mixture of phosphatidylserine and diolein (or a potent tumor promoter phorbol ester) was required for optimal cytochrome P-450scc phosphorylation. In addition, purified inner mitochondrial membrane preparations from adrenocortical mitochondria were found to contain protein kinase C activity. These findings, together with the previous demonstration that activators of protein kinase C such as a potent phorbol ester activates steroidogenesis of intact adrenocortical cells, suggest that phosphorylation of P-450scc should be examined for its possible role in the regulation of adrenocortical functions.     

Transport of electrons from mitochondria to microsomes in the reconstituted system of cell organelles

The reduction of cytochrome P-450--CO complex in the presence of various agents in the reconstituted system of liver cell organelles was studied. The reconstituted system was obtained by the preincubation of isolated liver microsomes and mitochondria of the rats kept on a prolonged phenobarbital diet. The addition of glutamate (but not succinate), NAD+ and amytal (or rotenone) to the reconstituted system caused a 40-50% reduction of NADPH-reducible cytochrome P-450. The inhibitor of mitochondrial NADH-cytochrome b5 reductase dicumarol prevented the cytochrome P-450 reduction in the presence of glutamate, NAD+ and amytal but did not affect the reduction of cytochrome P-450 by the added NADH. It was concluded that the electron transfer from the NAD-dependent substrates of the inner mitochondrial respiratory chain to the microsomal cytochrome P-450 occurs with the participation of non-bound NAD and cytochrome b5 of the outer mitochondrial membrane on the condition that the membranes of the two main oxidative systems are in tight contact.