Electron paramagnetic resonance study of ferrous cytochrome P-450scc-nitric oxide complexes: effects of cholesterol and its analogues

Electron paramagnetic resonance (EPR) spectra of nitric oxide (NO) complexes of ferrous cytochrome P-450scc were measured at 77 K for the first time without using the rapid-mixing and freeze-quenching technique. Without substrate the EPR spectra were very similar to those of cytochrome P-450cam (from Pseudomonas putida) and cytochrome P-450LM (from rat liver microsomes) with rhombic symmetry; gx = 2.071, gz = 2.001, gy = 1.962, and Az = 2.2 mT for 14NO complexes. Upon addition of substrates [such as cholesterol, 22(S)-hydroxycholesterol, 22(R)-hydroxycholesterol, 25-hydroxycholesterol, and 22-ketocholesterol], the EPR spectra exhibited many variations having rhombic symmetry in the major component and an additional minor component with less rhombic symmetry. Furthermore, addition of 20(S)-hydroxycholesterol caused a striking change in the EPR spectrum. The component with rhombic symmetry disappeared completely, and the component with less rhombic symmetry dominated (gx = 2.027, gz = 2.007, gy = 1.984, and Az = 1.76 mT for 14NO complexes). These observations suggest the existence of the following physiologically important natures: (1) the conformational flexibility of the active site of the enzyme due to the steric interaction between the substrate and the heme-bound ligand molecule and (2) the importance of the hydroxylation of the cholesterol side chain at the 20S position to proceed the side-chain cleavage reaction in cytochrome P-450scc.     

Electron paramagnetic resonance detectable states of cytochrome P-450cam

Cytochrome P-450cam is a low-spin Fe3+hemoprotein (g = 2.45, 2.26, and 1.91) which is made 60% high spin (g = 7.85, 3.97, and 1.78) at 12 K by the addition of 1 mol of substrate per mol of enzyme. Low-temperature EPR spectra show that the low-spin fraction of substrate-bound P-450cam contains two magnetic species. The majority species has an unusual EPR spectrum (g = 2.42, 2.24, and 1.97) which connot be simulated by using the range of crystal field parameters known for other heme proteins. The minority species has the same g values as substrate-free enzyme. Both low-spin species show Curie law temperature dependence below 50 K and have similar saturation behavior. Above 50 K the g = 2.42, 2.24, and 1.97 species rapidly loses signal intensity. The distribution of low-spin species is pH dependent (apparent pKa = 6.2) with the g = 2.42, 2.24, and 1.97 magnetic species favored at high pH. The substrate binding stoichiometry and the equilibria observed in the low-spin fraction suggest that there are not multiple protein forms of cytochrome P-450cam. Putidaredoxin and other effector molecules which specifically catalyze hydroxylation convert either the high-spin or the g = 2.42, 2.24, and 1.97 low-spin species to another new magnetic species (g = 2.47, 2.26, and 1.91). This species is only seen in the presence of substrate, and its stability reflects the catalytic potency of the effector molecule. The EPR and UV-visible spectra of cytochrome P-420 depend upon the manner in which the P-420 is generated. Incubation with acetone or reaction with N-ethylmaleimide or diethyl pyrocarbonate generates P-420 with different spectral characteristics. Through identification of active-site amino acids by chemical modification and comparison with porphyrin model complexes, the range of ligands likely to participate in each of the EPR detectable species is assigned. Mechanisms of interconversion of these species and their bearing on catalysis are discussed.     

Electron paramagnetic resonance studies of cytochrome P-450 in plant microsomes.

The technique of electron paramagnetic resonnance spectrometry has been applied to the study of plant microsomal electron-transport components. Only tulip-bulb microsomes were found to give strong enough signals to allow detailed study. At 77 K in the oxidised state, signals were observed at g values of 2.40, 2.25 and 1.93, characteristic of cytochrome P-450 in the low-spin state, and also at g = 4.27, attributable to ferric iron in a rhombic environment. The signals at g = 2.40, 2.25 and 1.93 disappeared upon reduction with sodium dithionite. At 10 K in the oxidised state, signals at g = 8.3 and 3.3 appeared, and these were attributed to high-spin cytochrome P-450. At this temperature a further signal at g = 6, due to cytochrome P-420, was seen in aged tulip-bulb microsomes. Redox titration of both high-spin and low-spin cytochrome P-450 gave the same apparent midpoint potential of -315 +/- mV at pH 6.8 and 25 degrees C. The significance of this value is discussed. Addition of "type I" or "type II" ligands to oxidized cytochrome P-450 caused an increase and a decrease, respectively, in the ratio of the high-spin to the low-spin form. A second effect of aniline, a type II ligand of cytochrome P-450, was to remove the g = 6 signal, suggesting that it also interacts with cytochrome P-420. No iron-sulphur proteins similar to those found in some other cytochrome P-450 electron-transport chains could be detected in any of the microsomes analysed.     

Electron paramagnetic resonance spectra of mitochondrial and microsomal cytochrome P-450 from the rat adrenal

The electron paramagnetic resonance (EPR) spectra of rat adrenal zona fasciculata mitochondria showed peaks corresponding to low spin ferric cytochrome P-450 with apparent g values of 2.424, 2.248 and 1.917, and weak signals due to high spin ferric cytochrome P-450 with g_x values of 8.08 and 7.80. The former is attributed to cholesterol side chain cleavage cytochrome P-450, the latter to 11β-hydroxylase cytochrome P-450. On addition of deoxycorticosterone the g = 7.80 signal was elevated and there was an associated drop in the low spin signal. As the pH was reduced from 7.4 to 6.1, the g = 8.08 signal increased with again a drop in intensity of the low spin signal. Mitochondria from the zona glomerulosa showed similar spectral properties to those described above. Addition of succinate, isocitrate or pregnenolone caused a loss of the g = 8.08 signal. Addition of calcium increased the magnitude of the g = 8.08 signal, and caused a slight reduction in the magnitude of the low spin signal. Also, addition of deoxycorticosterone, pregnenolone, succinate or isocitrate caused slight shifts of the outer lines of the low spin spectrum. Interaction of mitochondrial cytochrome P-450 with metyrapone and aminoglutethimide modified the low spin parameters. Adrenal microsomal cytochrome P-450 had low spin ferric g values of 2.417, 2.244 and 1.919 and high spin ferric g_xy values of 7.90 and 3.85, distinct from the values obtained with mitochondria.     

Active site of bovine adrenocortical cytochrome P-450(11) beta studied by resonance Raman and electron paramagnetic resonance spectroscopies: distinction from cytochrome P-450scc

Cytochrome P-45011 beta was purified as the 11-deoxycorticosterone-bound form from bovine adrenocortical mitochondria and its active site was investigated by resonance Raman and EPR spectroscopies. Resonance Raman spectra of the purified sample revealed that the heme iron adopts the pure pentacoordinated ferric high-spin state on the basis of the nu 10 (1629cm-1) and nu 3 (1490 cm-1) mode frequencies, which are higher than those of the hexacoordinated ferric high-spin cytochrome P-450scc-substrate complexes. In the ferrous-CO state, a Fe2(+)-CO stretching mode was identified at 481.5 cm-1 on the basis of an isotopic substitution technique; this frequency is very close to that of cytochrome P-450scc in the cholesterol-complexed state (483 cm-1). The EPR spectra of the purified sample at 4.2 K showed ferric high-spin signals (at g = 7.98, 3.65, and 1.71) that were clearly distinct from the cytochrome P-450scc ferric high-spin signals (g = 8.06, 3.55, and 1.68) and confirmed previous assignments of ferric high-spin signals in adrenocortical mitochondria. The EPR spectra of the nitric oxide (NO) complex of ferrous cytochrome P-45011 beta showed EPR signals with rhombic symmetry (gx = 2.068, gz = 2.001, and gy = 1.961) very similar to those of the ferrous cytochrome P-450scc-NO complex in the presence of 22(S)-hydroxycholesterol and 20(R),22-(R)-dihydroxycholesterol at 77 K.(ABSTRACT TRUNCATED AT 250 WORDS)     

Conformational change of the heme moiety of the ferrous cytochrome P-450scc-phenyl isocyanide complex upon binding of reduced adrenodoxin

Reduction of cytochrome P-450scc(SF) (SF, substrate free) purified from bovine adrenocortical mitochondria with sodium dithionite (Na2S2O4) or with beta-NADPH mediated by catalytic amounts of adrenodoxin and adrenodoxin reductase in the presence of phenyl isocyanide produced a ferrous cytochrome P-450scc(SF)-phenyl isocyanide complex with Soret absorbance maximum at 455 nm having a shoulder at 425 nm. On the other hand, when a preformed cytochrome P-450scc(SF)-adrenodoxin complex was reduced chemically or enzymatically under the same conditions, the absorbance spectrum showed drastic changes, i.e., an increase in intensity at 425 nm and a concomitant decrease in intensity at 455 nm. Similar spectral changes could be produced by addition of the same amount of reduced adrenodoxin afterward to the ferrous cytochrome P-450scc(SF)-phenyl isocyanide complex. Titration experiments with adrenodoxin showed that (1) a 1:1 stoichiometric saturation of the spectral change was obtained for both the absorbance increase at 425 nm and the absorbance decrease at 455 nm, (2) there was no spectral change in the presence of 0.35 M NaCl, and (3) there was no spectral change for cytochrome P-450scc(SF) whose Lys residue(s) essential to the interaction with adrenodoxin had been covalently modified with PLP. These results suggest that ternary complex formation of ferrous cytochrome P-450scc(SF)-phenyl isocyanide with reduced adrenodoxin caused a conformational change around the ferrous heme moiety. By analysis of temperature and pH dependencies of the spectral change of the ternary complex, it was suggested that this conformational change may reflect the essential step for electron transfer from reduced adrenodoxin to the ferrous-dioxygen complex of cytochrome P-450scc.     

Electron paramagnetic resonance studies on hepatic microsomal cytochrome P-450 from a marine teleost fish

Hepatic microsomal cytochrome P-450 from fish (Stenotomus versicolor), untreated or treated with 3-methylcholanthrene, 5, 6-benzoflavone, or tricaine methanesulfonate, exhibited an absorption maximum at 450 nm when reduced and ligated to CO. Microsomes from all groups exhibited EPR spectra with g values near 2.4, 2.24 and 1.9, yielding crystal field parameters similar to those for cytochrome P-450 from a variety of other sources. Treatment with 3-methylcholanthrene or 5, 6-benzoflavone resulted in elevated levels of aryl hydrocarbon (benzo[a]pyrene) hydroxylase activity yet produced no apparent change in the levels or optical properties of CO-ligated cytochrome P-450. Tricaine methanesulfonate, a common fish anaesthetic, caused a decrease in the levels of fish cytochrome P-450.     

Electron paramagnetic resonance spectra of mitochondrial and microsomal cytochrome P-450 from the rat adrenal.

The electron paramagnetic resonance (EPR) spectra of rat adrenal zona fasciculate mitochondria showed peaks corresponding to low spin ferric cytochrome P-450 with apparent g values of 2.424, 2.248 and 1.917, and weak signals due to high spin ferric cytochrome P-450 with gx values of 8.08 and 7.80. The former is attributed to cholesterol side chain cleavage cytochrome P-450, the latter to 11beta-hydroxylase cytochrome P-450. On addition of deoxycorticosterone the g = 7.80 signal was elevated and there was an associated drop in the low spinal signal. As the pH was reduced from 7.4 to 6.1, the g = 8.08 signal increased with again a drop in intensity of the low spin signal. Mitochondria from the zona glomerulosa showed similar spectral properties to those described above. Addition of succinate, isocitrate or pregnenolone caused a loss of the g = 8.08 signal. Addition of calcium increased the magnitude of the g = 8.08 signal, and caused a slight reduction in the magnitude of the low spin signal. Also, addition of deoxycorticosterone, pregnenolone, succinate or isocitrate caused slight shifts of the outer lines of the low spin spectrum. Interaction of mitochondrial cytochrome P-450 with metyrapone and aminoglutethimide modified the low spinal parameters. Adrenal microsomal cytochrome P-450 had low spin ferric g values of 2.417, 2.244 and 1.919 and a high spin ferric gxy values of 7.90 and 3.85, distinct from the values obtained with mitochondria.     

Renal cytochrome P-450's-electrophoretic and electron paramagnetic resonance studies.

The cytochrome P-450's of the microsomal mixed function oxidase systems from the rabbit renal cortex, outer medulla, inner medulla, and the liver were compared. Sodium dodecyl sulfate-(SDS) gel electrophoresis and electron paramagnetic resonance (EPR) studies detected cytochrome P-450 proteins in the liver, renal cortex, and outer medulla but not the inner medulla of normal animals. Two cytochrome P-450 peptides, which had molecular weights of 54,500 and 58,900 and which comigrated with known hepatic cytochrome P-450's on SDS gels, were identified in the cortex and outer medulla. Treatment of animals with 3-methylcholanthrene (MC) enhanced the 54,500 and 58,900 peptides in the liver and cortex but produced little change in outer medulla. MC treatment induced faint cytochrome P-450 bands in the inner medulla. The EPR studies detected low spin heme iron absorption lines at g = 2.42, 2.26, and 1.92 in liver, cortex, and outer medulla from untreated animals. The amplitude of the low spin absorption lines was increased by ethanol, a reverse type I compound, and reduced by chloroform, a type I compound, in these tissues. MC treatment increased the amplitude of the heme absorption lines in these tissues, and it induced a barely detectable heme spectrum in the inner medulla. Differences in exogenous substrate binding between hepatic and renal microsomes from MC-treated animals were detected by EPR and optical difference spectroscopy. Acetone, 1-butanol, and 2-propanol gave evidence of binding to the hepatic cytochrome P-450's but no evidence of binding to renal cortical microsomes. These results, along with previous enzymatic studies, suggest that the liver and each area of the kidney contain different substrate specificities and pathways for the metabolism of organic compounds.     

Electron paramagnetic resonance analyses of biotransformation reactions with cytochrome P-450 immobilized on mesoporous molecular sieves

Mobil Crystalline Material (MCM-41) can be used for the immobilization of enzymes and the investigation of electron transfer in biological systems. Electron transfer between MCM-41 with aluminum (Al-MCM-41) and cytochrome P-450 (CYP2B4) was observed using electron paramagnetic resonance (EPR). When CYP2B4 was immobilized by adsorption, it catalyzed the conversion of aniline to p-aminophenol. The electron transfer was evidenced when the signal with a g value (also called g-factor or spectroscopic manifestation of the magnetic moment) of 1.98 increased at the same time that the signal with a g value 2.24 decreased due to the addition of NADPH to CYP2B4 immobilized on Al-MCM-41, indicating that Fe^III was reduced to Fe^II. Therefore, it is possible that Al-MCM-41 participates in the electron transfer process in biological systems.     

Electron paramagnetic resonance studies of the purified cytochrome P-450scc and P-45011beta from bovine adrenocortical mitochondria.

Electron paramagnetic resonance studies have been carried out on two species of cytochrome P-450 (P-450scc and P-45011beta) purified from bovine adrenocortical mitochondria. The g values of the steroid-bound cytochromes in the high spin form were determined at 4.2 degrees K to be 8.07, 3.60 and 1.70 for P-450scc and 8.00, 3.65 and 1.71 for P-45011beta. The E/D values were estimated to be 0.103 for P-450scc and 0.099 for P-45011beta. Either high spin P-450 was converted into the low spin form by the treatment with an NADPH dependent electron donating system and subsequent gel filtration in order to remove the steroid. The g values of the low spin ferric cytochromes were 2.423, 2.247 and 1.914 for P-450scc and 2.430, 2.251 and 1.919 for P-45011beta at 77 degrees K. The values for magnitude of delta/gamma, magnitude of V/gamma and k were 5.69, 5.21 and 1.11 for P-450scc and 5.94, 5.38 and 1.16 for P-45011beta. These studies indicate that there are some differences in the ferric heme environment between P-450scc and P-45011beta.     

The diverse spectroscopic properties of ferrous cytochrome P-450-CAM ligand complexes

The UV-visible absorption, magnetic circular dichroism (MCD) and CD spectral characteristics of a variety of low spin ferrous P-450-ligand complexes have been carefully determined in order to establish whether all such complexes are hyperporphyrins as previously suggested in the literature. Two general spectral classes are found to occur. Complexes in the first class are, indeed, hyperporphyrin in nature, with pi-acceptor ligands such as CO, NO, phosphine, nitrosoalkanes and isocyanides trans to cysteinate. Individual, but minor, variations in the spectral properties of the hyperporphyrins suggest that subclasses exist, wherein the nature of the trans ligand to thiolate affects the orbital overlap pattern and thus the observed spectra. Adducts in the second spectral class, which have sigma-donor nitrogen and sulfur ligands, also have the red-shifted Soret absorption maximum but are spectrally distinct in all other respects from the hyperporphyrins. Comparison of the MCD spectra of the second category to those of ferrous cytochromes b5, c, and P-420 suggests that the axial cysteinate ligand is still present in the nonhyper ferrous P-450 species. Thus, the combination of a strongly electron-donating cysteinate ligand and a trans sigma-donor, not the orbital mixing mechanism, is most likely the origin of the red-shifted Soret absorption maximum of nonhyper ferrous P-450 ligand complexes. Further, the nature of the total electronic interactions between both axial ligands and the heme iron of ferrous P-450 and not solely the cysteinate ligand determines whether the ligand complexes will be of the hyper or nonhyperporphyrin category. These findings are strengthened by the simultaneous use of three different spectroscopic techniques; together they provide a more detailed explanation for the unusual spectroscopic properties of cytochrome P-450.     

Effects of cholesterol and adrenodoxin binding on the heme moiety of cytochrome P-450scc: a resonance Raman study

The effects of cholesterol and adrenodoxin binding on resonance Raman spectra of cytochrome P-450scc in both oxidized and CO-reduced states were examined. Upon cholesterol binding, oxidized cytochrome P-450scc showed a significant shift of spin equilibrium from low-spin to high-spin state. Addition of adrenodoxin caused a complete conversion of cholesterol-bound oxidized cytochrome P-450scc to a pure high-spin state that was considered to be in the hexacoordinated state judged by the v10 mode at 1620 cm-1 and v3 mode around 1485 cm-1. Cholesterol in substrate binding site may oppose a linear and perpendicular binding of carbon monoxide to the reduced heme iron, leading to the distorted Fe-C-O linkage. This is based on the following observations: (1) an increase of the Fe-CO stretching frequency to 483 from 477 cm-1 upon addition of cholesterol; (2) an enhanced photodissociability of bound carbon monoxide of CO complex of cytochrome P-450scc in the presence of cholesterol. As another aspect of the effect of cholesterol on the CO complex form of cytochrome P-450scc, the enhanced stability of the native form ("P-450" form) was observed. There was no additional effect of reduced adrenodoxin on the Raman spectra of the CO-reduced form of cytochrome P-450scc.     

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.     

A nuclear magnetic resonance study of axial ligation for the reduced states of chloroperoxidase,cytochrome P-450cam,and porphinatoiron(II) thiolate complexes

The reduced forms of cytochrome P-450_cam and chloroperoxidase were examined by proton NMR spectroscopy. The pH and temperature dependences of the proton NMR spectra of both ferrous enzymes are reported. A series of alkyl mercaptide complexes of both synthetic and natural-derivative iron(II) porphyrins was also examined. The proton NMR spectra of these complexes facilitated the assignment of resonances due to the axial ligand in the model compounds on the basis of their isotropic shifts and multiplicities. Comparison of model compound data with that for the reduced enzymes supports assignment of the methylene protons for the axial cysteinate of ferrous cytochrome P-450_cam and ferrous chloroperoxidase to proton NMR resonances at 279 and 200 ppm (pH 7.0, 298K), respectively. Differences in the active site structure of the two enzymes are further demonstrated by ¹⁵N-NMR spectroscopy of the cyanide complexes of the ferric forms.     

Electron paramagnetic resonance studies of cytochrome P-450 and adrenal ferredoxin in single whole rat adrenal glands. Effect of corticotropin

Low and high spin ferric cytochrome P-450 and reduced adrenal ferredoxin (adrenodoxin) have been directly studied by EPR techniques in whole rat adrenal glands. The spectra obtained correspond closely to those obtained from sub-cellular fractions except in the case of low spin ferric cytochrome P-450, where there are differences in the shape of the g = 2.41 line. The relative magnitudes of these peaks in anaerobic and aerobic rapidly frozen adrenals from control and corticotropin stimulated hypophysectomised rats were used to investigate the control and rate limiting steps in adrenal steroid biosynthesis via cytochrome P-450. All adrenals showed a close to maximal level of reduced adrenodoxin and aerobic and anaerobic glands from control rats and aerobic glands from corticotropin stimulated rats showed similar quantities of low spin ferric cytochrome P-450. On anaerobiosis the quantity of low spin ferric cytochrome in adrenals from corticotropin stimulated rats dropped to 30–40% of the aerobic level. Treatment of the rats with cycloheximide prior to administration of corticotropin prevented these changes. Approximately 0.4% of the total cytochrome P-450 was high spin ferric in control adrenals and in aerobic stimulated adrenals this rose to approximately 0.6%. These results demonstrate that association of substrate with cytochrome P-450 is the rate limiting step in adrenal steroidogenesis via cytochrome P-450. It is suggested on the basis of these and mitochondrial optical and EPR experiments that the limiting step being observed is cholesterol binding to cholesterol side chain cleavage cytochrome P-450, and that the rate of this association is stimulated by corticotropin.