Characterization of a mitochondrial matrix protease catalyzing the processing of adrenodoxin precursor

Adrenodoxin (Ad) is synthesized as a larger precursor (preAd) by cytoplasmic polysomes and then transported into mitochondria concomitant with its proteolytic processing to the mature form. The protease in bovine adrenal cortex mitochondria, which converts preAd to the mature form, is a metalloprotease in the matrix (Sagara, Y., Ito, A. & Omura, T. (1984) J. Biochem. 96, 1743-1752). In this study, the protease was purified about 100-fold from the matrix fraction of bovine adrenal cortex mitochondria. The partially purified protease converted not only preAd, but also the precursors of malate dehydrogenase (MDH) and 27 kDa protein (P-27) to the corresponding mature forms. However, it was inactive toward the precursors of P-450(SCC) and of P-450(11 beta). Since isolated rat liver mitochondria can import and process preAd as efficiently as bovine adrenal cortex mitochondria, we partially purified a preAd-processing protease from rat liver mitochondria and compared its properties with those of the bovine adrenal cortex enzyme. The properties of the rat liver protease were indistinguishable from those of the bovine adrenal cortex enzyme in molecular weight determined from Sephadex G-150 gel filtration, metal requirement and ability to process preMDH and preP-27. The rat liver enzyme was also inactive toward the precursors of P-450(SCC) and P-450(11 beta). These results indicate the presence in both adrenal cortex and liver mitochondria of the same type of processing protease, which processes preAd and also the precursors of some other mitochondrial proteins.     

Import and processing of P-450SCC and P-450(11) beta precursors by corpus luteal mitochondria: a processing pathway recognizing homologous and heterologous precursors

Maturation of the precursor forms of bovine cholesterol side-chain cleavage cytochrome P-450 (P-450SCC) and 11 beta-hydroxylase cytochrome P-450 (P-450(11)beta) was investigated using mitochondria from bovine corpus luteum. The results show that both precursors, whose synthesis was directed by bovine adrenocortical RNA, can be imported and proteolytically processed to their corresponding mature forms by bovine corpus luteal mitochondria, even though P-450(11)beta is not expressed in this tissue. Furthermore, the efficiency of processing of pre-P-450(11)beta by corpus luteal mitochondria is similar to that of pre-P-450SCC, an endogenous enzyme of these mitochondria. However, the P-450(11)beta precursor is not processed by mitochondria from a nonsteroidogenic tissue (heart), a result observed previously for the P-450SCC precursor (M. F. Matocha and M. R. Waterman (1984) J. Biol. Chem. 259, 8672-8678). This discriminatory processing of pre-P-450(11)beta by heterologous mitochondria suggests that the precursor forms of P-450SCC and P-450(11)beta are processed via a common pathway in steroidogenic mitochondria and that this pathway is absent in nonsteroidogenic mitochondria.     

Processing-independent in vitro translocation of cytochrome P-450(SCC) precursor across mitochondrial membranes

In the presence of a membrane-permeable metal chelator, bovine adrenal cortex mitochondria imported P-450(SCC) precursor without processing of the amino-terminal extension peptide. The imported precursor was bound to the matrix side surface of the inner membrane. When the inhibition due to the metal chelator was removed, the imported precursor was processed to the mature form. Unprocessed precursor was also detected in mitochondria when the import reaction was carried out at relatively low temperature. These results suggest that the translocation of P-450(SCC) precursor across mitochondrial membranes is independent of its processing to the mature form. Both membrane-bound and solubilized P-450(SCC) could be cleaved by trypsin into two fragments with molecular weights of 29 kDa and 26 kDa, respectively, suggesting a two-domain structure of the molecule. The in vitro-imported and processed P-450(SCC) was also cleaved by trypsin in the same way. This finding indicated that the in vitro-imported and processed P-450(SCC) has the same conformation as the native form.     

Partial purification of a metalloprotease catalyzing the processing of adrenodoxin precursor in bovine adrenal cortex mitochondria

In vitro translation of bovine adrenal cortex RNA in rabbit reticulocyte lysate cell-free system produced the precursor form of adrenodoxin having a molecular weight of approximately 22,000 daltons, which was about 10,000 daltons larger than mature adrenodoxin. The precursor of adrenodoxin was efficiently imported into adrenal cortex mitochondria in vitro. The precursor was also imported into rat liver mitochondria, suggesting the lack of tissue specificity and species specificity of the import process. The enzyme which processed the precursor of adrenodoxin to the mature form was in the matrix fraction from bovine adrenal cortex mitochondria, and the processing protease was partially purified from the matrix fraction. The apparent molecular weight of the processing protease was about 60,000 daltons as determined by Sephadex G-150 gel filtration, and its activity was optimal at pH 8.5. The processing protease was not inhibited by various bacterial protease inhibitors examined. Metal chelators (EGTA, GTP, 8-hydroxyquinoline, and Zincon) inhibited the processing, and EDTA and o-phenanthroline were more strongly inhibitory than other chelators. The processing protease was completely inactivated by incubation with 10 microM EDTA, and its activity was restored by addition of excess amounts of Mn2+, Fe2+, or Co2+. These results indicate that the maturation of the precursor of adrenodoxin is catalyzed by a soluble metalloprotease in the matrix.     

Presence of a prepiece at the NH2-terminal end of pre-cytochrome P-450(SCC) peptide

Mild acid treatment of in vitro translated cytochrome P-450(SCC) (pre-P-450(SCC] peptide cleaved the peptide into two fragments. Comparison of the sizes and the NH2-terminal amino acids of the fragments with those of the corresponding fragments from mature P-450(SCC) suggested that the prepiece of pre-P-450(SCC) was present at the NH2-terminal end of the peptide. This conclusion was confirmed by radio-sequencing of the NH2-terminal portion of pre-P-450(SCC).     

Multiple molecular forms of cytochrome P-450SCC purified from bovine corpus luteum mitochondria

Cytochrome P-450 related to side-chain cleavage of cholesterol (P-450SCC) was isolated from bovine corpus luteum mitochondria in the form of its stable cholesterol complex. The isolation procedure included ammonium sulfate fractionation and chromatography on omega-aminohexyl-Sepharose (AH-Sepharose). Corpus luteum P-450SCC was resolved into one minor (AH-I) and two major (AH-II and AH-III) fractions by the chromatography. Results of re-chromatography suggested the possibility that AH-III Fraction was originally complexed with lipidic material. The two major fractions purified by the re-chromatography (AH-IIR and AH-IIIR Fractions) showed essentially a single band on sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis and their absorption spectra were indistinguishable from each other. Both fractions were further resolved into two major and some minor bands of P-450SCC by isoelectric focusing on polyacrylamide gel in the presence of a non-ionic detergent, as detected by protein staining, heme staining and immunoblot analysis with anti-bovine P-450SCC monoclonal antibody. Both AH-IIR and AH-IIIR Fractions were further resolved by high-performance liquid chromatography (HPLC) on SP-TSK gel column into two fractions, SP-I and SP-II. These fractions had the same N-terminal amino acid sequence, showed similar catalytic activity and resolved into one major and a few minor bands on isoelectric focusing on polyacrylamide gel. Much more heterogeneity was observed in purified P-450SCC preparations from bovine adrenal cortex mitochondria. These results indicated the presence of multiple molecular forms of corpus luteum P-450SCC as well as adrenal cortex P-450SCC. Computer simulation studies were carried out in order to analyze the mechanism of formation of multiple bands on isoelectric focusing. The multiple bands of corpus luteum P-450SCC could be explained by postulating the presence of two isozymes (or molecular forms) having a pair of sites each with or without a charged group.     

Site-directed mutagenesis of basic amino acid residues in the extension peptide of P-450(SCC) precursor: effects on the import of the precursor into mitochondria

The precursor of cytochrome P-450(SCC) (preP-450(SCC], an inner membrane protein of adrenal cortex mitochondria, has an extension peptide consisting of 39 amino acids which is thought to play an essential role in the import of the precursor into mitochondria. The amino terminal portion of the extension peptide contains three positively charged amino acid residues, Arg(4), Arg(9), and Lys(14). To investigate their role in the import of preP-450(SCC) into mitochondria, they were replaced by other amino acids, Ser or Thr, by site-directed mutagenesis. The import of mutated preP-450(SCC)s with single amino acid substitution was much less efficient than with the original precursor. The mutated preP-450(SCC)s with two or three substitutions were not imported. These results suggest that the positively charged amino acid residues in the amino terminal portion of the extension peptide are essential for the import of preP-450(SCC) into mitochondria.     

Critical region in the extension peptide for the import of cytochrome P-450(SCC) precursor into mitochondria

In order to establish the role of the extension peptide of the precursor of P-450(SCC), a mitochondrial inner membrane protein, in the import into the organella, three deletion mutants of the precursor, in which the deletions were in the mature portion, were constructed. These mutant precursors were imported into mitochondria in vitro as efficiently as the original precursor, indicating that the extension peptide contains sufficient information for the import of the precursor into mitochondria. To investigate which portion of the extension peptide contains the mitochondrial targeting signal, various lengths of the amino-terminal portion of the extension peptide of P-450(SCC) precursor were fused to the mature portion of adrenodoxin. The fusion proteins consisting of 44 and 19 amino-terminal amino acids and mature adrenodoxin were imported into mitochondria, whereas those containing 14, 7, and 2 amino-terminal amino acid residues were not. The importance of the amino-terminal portion of the extension peptide was confirmed by the deletion from the amino-terminal end of a fusion protein consisting of the amino-terminal 44 amino acid residues of P-450(SCC) precursor and mature adrenodoxin, SCC44RAd. The amino-terminal deletions abolished the import of the fusion proteins into mitochondria. Substitution of all of the three basic amino acids, Arg(4), Arg(9), and Lys(14) in the extension peptide of SCC44RAd to Ser or Thr inhibited the binding of the fusion protein to mitochondria as well as its import.(ABSTRACT TRUNCATED AT 250 WORDS)     

Purification and characterization of a processing protease from rat liver mitochondria.

A processing protease has been purified from the matrix fraction of rat liver mitochondria. The purified protease contained two protein subunits of 55 kd (P-55) and 52 kd (P-52) as determined by SDS-PAGE. The processing protease was estimated to be 105 kd in gel filtration, indicating that the two protein subunits form a heterodimeric complex. At high ionic conditions, the two subunits dissociated. The purified processing protease cleaved several mitochondrial protein precursors destined to different mitochondrial compartments, including adrenodoxin, malate dehydrogenase, P-450(SCC) and P-450(11 beta), but the processing efficiencies were different each other. The endoprotease nature of the processing protease was confirmed with the purified enzyme using adrenodoxin precursor as the substrate; both the mature form and the extension peptide were detected after the processing. The processing activity of the protease was inhibited by metal chelators, and reactivated by Mn2+, indicating that the protease is a metalloprotease.     

Characterization of adrenodoxin precursor expressed in Escherichia coli.

The precursor of bovine adrenodoxin (pAd), a mitochondrial protein, was expressed in Escherichia coli. The cloned cDNA of pAd was ligated to an expression vector pET-3d, and silent mutations were introduced into the N-terminal portion of the cDNA in order to increase the expression. The precursor was highly expressed (approximately 20% of the total cell protein) as the inclusion body, and contained an iron-sulfur center as judged from its optical absorption spectra. The inclusion body was solubilized with 7 M urea and pAd was purified in the presence of urea. The purified pAd was efficiently imported into isolated bovine adrenal cortex mitochondria and processed to the mature form. The import reaction required ATP inside the mitochondria in addition to the inner membrane potential, and was strongly inhibited by trypsin treatment of the mitochondria, as in the case of the in vitro translated precursor. It was, however, not dependent on the unfolding activity of the cytosolic factor with extramitochondrial ATP.     

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.     

Discriminatory processing of the precursor forms of cytochrome P-450scc and adrenodoxin by adrenocortical and heart mitochondria

The mitochondrial proteins involved in adrenocortical steroidogenesis are synthesized as higher molecular weight precursors which require processing by the mitochondria to their mature sizes. The post-translational maturation of two of these proteins has been examined: the cholesterol side chain cleavage cytochrome P-450 (P-450scc) and the iron-sulfur protein, adrenodoxin. Total translation products synthesized in a cell-free system programmed by bovine adrenocortical poly(A+) RNA were incubated with isolated bovine adrenocortical or heart mitochondria followed by immunoisolation of radiolabeled P-450scc or adrenodoxin. In the presence of adrenocortical mitochondria, the precursor form of P-450scc was converted into a trypsin-resistant form that had the same molecular weight as mature P-450scc. Unlike adrenocortical mitochondria, heart mitochondria were unable to process the P-450scc precursor which remained unaltered and trypsin-sensitive. In addition, a matrix fraction of heart mitochondria did not cleave the P-450scc precursor. In contrast, the adrenodoxin precursor did not exhibit similar specificity as it was processed to the mature form by both adrenocortical and heart mitochondria. Also, the adrenocortical mitochondria were not restricted to processing endogenous proteins as they imported and cleaved the precursor to ornithine transcarbamylase. The results indicate that some mitochondrial precursor proteins have tertiary structures which allow them to be recognized by all mitochondria while other mitochondrial precursor proteins have structures recognizable by only specialized mitochondria.     

Purification and analysis of phospholipids in the inner mitochondrial membrane fraction of bovine corpus luteum, and properties of cytochrome P-450scc incorporated into vesicles prepared from these phospholipids

Cytochrome P-450scc, which catalyses the conversion of cholesterol to pregnenolone in steroidogenic tissues, can be incorporated into artificial phospholipid vesicles and cholesterol binding to the cytochrome is affected by the composition of the vesicles. We have purified the phospholipids from the inner mitochondrial membrane fraction of the bovine corpus luteum where the cytochrome is located. The composition in mol % was 49% phosphatidylcholine, 34% phosphatidylethanolamine, 8.7% cardiolipin, 6.4% lysophosphatidylethanolamine and 1.5% phosphatidylinositol. The ratio of cholesterol to phospholipid (mol/mol) in the inner membrane fraction was 0.14 to 1. The Km for cholesterol of purified luteal cytochrome P-450scc incorporated into vesicles prepared from the total inner mitochondrial membrane phospholipids was 0.063 mol of cholesterol per mol of phospholipid. Removal of the cardiolipin component of the inner mitochondrial membrane phospholipids prior to preparation of vesicles caused a four fold increase in the Kd of cytochrome P-450 for cholesterol and a two fold increase in Km. The data suggests that in the inner mitochondrial membrane of the bovine corpus luteum the cholesterol concentration is less than saturating for cytochrome P-450scc.     

Cytochrome P-450scc induces vesicle aggregation through a secondary interaction at the adrenodoxin binding sites (in competition with protein exchange

Addition of bovine adrenal cytochrome P-450scc to small unilamellar dioleoylphosphatidylcholine vesicles (DOPC-SUV) produces a complex sequence of interactions, indicating exceptional cytochrome mobility. First, cholesterol transfer from cytochrome to vesicles indicated rapid dissociation of P-450scc oligomers and integration of monomers into the membrane (delta A 390-420 nm; t1/2 = 2 s). After 10-15 s, P-450scc-induced aggregation of the vesicles starts, as indicated by increased turbidity (delta A 448 or 520 nm; complete in 6-8 min). Fluorescence quenching experiments indicate that this aggregation does not lead to measurable vesicle fusion during this period. Aggregation is prevented by mild heat denaturation of P-450scc, by addition of anti-P-450scc IgG, and also by 1:1 complex formation with the electron donor adrenodoxin (ADX). P-450scc, therefore, links two vesicles through two separate domains involved in, respectively, membrane integration (lipophilic) and ADX binding (charged). Although completely bound by DOPC-SUV, as evidenced by Sephadex elution, P-450scc has access within 1 min to cholesterol in secondary SUV. This is indicated by spectral changes (cholesterol complex formation) and by metabolism of secondary vesicle cholesterol. Since cholesterol equilibrates slowly between vesicles (t1/2 = 1-2 h), these changes arise from P-450scc transfer. This transfer was maximally slowed after a 5-min preincubation with primary vesicles, reflecting more extensive integration into the membrane than is necessary for the rapid initial cholesterol transfer to P-450scc. P-450scc transfer probably results from simultaneous interaction of P-450scc with two vesicles that may also initiate aggregation. Weaker integration into primary dimyristoylphosphatidylcholine vesicles facilitates exchange but prevents aggregation. Integration and aggregation are both enhanced by incorporation of 10% phosphatidylinositol into SUV, while exchange is slowed. This mobility of P-450scc is most probably a consequence of the absence of amino-terminal anchoring. P-450scc-induced association of inner mitochondrial membrane segments may contribute to the exceptionally vesiculated structure of adrenal and ovarian mitochondria that parallels increased P-450scc content.     

GROWTH AND DIFFERENTIATION OF MITOCHONDRIA IN THE REGENERATING RAT ADRENAL CORTEX : A Correlated Biochemical and Stereological Approach

Diameters of the circular profiles of spherical mitochondria in parenchymal cells of the zona fasciculata in rat adrenal cortex were measured for intact controls and for the regenerating adrenal cortex on electron micrographs recorded at random. The diameter data were then processed by Bach's method which deals with the sphere size distribution. The structural parameters of the mitochondria were computed with the aid of an electronic computer. The total number of mitochondria in all the parenchymal cells of the zona fasciculata were calculated. The surface area of the inner mitochondrial membrane was then determined stereologically. Biochemical parameters were obtained for the protein, the phospholipid, and the cytochrome P-450 content, per averaged mitochondrion. The number of cytochrome P-450 molecules contained in the inner membrane was determined in terms of the unit surface area and of the unit amount of phospholipid. These correlated biochemical and stereological parameters have led to the following conclusions. (a) The genesis of the mitochondria after the adrenal enucleation is almost completed within 10 days. (b) During the period of mitochondrial proliferation, the mitochondria are small in size and also immature both in the structure and in the function of their inner membrane, (c) These small and immature mitochondria grow through an increase of the phospholipid and protein, and this increase is accompanied by expansion of the area of the membrane surface, (d) An enrichment of the inner membrane with cytochrome P-450 molecules occurs, thus indicating the differentiation of adrenocortical mitochondria. The process of membrane differentiation is not tightly coupled with that of membrane growth.     

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.     

Effects of phospholipid and detergent on the substrate specificity of adrenal cytochrome P-450scc. Substrate binding and kinetics of cholesterol side chain oxidation

Cytochrome P-450scc was isolated from mitochondria of bovine adrenal cortex by hydrophobic chromatography on octyl Sepharose followed by affinity chromatography on cholesterol-7-(thiomethyl)carboxy-3 beta-acetate-Sepharose. The partially purified eluate from the octyl Sepharose resin was free of adrenodoxin and adrenodoxin reductase and displayed biphasic binding characteristics for cholesterol, cholesterol sulfate, and cholesterol acetate (CA). Chromatography of the octyl Sepharose eluate on CA-Sepharose removed extraneous proteins and resolved the cytochrome P-450scc into two fractions, each of which displayed monophasic binding with all three substrates. These fractions behaved identically with respect to their ability to bind substrates, their kinetic properties, and their rate of migration during sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The dissociation constants of the cytochrome P-450scc.substrate complexes are 1.1, 2.6, and 1.3 microM for cholesterol, cholesterol sulfate, and cholesterol acetate, respectively. Addition of phospholipids isolated from adrenal cortex mitochondria or adrenodoxin had no effect on the equilibrium binding constants. Addition of Emulgen 913, however, decreased the binding affinities 10-20-fold. Emulgen 913 also inhibited the interaction of adrenodoxin with the cytochrome. An active side chain cleavage system was reconstituted with purified P-450 by addition of saturating amounts of adrenodoxin, adrenodoxin reductase, and NADPH-generating system. The apparent Km values for this reconstituted system of cholesterol, cholesterol sulfate, and cholesterol acetate are 1.8, 1.9, and 0.6 microM, respectively. Since the Km values of substrate oxidation are similar to the Kd values of the cytochrome P-450.substrate complexes, it seems likely that the binding of substrates, particularly when the side chain cleavage system is free of mitochondrial membranes, is not rate-limiting. Based on these results and electrophoretic data, it appears that one cytochrome P-450 present in adrenal mitochondria can oxidize cholesterol, its sulfate, and its acetate. This enzyme represented about 60% of the cytochrome P-450 present in the octyl Sepharose eluate. The factors responsible for the biphasic kinetics of oxidation by intact mitochondria and biphasic binding of sterol substrates by partially purified preparations of cytochrome P-450scc are still unknown.     

Stimulation by endozepine of the side-chain cleavage of cholesterol in a reconstituted enzyme system

Addition of endozepine in nanomolar concentrations to a system for side-chain cleavage reconstituted from highly purified P-450scc and electron carriers (adrenodoxin reductase and adrenodoxin) stimulates the conversion of cholesterol to pregnenolone (side-chain cleavage). This response is concentration and time-dependent and specific to the extent that a second steroidogenic P-450 located in the inner mitochondrial membrane (ie 11 beta-hydroxylase) was not stimulated by endozepine. Homogeneous endozepine prepared from bovine brain, the corresponding genetically engineered peptide and des(glu-ilu)-endozepine isolated from bovine adrenal cortex are all approximately equipotent in this system. Moreover, endozepine accelerates the rate of reduction of P-450scc by NADPH and the electron carriers. The results suggest that endozepine acts directly on P-450 and hence the rate of side-chain cleavage.     

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 active form of cytochrome P-45011beta from adrenal cortex mitochondria.

Cytochrome P-45011beta has been solubilized and partially purified from bovine adrenal cortex mitochondria by means of chromatography on Octyl-Sepharose CL-4B or DEAE-Sepharose CL-6B. The partially purified P-450 preparations were about 90% pure as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, but had a low specific content of P-450 (between 1 and 2 nmol of P-450 per mg of protein). In the presence of purified preparations of adrenodoxin reductase and adrenodoxin, the partially purified P-450 preparations catalyzed NADPH-supported 11beta-hydroxylation of unconjugated and sulfoconjugated deoxycorticosterone. In the reconstituted system the hydroxylation of deoxycorticosterone sulfate proceeded at a much higher rate than in intact mitochondria, indicating that in the former case interactions between the hydrophilic substrate and P-450 were facilitated. In the presence of Triton X-100 the partially purified cytochrome P-45011beta had a Stokes radius of 4.5 nm, a sedimentation coefficient of 3.1 S, and a partial specific volume of about 0.85 cm3/g. These results indicate that the cytochrome P-45011beta . Triton X-100 complex had a molecular weight of about 100,000 and that P-45011beta bound about 1.1 g of Triton X-100 per g of protein. The P-45011beta . Triton X-100 complex was catalytically active in hydroxylation reactions supported by NADPH or the hydroxylating agent ortho-nitroiodosobenzene, suggesting that the monomer of cytochrome P-45011beta is the active form of the protein.