The interaction of bovine adrenodoxin with CYP11A1 (cytochrome P450scc) and CYP11B1 (cytochrome P45011beta ). Acceleration of reduction and substrate conversion by site-directed mutagenesis of adrenodoxin.

The kinetics of protein-protein interaction and heme reduction between adrenodoxin wild type as well as eight mutants and the cytochromes P450 CYP11A1 and CYP11B1 was studied in detail. Rate constants for the formation of the reduced CYP11A1.CO and CYP11B1.CO complexes by wild type adrenodoxin, the adrenodoxin mutants Adx-(4-108), Adx-(4-114), T54S, T54A, and S112W, and the double mutants Y82F/S112W, Y82L/S112W, and Y82S/S112W (the last four mutants are Delta113-128) are presented. The rate constants observed differ by a factor of up to 10 among the respective adrenodoxin mutants for CYP11A1 but not for CYP11B1. According to their apparent rate constants for CYP11A1, the adrenodoxin mutants can be grouped into a slow (wild type, T54A, and T54S) and a fast group (all the other mutants). The adrenodoxin mutants forming the most stable complexes with CYP11A1 show the fastest rates of reduction and the highest rate constants for cholesterol to pregnenolone conversion. This strong correlation suggests that C-terminal truncation of adrenodoxin in combination with the introduction of a C-terminal tryptophan residue enables a modified protein-protein interaction rendering the system almost as effective as the bacterial putidaredoxin/CYP101 system. Such a variation of the adrenodoxin structure resulted in a mutant protein (S112W) showing a 100-fold increased efficiency in conversion of cholesterol to pregnenolone.     

Probing the interaction of bovine cytochrome P450scc (CYP11A1) with adrenodoxin: evaluating site-directed mutations by molecular modeling

The present study was undertaken to evaluate the role of positively charged amino acid residues proposed to reside on the proximal surface of bovine cytochrome P450 cholesterol side chain cleavage (P450scc, CYP11A1) and to determine which residues may be involved in protein-protein interactions with the electron carrier adrenodoxin (Adx). In previous studies, nine different lysine residues were identified by chemical and immunological cross-linking experiments as potentially interacting with Adx, while in the present study, two arginine residues have been identified from sequence alignments. From these 11 residues, 13 different P450scc mutants were made of which only seven were able to be expressed and characterized. Each of the seven mutants were evaluated for their ability to bind Adx, to be reduced, and for their enzymatic activity. Among these, K403Q and K405Q showed a consistent decrease in Adx binding, the ability to be reduced by Adx, and enzymatic activity, with K405Q being affected to a much greater extent. More dramatic was the complete loss of Adx binding by R426Q, while still retaining its ability to be chemically reduced and bind carbon monoxide. Independently, a homology model of P450scc was constructed and docked with the structure of Adx. Four potential sites of interaction were identified: P450scc:K403 with Adx:D76, P450scc:K405 with Adx:D72; P450scc:R426 with Adx:E73, and P450scc:K267 with Adx:E47. Thus, the biochemical and molecular modeling studies together support the hypothesis that K267, K403, K405, and R426 participate in the electrostatic interaction of P450scc with Adx.     

Deletions in the loop surrounding the iron-sulfur cluster of adrenodoxin severely affect the interactions with its native redox partners adrenodoxin reductase and cytochrome P450(scc) (CYP11A1)

The redox active iron-sulfur center of bovine adrenodoxin is coordinated by four cysteine residues in positions 46, 52, 55 and 92 and is covered by a loop containing the residues Glu-47, Gly-48, Thr-49, Leu-50 and Ala-51. In plant-type [2Fe-2S] ferredoxins, the corresponding loop consists of only four amino acids. The loop is positioned at the surface of the proteins and forms a boundary separating the [2Fe-2S] cluster from solvent. In order to analyze the biological function of the five amino acids of the loop in adrenodoxin (Adx) for this electron transfer protein each residue was deleted by site-directed mutagenesis. The resulting five recombinant Adx variants show dramatic differences among each other regarding their spectroscopic characteristics and functional properties. The redox potential is affected differently depending on the position of the conducted deletion. In contrast, all mutations in the protein loop influence the binding to the redox partners adrenodoxin reductase (AdR) and cytochrome P450(scc) (CYP11A1) indicating the importance of this loop for the physiological function of this iron--sulfur protein.     

Active complex between adrenodoxin reductase and adrenodoxin in the cytochrome P-450scc reduction reaction

In order to elucidate the mechanism of the electron transfer reaction of mitochondrial steroid hydroxylase, the reduction reaction of cytochrome P-450scc (P-450scc) catalyzed by covalently cross-linked complexes between adrenodoxin reductase (AR) and adrenodoxin (AD) was studied. The reduction rate with the covalent AR-AD complex was very slow (0.030 min-1, as the flavin turnover number) compared with the reduction catalyzed by AR and AD (4.6 min-1). When free AD was added to the reaction mixture containing the AR-AD complex, the rate increased about 30 times. The AD dimer [(AD)2], and a complex between AR and the AD dimer [AR-(AD)2] were then prepared. The Vmax for the P-450scc reduction activity of AR with (AD)2 was 50% of that of AR with AD. The Km value for the total concentration of AD in the P-450scc reduction reaction mixture containing AR and (AD)2 was found to be the same as that in the reaction mixture containing AR and AD. P-450scc reduction by AR-(AD)2 was about 5 times faster than that by AR-AD. The addition of free AD to the AR-(AD)2 complex enhanced the P-450scc reduction about 30 times. AR-AD and AR-(AD)2 were able to reduce external AD, cytochrome c, and acetylated cytochrome c.(ABSTRACT TRUNCATED AT 250 WORDS)     

Phosphorylation of bovine adrenodoxin by protein kinase CK2 affects the interaction with its redox partner cytochrome P450scc (CYP11A1)

Adrenodoxin (Adx), a [2Fe-2S] vertebrate-type ferredoxin, transfers electrons from the NADPH-dependent flavoprotein Adx reductase (AdR) to mitochondrial cytochrome P450 enzymes of the CYP11A and CYP11B families, which catalyze key reactions in steroid hormone biosynthesis. Adx is a known phosphoprotein, but the kinases that phosphorylate Adx have remained mostly obscure. The aim of this study was to identify previously unknown Adx phosphorylating kinases and to acquire a deeper insight into the functional consequences of such a modification. Here, we show for the first time that bovine Adx is a substrate of protein kinase CK2, whereas bovine CYP11A1, CYP11B1, and AdR are not phosphorylated by this kinase. CK2 phosphorylation of mature Adx requires the presence of both the catalytic alpha-subunit and the regulatory beta-subunit of CK2 and takes place exclusively at residue Thr-71, which is located within the redox partner interaction domain of the protein. We created two Adx mutants, Adx-T71E (imitating a phosphorylation) and Adx-T71V (which cannot be phosphorylated at this site), respectively, and investigated how these mutations affected the interaction of Adx with its redox partners. These data were supplemented with detailed spectroscopic and functional assays using the phosphorylated protein. All Adx species behaved like wild type (Adx-WT) with respect to their redox potential, iron-sulfur cluster symmetry, and overall backbone structure. Substrate conversion assays catalyzed by CYP11A1 showed an increase in product formation when Adx-T71E or CK2-phosphorylated Adx were used as electron carrier instead of Adx-WT, whereas the activity toward CYP11B1 was not altered using these Adx species. Additionally, Adx-T71E represents the only full-length Adx mutant which leads to an increase in CYP11A1 product formation. Therefore, characterizing this full-length mutant helps to improve our knowledge on the functional effects of phosphorylations on complex redox systems.     

The F-G loop region of cytochrome P450scc (CYP11A1) interacts with the phospholipid membrane

Cytochrome P450scc (CYP11A1) is a protein attached to the inner surface of the inner mitochondrial membrane that uses cholesterol from the membrane phase as its substrate for the first step in steroid hormone synthesis. We investigated the mechanism by which CYP11A1 interacts with the membrane. Hydrophobicity profiles of CYP11A1 and two other mitochondrial cytochromes P450, plus a model structure of CYP11A1 using CYP2C5 as template, suggest that CYP11A1 has a monotopic association with the membrane which may involve the A' helix and the F-G loop. Deletion of the A' helix reduced the proportion of expressed CYP11A1 associated with the bacterial membrane fraction, indicating a role for the A' helix in membrane binding. However, introduction of a cysteine residue in this helix at position 24 (L24C) and subsequent labelling with the fluorescent probe N'-(7-nitrobenz-2-oxal,3-diazol-4-yl)ethylenediamine (NBD) failed to show a membrane localisation. Cysteine mutagenesis and fluorescent labelling of other residues appearing on the distal surface of the CYP11A1 model revealed that V212C and L219C have enhanced fluorescence and a blue shift following association of the mutant CYP11A1 with phospholipid vesicles. This indicates that these residues, which are located in the F-G loop, become localised to a more hydrophobic environment following membrane binding. Analysis of the quenching of tryptophan residues in CYP11A1 by acrylamide indicates that at least one and probably two tryptophans are involved in membrane binding. We conclude that CYP11A1 has a monotopic association with the membrane that is mediated, at least in part, by the F-G loop region.     

Interaction of CYP11B1 (cytochrome P-45011 beta) with CYP11A1 (cytochrome P-450scc) in COS-1 cells.

The interactions of CYP11B1 (cytochrome P-45011beta), CYP11B2 (cytochrome P-450aldo) and CYP11A1 (cytochrome P-450scc) were investigated by cotransfection of their cDNA into COS-1 cells. The effect of CYP11A1 on CYP11B isozymes was examined by studying the conversion of 11-deoxycorticosterone to corticosterone, 18-hydroxycorticosterone and aldosterone. It was shown that when human or bovine CYP11B1 and CYP11A1 were cotransfected they competed for the reducing equivalents from the limiting source contained in COS-1 cells; this resulted in a decrease of the CYP11B activities without changes in the product formation patterns. The competition of human CYP11A1 with human CYP11B1 and CYP11B2 could be diminished with excess expression of bovine adrenodoxin. However, the coexpression of bovine CYP11B1 and CYP11A1 in the presence of adrenodoxin resulted in a stimulation of 11beta-hydroxylation activity of CYP11B1 and in a decrease of the 18-hydroxycorticosterone and aldosterone formation. These results suggest that the interactions of CYP11A1 with CYP11B1 and CYP11B2 do not have an identical regulatory function in human and in bovine adrenal tissue.     

Kinetics of vitamin D3 metabolism by cytochrome P450scc (CYP11A1) in phospholipid vesicles and cyclodextrin

Vitamin D3 can be hydroxylated sequentially by cytochrome P450scc (CYP11A1) producing 20-hydroxyvitamin D3, 20,23-dihydroxyvitamin D3 and 17,20,23-trihydroxyvitamin D3. The aim of this study was to characterize the ability of vitamin D3 to associate with phospholipid vesicles and to determine the kinetics of metabolism of vitamin D3 by P450scc in vesicles and in 2-hydroxypropyl-beta-cyclodextrin (cyclodextrin). Gel filtration of phospholipid vesicles showed that the vitamin D3 remained quantitatively associated with the phospholipid membrane. Vitamin D3 exchanged between vesicles at a rate 3.8-fold higher than for cholesterol exchange and was stimulated by N-62 StAR protein. The Km of P450scc for vitamin D3 in vesicles was 3.3 mol vitamin D3/mol phospholipid and the rate of conversion of vitamin D3 to 20-hydroxyvitamin D3 was first order with respect to the vitamin D3 concentration for the range of concentrations of vitamin D3 that could be incorporated into the vesicle membrane. 20-Hydroxyvitamin D3 was further hydroxylated by P450scc in vesicles, producing primarily 20,23-dihydroxyvitamin D3, with Km and kcat values 22- and 6-fold lower than those for vitamin D3, respectively. 20,23-dihydroxyvitamin D3 was converted to 17,20,23-trihydroxyvitamin D3 with even lower Km and kcat values. Vitamin D3 and cholesterol were metabolized with comparable efficiencies in cyclodextrin, but the Km for both showed a strong dependence on the cyclodextrin concentration, decreasing with decreasing cyclodextrin. This study shows that vitamin D3 quantitatively associates with phospholipid vesicles, can exchange between membranes, and can be hydroxylated by membrane-associated P450scc but with lower efficiency than for cholesterol hydroxylation. The kcat values for metabolism of vitamin D3 in vesicles and 0.45% cyclodextrin are similar, but the ability to solubilize vitamin D3 at a concentration higher than its Km makes the cyclodextrin system more efficient for producing the hydroxyvitamin D3 metabolites for further characterization.     

Electrostatic interaction between cytochrome P450 and NADPH-P450 reductase: comparison of mixed and fused systems consisting of rat cytochrome P450 1A1 and yeast NADPH-P450 reductase

The electrostatic interaction between rat cytochrome P450 1A1 and yeast NADPH-P450 reductase was analyzed by using recombinant yeast microsomes containing both native enzymes or their fused enzyme. The Vmax of the 7-ethoxycoumarin O-deethylation in the recombinant microsomes containing both rat cytochrome P4501A1 and yeast NADPH-P450 reductase (the mixed system) was maximal when the ionic strength of the reaction mixture was 0.1-0.15. However, on the fused enzyme between rat cytochrome P450 1A1 and yeast NADPH-P450 reductase (the fused system), the activity was uniformly reduced with increasing ionic strength. The pH profiles of Vmax were also different between the mixed and the fused systems. Based on these results, we propose a hypothesis that cytochrome P450 and NADPH-P450 reductase have more than one binding mode. The maximal activity of the mixed system at ionic strength of 0.1-0.15 is explained by change of the binding mode. On the other hand, the fused enzyme appears to have only one binding mode due to the limited topology of cytochrome P450 and NADPH-P450 reductase domains.     

Brain mitochondrial cytochrome P-450scc: spectral and catalytic properties

The cytochrome P-450-dependent cholesterol side chain cleavage system of the brain has been studied using nonsynaptic mitochondria as the source of enzymatic activity. The system has been found to bind cholesterol and 11-deoxycorticosterone, producing type I difference spectra, whereas the binding of pregnenolone induced a reverse type I difference spectrum. Inhibitors of cytochrome P-450-linked monooxygenase activities produced type II spectra. The formation of labeled pregnenolone after incubation of brain mitochondria with [4-14C]cholesterol has been obtained, and this formation was inhibited by glutethimide, a specific inhibitor of cytochrome P-450scc. The functional significance of this enzymatic activity is discussed.     

Modification of histidine 56 in adrenodoxin with diethyl pyrocarbonate inhibited the interaction with cytochrome P-450scc and adrenodoxin reductase

Three histidine residues of bovine adrenodoxin, His-10, His-56, and His-62, were modified with diethyl pyrocarbonate. The order of the modification among the three histidines were monitored by measuring the proton NMR spectra. The modified adrenodoxin exhibited reduced affinity for adrenodoxin reductase as determined in cytochrome c reductase activity. In the presence of cholesterol, the modified adrenodoxin induced a high spin form of cytochrome P-450scc on complex formation in the same manner as native adrenodoxin. The spectral titration showed that adrenodoxin modified with diethyl pyrocarbonate exhibited a 5-fold higher Kd value than that of native adrenodoxin. These effects of the modification of adrenodoxin on the affinities for the redox partners were not proportional to the number of modified histidines determined by the optical absorbance change at 240 nm. Modification of adrenodoxin up to 2 histidine residues did not affect the affinity for the redox partners, but further modification on the third one resulted in an increase of apparent Km in cytochrome c reductase activity by 2-fold and of Kd for cytochrome P-450scc by 5-fold. The 1H NMR spectra of the modified adrenodoxin unequivocally demonstrated that histidine residues at His-10 and His-62 reacted more readily with diethyl pyrocarbonate than His-56 did, indicating that modification of His-56 was responsible for the reduction of binding affinities of adrenodoxin for redox partners. These results are consistent with the proposal that the residue of His-56 in adrenodoxin has an essential role in the electron transfer mechanism where adrenodoxin functions as a mobile shuttle.     

The use of a specific fluorescence probe to study the interaction of adrenodoxin with adrenodoxin reductase and cytochrome P-450scc

The single free cysteine at residue 95 of bovine adrenodoxin was labeled with the fluorescent reagent N-iodoacetylamidoethyl-1-aminonaphthalene-5-sulfonate (1,5-I-AEDANS). The modification had no effect on the interaction with adrenodoxin reductase or cytochrome P-450scc, suggesting that the AEDANS group at Cys-95 was not located at the binding site for these molecules. Addition of adrenodoxin reductase, cytochrome P-450scc, or cytochrome c to AEDANS-adrenodoxin was found to quench the fluorescence of the AEDANS in a manner consistent with the formation of 1:1 binary complexes. F?rster energy transfer calculations indicated that the AEDANS label on adrenodoxin was 42 A from the heme group in cytochrome c, 36 A from the FAD group in adrenodoxin reductase, and 58 A from the heme group in cytochrome P-450scc in the respective binary complexes. These studies suggest that the FAD group in adrenodoxin reductase is located close to the binding domain for adrenodoxin but that the heme group in cytochrome P-450scc is deeply buried at least 26 A from the binding domain for adrenodoxin. Modification of all the lysines on adrenodoxin with maleic anhydride had no effect on the interaction with either adrenodoxin reductase or cytochrome P-450scc, suggesting that the lysines are not located at the binding site for either protein. Modification of all the arginine residues with p-hydroxyphenylglyoxal also had no effect on the interaction with adrenodoxin reductase or cytochrome P-450scc. These studies are consistent with the proposal that the binding sites on adrenodoxin for adrenodoxin reductase and cytochrome P-450scc overlap, and that adrenodoxin functions as a mobile electron carrier.     

Purification and catalytic properties of a cross-linked complex between adrenodoxin reductase and adrenodoxin

A stable covalent complex was prepared by cross-linking adrenodoxin reductase with adrenodoxin using 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide. The covalent complex was purified extensively until free components were removed completely. The major component of the complex had a molecular weight of 63 kDa, which corresponds to a 1:1 stoichiometric complex between adrenodoxin reductase and adrenodoxin. NADPH-cytochrome c reduction activity of the covalent complex was comparable to that of an equimolar mixture of adrenodoxin reductase and adrenodoxin (native complex), and the NADPH-ferricyanide reduction activity of the complex was equal to that of the native one. In contrast to the native complex, the covalent complex produced much less superoxide upon NADPH-oxidation, and the covalent complex was found to be more stable than the native complex, suggesting that the complex state is more favorable for catalysis. From these results, we conclude that the adrenodoxin molecule does not need to dissociate from the complex during electron transfer from NADPH to cytochrome c.     

Comparative study of topogenesis of cytochrome P450scc (CYP11A1) and its hybrids with adrenodoxin expressed in <Emphasis Type=Italic>Escherichia coli</Emphasis> cells

Hybrid proteins consisting of the mature form of cytochrome P450scc (mP) and adrenodoxin (Ad), attached to either the NH2- or COOH-terminus (Ad-mP and mP-Ad, respectively), were expressed in E. coli. Spectral and catalytic properties of P450scc were studied using the membrane fraction of E. coli cells. It has been shown that the Ad amino acid sequence attached to the termini of the P450scc-domain neither affects the insertion of a hybrid protein into the cytoplasmic membrane nor influences its heme binding ability. The results suggest that Ad attached to the NH2-terminus does not markedly affect the folding of the P450scc-domain, but cholesterol hydroxylase/lyase activity of the Ad-mP hybrid was found to be much lower than that of the native P450scc enzyme. The modification of the COOH-terminus does not alter the specific P450scc activity, but results in a dramatic increase in the amount of hybrid protein with incorrectly folded P450scc domain.     

The concentration of adrenodoxin reductase limits cytochrome p450scc activity in the human placenta.

We have previously reported that cytochrome P450scc activity in the human placenta is limited by the supply of electrons to the P450scc [Tuckey, R. C., Woods, S. T. & Tajbakhsh, M. (1997) Eur. J. Biochem. 244, 835-839]. The aim of the present study was to determine whether it is adrenodoxin reductase, adrenodoxin or both which limits cytochrome P450scc activity and hence progesterone synthesis in the placenta. We found that the concentrations of adrenodoxin reductase and adrenodoxin in placental mitochondria were both considerably lower than the concentrations of these proteins in the bovine adrenal cortex. When P450scc activity assays were carried out at high mitochondrial protein concentrations, we found that the addition of exogenous adrenodoxin reductase to sonicated mitochondria rescued pregnenolone synthesis to a level above that for intact mitochondria, showing that adrenodoxin is near-saturating in vivo. In contrast, pregnenolone synthesis by sonicated mitochondria was almost zero even after the addition of human adrenodoxin. This shows that the concentration of endogenous adrenodoxin reductase was insufficient to support appreciable rates of pregnenolone synthesis, even when concentrated mitochondrial samples were used. Comparative studies with human and bovine adrenodoxin reductase have revealed that a twofold higher concentration of human adrenodoxin reductase is required for maximal P450scc activity in the presence of saturating human adrenodoxin. Thus, not only is the adrenodoxin concentration low in placental mitochondria, but the amount required for maximal P450scc activity is higher than that for the bovine reductase. Overall, the data indicate that the adrenodoxin reductase concentration limits the activity of P450scc in placental mitochondria and hence determines the rate of progesterone synthesis.     

Adrenodoxin (Adx) and CYP11A1 (P450scc) induce apoptosis by the generation of reactive oxygen species in mitochondria

Mitochondrial cytochrome P450 systems are an indispensable component of mammalian steroid biosynthesis; they catalyze regio- and stereo-specific steroid hydroxylations and consist of three protein entities: adrenodoxin reductase (AdR), adrenodoxin (Adx), and a mitochondrial cytochrome P450 enzyme, e.g., CYP11A1 (P450 side chain cleavage, P450scc). It is known that the latter two are able to generate reactive oxygen species (ROS) in vitro . In this study, we investigated whether this ROS generation also occurs in vivo and, if so, whether it leads to the induction of apoptosis. We found that overexpression of either human or bovine Adx causes a significant loss of viability in 11 different cell lines. This loss of viability does not depend on the presence of the tumor suppressor protein p53. Transient overexpression of human Adx in HCT116 cells leads to ROS production, to a disruption of the mitochondrial transmembrane potential (DeltaPsi), to cytochrome c release from the mitochondria, and to caspase activation. In contrast, the effect of transient overexpression of human CYP11A1 on cell viability varies in different cell lines, with some being sensitive and others not. We conclude that mitochondrial cytochrome P450 systems are a source of mitochondrial ROS production and can play a role in the induction of mitochondrial apoptosis.     

Covalently crosslinked complexes of bovine adrenodoxin with adrenodoxin reductase and cytochrome P450scc. Mass spectrometry and Edman degradation of complexes of the steroidogenic hydroxylase system.

NADPH-dependent adrenodoxin reductase, adrenodoxin and several diverse cytochromes P450 constitute the mitochondrial steroid hydroxylase system of vertebrates. During the reaction cycle, adrenodoxin transfers electrons from the FAD of adrenodoxin reductase to the heme iron of the catalytically active cytochrome P450 (P450scc). A shuttle model for adrenodoxin or an organized cluster model of all three components has been discussed to explain electron transfer from adrenodoxin reductase to P450. Here, we characterize new covalent, zero-length crosslinks mediated by 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide between bovine adrenodoxin and adrenodoxin reductase, and between adrenodoxin and P450scc, respectively, which allow to discriminate between the electron transfer models. Using Edman degradation, mass spectrometry and X-ray crystallography a crosslink between adrenodoxin reductase Lys27 and adrenodoxin Asp39 was detected, establishing a secondary polar interaction site between both molecules. No crosslink exists in the primary polar interaction site around the acidic residues Asp76 to Asp79 of adrenodoxin. However, in a covalent complex of adrenodoxin and P450scc, adrenodoxin Asp79 is involved in a crosslink to Lys403 of P450scc. No steroidogenic hydroxylase activity could be detected in an adrenodoxin -P450scc complex/adrenodoxin reductase test system. Because the acidic residues Asp76 and Asp79 belong to the binding site of adrenodoxin to adrenodoxin reductase, as well as to the P450scc, the covalent bond within the adrenodoxin-P450scc complex prevents electron transfer by a putative shuttle mechanism. Thus, chemical crosslinking provides evidence favoring the shuttle model over the cluster model for the steroid hydroxylase system.     

The formation of binary and ternary complexes of cytochrome P-450scc with adrenodoxin and adrenodoxin reductase.adrenodoxin complex. The implication in ACTH function.

Binary and ternary complexes of bovine adrenocortical mitochondrial cytochrome P-450scc with adrenodoxin and adrenodoxin reductase.adrenodoxin complex are formed in the presence of cholesterol and Emulgen 913. Both cholesterol and Emulgen 913 are required for the binding of cytochrome P-450scc with adrenodoxin. Since phospholipids are able to replace Emulgen 913 in this reaction, in vivo phospholipids of the mitochondrial inner membrane appear to play the function of the detergent. The dissociation constants of the cytochrome.adrenodoxin complex are 0.3 to 0.4 microM at 130 microM dimyristoylphosphatidylcholine and 0.9 microM at 120 microM Emulgen 913, whereas the dissociation constant for the ternary complex of cytochrome P-450scc with adrenodoxin reductase and adrenodoxin is 4.0 microM at 150 microM Emulgen 913. The stoichiometry of binary and ternary complexes reveals the 1:1 and 1:1:1 molar ratios, respectively, judging from chemical analyses after the fractionation of the complexes by gel filtration. Emulgen 913, Tween 20, ethylene glycol, myristoyllysophosphatidylcholine, dimyristoylphosphatidylcholine, and phosphatidylethanolamine show the enhanced activity of cholesterol side chain cleavage reaction with cytochrome P-450scc, adrenodoxin, adrenodoxin reductase, and NADPH. These results, in conjunction with earlier experiments, lead us to the proposal on the structure of the hydroxylase complex in the membrane and to the hypothesis on the regulation of the enzymatic activity by the availability of substrate cholesterol to the cytochrome. Hence, we propose a mobile P-450scc hypothesis for the response of the mitochondrion to adrenocorticotropic hormone stimuli.     

Conformational dynamics and molecular interaction reactions of recombinant cytochrome p450scc (CYP11A1) detected by fluorescence energy transfer.

Bovine adrenocortical cytochrome P450scc (P450scc) was expressed in Escherichia coli and purified as the substrate bound, high-spin complex (16.7 nmol of heme per mg of protein, expression level in E. coli about 400-700 nmol/l). The recombinant protein was characterized by comparison with native P450scc purified from adrenal cortex mitochondria. To study the interaction of the electron transfer proteins during the functioning of the heme protein, recombinant P450scc was selectively modified with fluorescein isothiocyanate (FITC). The present paper shows that modified P450scc, purified by affinity chromatography using adrenodoxin-Sepharose to remove non-covalently bound FITC, retains the functional activity of the unmodified enzyme, including its ability to bind adrenodoxin. Based on the efficiency of resonance fluorescence energy transfer in the donor-acceptor pair, FITC-heme, we calculated the distance between Lys(338), selectively labeled with the dye, and the heme of P450scc. The intensity of fluorescence from the label dramatically changes during: (a) denaturation of P450scc; (b) changing the spin state or redox potential of the heme protein; (c) formation of the carbon monoxide complex of reduced P450scc; (d) as well as during reactions of intermolecular interactions, such as changes of the state of aggregation, complex formation with the substrate, binding to the electron transfer partner adrenodoxin, or insertion of the protein into an artificial phospholipid membrane. Selective chemical modification of P450scc with FITC proved to be a very useful method to study the dynamics of conformational changes of the recombinant heme protein. The data obtained indicate that functionally important conformational changes of P450scc are large-scale ones, i.e. they are not limited only to changes in the dynamics of the protein active center. The results of the present study also indicate that chemical modification of Lys(338) of bovine adrenocortical P450scc does not dramatically alter the activity of the heme protein, but does result in a decrease of protein stability.     

Enzymatic properties of vesicle-reconstituted human cytochrome P450SCC (CYP11A1) differences in functioning of the mitochondrial electron-transfer chain using human and bovine adrenodoxin and activation by cardiolipin.

The recently reported heterologous expression and purification of both human cytochrome P450SCC and adrenodoxin [Woods, S.T., Sadleir, J., Downs, T., Triantopoulos, T., Haedlam, M.J. & Tuckey, R.C. (1998) Arch. Biochem. Biophys. 353, 109-115] has enabled us to perform studies with the membrane-reconstituted human enzymes to better understand the side-chain cleavage reaction in humans. Human P450SCC was successfully reconstituted into dioleoylphosphatidylcholine vesicles with and without cardiolipin and its enzymatic properties characterized in the membrane-bound state. Enhancement of the P450SCC activity and significant activation by cardiolipin were observed when human adrenodoxin instead of bovine adrenodoxin was used as electron donor. In the absence of cardiolipin, Km for cholesterol was decreased twice in the case of human adrenodoxin indicating enhanced cholesterol binding. On the other hand, in the presence of cardiolipin in the membrane both Km and V for cholesterol were decreased with human adrenodoxin as electron donor. Kinetic analysis of the interaction between human P450SCC and its redox partners provided evidence for enhanced binding of the human electron donor to human P450SCC indicated by both an increased V and decreased Kd for human adrenodoxin compared with the values with bovine adrenodoxin. Because no similar effects were observed in Tween 20 micelles, these results suggest that the phospholipid membrane may play an important role in the interaction of human adrenodoxin with human P450SCC.