Purification and immunochemical characterization of the two adrenal cortex mitochondrial cytochrome P-450-proteins.

A procedure for the separation and purification of two distinct P-450 cytochromes, termed P-450_scc and P-450_11β, solubilized from bovine adrenal cortex mitochondria is reported. Important features of the purification procedure are uses of aniline-substituted Sepharose chromatography and utilization of the markedly different characteristics in stability and solubility of each cytochrome. Polyacrylamide gel electrophoresis of the two purified preparations in sodium dodecyl sulfate reveals single protein bands. The P-450_scc, which catalyzes the formation of pregnenolone from cholesterol, has a turnover number of 16 mol of pregnenolone formed per minute per mole of P-450-heme. The P-450_11β catalyzes the hydroxylation of deoxycorticosterone at 11β- and 18-positions with turnover numbers of 110 and 18, and of 4-androstene-3,17-dione at 11β- and 19-positions with turnover numbers of 41 and 12, respectively. The recoveries of the P-450_scc and P-450_11β, in terms of the catalytic activities, are 20% and 15%, respectively, from the crude extract which contains the two activities in a ratio of roughly 2:1. Each rabbit antibody prepared against the two purified P-450-proteins interacts with respective, but not alternative cytochrome P-450, whether in the crude mitochondrial preparation or in the purified preparation. The observed patterns of immunoprecipitation and inhibition of catalytic activity indicated that the two P-450 proteins are immunochemically different from each other. Neither antibody immunoprecipitates with a highly purified bacterial cytochrome P-450, P-450_cam.     

Properties of an adrenal cytochrome P-450 (P-45011β) for the hydroxylations of corticosteroids

A highly purified preparation of cytochrome P-450, designated as P-450_11β, has been obtained from bovine adrenal cortex mitochondria. The P-450_11β exhibits remarkably high steroid hydroxylase activity in the reconstituted adrenal electron-donating system from NADPH via NADPH:adrenal ferredoxin oxidoreductase (EC 1.6.7.1) and adrenal ferredoxin. The turnover numbers (moles of hydroxylated product formed per minute per mole of P-450-heme) are 110 and 18 for respective 11β- and 18-hydroxylase activity when deoxycorticosterone is the substrate. The apparent K_m value is 6 μm for both reactions. The ratio, about 6:1 between the two activities, is constant under various experimental conditions including those in the presence of competitive inhibitors of hydroxylation. In addition to deoxycorticosterone, other steroids such as 11-deoxycortisol, 4-androstene-3,17-dione and testosterone are the hydroxylatable substrates. In cases in which 4-androstene-3,17-dione, a C₁₉-steroid, is the substrate, the hydroxylatable sites appear to be its respective 11β- and 19-position. The ratio between the two activities is about 4:1. In view of these results, it is concluded that one hemoprotein species, the P-450_11β, is responsible for the hydroxylase reactions of various Corticosteroids. 2-Methyl-1,2-di-3-pyridyl-1-propanone (metyrapone) inhibits the P-450_11β-catalyzed steroid hydroxylase reactions of either deoxycorticosterone at 11β- and 18-position or 4-androstene-3,17-dione at 11β- and 19-position (K_i = 0.1-0.2 μM). The P-450_scc-catalyzed cholesterol desmolase reaction is also inhibited, although weakly (K_i = 160 μM). In addition, both adrenal cytochromes appeared to differ from each other in spectral response to metyrapone.     

Oxidation-reduction potentials of cytochromes P-450 and ferredoxin in the bovine adrenal: Their modification by substrates and inhibitors

The midpoint reduction potentials of the haem iron in bovine adrenal cytochrome P-450 and its associated iron-sulphur protein, adrenal ferredoxin, have been measured, using EPR spectroscopy to monitor the high and low spin ferric haem iron and reduced adrenal ferredoxin signals as a function of potential, in mitochondrial and microsomal suspensions.In mitochondria the high spin (substrate-bound) cytochrome P-450 showed single-component one-electron plots under most conditions; at pH 6.65 cholesterol side-chain cleavage cytochrome P-450 (P-450_scc) had a midpoint E_m = ?305 mV; at pH 8.0 11β-hydroxylase cytochrome P-450 (P-450_11β) had E_m = ?335 mV. Low spin cytochrome P-450 showed more complex titration curves under all conditions, which could be most simply interpreted in terms of two one-electron components with midpoint potentials approx. ?360 and ?470 mV, with varying intensities. During treatments that caused substrate binding, only the ?470 mV component was reduced in magnitude. On sonication and removal of adrenal ferredoxin, the ?470 mV low spin component was converted to higher potential. The potentials could also be altered by the cytochrome P-450 inhibitors aminoglutethimide and metyrapone. In the microsomes, a high spin component of cytochrome P-450 (E_m ≈ ?290 mV) was observed even at pH 8.0, suggesting the binding of an endogenous substrate, while the low spin P-450 showed a predominance of the ?360 mV component. The midpoint potential of membrane-bound adrenal ferredoxin under these various conditions was found to be ?248 mV ± 15 mV.     

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.     

Substrate-binding region of cytochrome P-450scc (P-450 XIA1). Identification and primary structure of the cholesterol binding region in cytochrome P-450scc

Cytochrome P-450_scc (P-450 XIA1) from bovine adrenocortical mitochondria was investigated using a suicide substrate: [¹⁴C]methoxychlor. [¹⁴C]Methoxychlor irreversibly abolished the activity of the side-chain cleavage enzyme for cholesterol (P-450_scc) and the inactivation was prevented in the presence of cholesterol. The binding of [¹⁴C]methoxychlor and cytochrome P-450_scc occurred in a molar ratio of 1:1 and the cholesterol-induced difference spectrum of cytochrome P-450_scc was similar with the methoxychlor-induced difference spectrum. [¹⁴C]Methoxychlor-binding peptides were purified from tryptic-digested cytochrome P-450_scc modified with [¹⁴C]methoxychlor. Determination of the sequence of the amino-acid residues of a [¹⁴C]methoxychlor-binding peptide allowed identification of the peptide comprising the amino-terminal amino-acid residues 8 to 28.     

Cholesterol 20, 22-epoxides: no conversion to pregnenolone by adrenal cytochrome P-450SCC.

All of the four 20,22-epoxycholesterols and (E)-20(22)-dehydrocholesterol were chemically synthesized and incubated with purified adrenocortical cytochrome P-450_scc in the presence of an appropriate electron-supplying system. None of these cholesterol derivatives were significantly converted to pregnenolone by the enzyme. A slight inhibition of the side-chain cleavage of radioactive cholesterol was observed by the addition of the cholesterol derivatives, but there occurred no trapping of the radioactivity by these compounds. It may be concluded that the side-chain cleavage of cholesterol by the adrenal cytochrome P-450 does not operate through olefin and epoxide formation as the intermediates.     

Cytochrome P-450 from mitochondria of bovine adrenal cortex Comparison of cholesterol side-chain cleavage P-450 with steroid 11β-hydroxylation P-450 and immunochemical cross-reactivity between adrenal mitochondrial and liver microsomal cytochromes P-450

Adrenocortical mitochondrial cytochrome P?450 specific to the cholesterol side-chain cleavage (desmolase) reaction differs from that for the 11β-hydroxylation reaction of deoxycorticosterone. The former cytochrome appears to be more loosely bound to the inner membrane than the latter. Upon ageing at 0°C or by aerobic treatment with ferrous ions, the desmolase P-450 was more stable than the 11β-hydroxylase P-450. By utilizing artificial hydroxylating agents such as cumene hydroperoxide, H₂O₂, and sodium periodate, the hydroxylation reaction of deoxycorticosterone to corticosterone in the absence of NADPH was observed to a comparable extent with the reaction in the presence of adrenodoxin reductase, adrenodoxin and NADPH. However, the hydroxylation reaction of cholesterol to pregnenolone was not supported by these artificial agents.Immunochemical cross-reactivity of bovine adrenal desmolase P-450 with rabbit liver microsomal P-450_LM4 was also investigated. We found a weak but significant cross-reactivity between the adrenal mitochondrial P-450 and liver microsomal P-450_LM4, indicating to some extent a homology between adrenal and liver cytochromes P-450.     

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.     

1H nuclear magnetic resonance and magnetic circular dichroism studies of ferric low-spin cytochrome P-450scc

400 MHz ¹H NMR of ferric low-spin cytochrome P-450_scc purified from bovine adrenal cortex was measured for the first time. As compared with ¹H NMR spectra of low-spin P-450_cam and metMb- mercaptan complexes, paramagnetic shifts of low-spin P-450_scc complexes were more divergent, suggesting that there is a subtle difference in the heme environment between P-450_scc and P-450_cam [1]. The paramagnetic shifts of low-spin complexes of P-450_scc caused by adding nitrogenous inhibitors, aminoglutethimide and metyrapone, were different from those caused by adding an intermediate, 20α-hydroxycholesterol, and a detergent, Tween 20 [2]. The paramagnetic shifts of the metMb-mercaptan complexes were convergent compared with those of ferric low-spin P-450_scc and P-450_cam, suggesting that the electronic character and/or the conformation of the internal thiolate ligand in P-450_scc and P-450_cam are different from those of the external thiolate ligand in metMb-thiolate complexes [3]. The paramagetic shifts of the metMb-mercaptan complexes were dependent on the electron donating factor of the alkyl group of the bound mercaptans [4].Magnetic CD(MCD) spectra of ferric low-spin P-450_scc, rabbit liver P-450 complexes and metMb- mercaptan complexes were also observed at various temperatures. The temperature dependences of the Soret MCD bands for the low-spin P-450 and metMb- mercaptan complexes were decidedly less pronounced than those for the low-spin metMb-CN? or imidazole complexes, suggesting that thiolate ligands markedly influence the Soret MCD band of the ferric low-spin complexes [1]. The suggestion described in [2] implied by the ¹H NMR study was reconfirmed from the temperature dependence study of the Soret MCD [2]. The temperature dependences of the Soret MCD bands for low-spin P-450 complexes having a non-nitrogenous ligand were more pronounced than for those having a nitrogenous ligand.     

Isolation from bovine liver mitochondria of a soluble ferredoxin active in a reconstituted steroid hydroxylation reaction.

An iron-sulfur protein has been isolated from bovine liver mitochondria and purified 140-fold on DEAE-cellulose and Sephadex G-100. During the isolation the protein was detected by its NADPH-cytochrome $\text{c}$ reductase activity in the presence of adrenal NADPH-ferredoxin reductase. The molecular weight of the protein (12,400), the optical spectrum (peaks at 414 nm and 455 nm which disappear upon reduction), and the EPR spectrum (g_x = g_y = 1.935 and g_z = 2.02) were typical for a ferredoxin. In the presence of soluble adrenal cytochrome P₄₅₀, ferredoxin reductase and NADPH, this protein could support the formation of pregnenolone from cholesterol. Under similar conditions, but in the presence of a cytochrome P₄₅₀ solubilized from rat liver mitochondria, cholesterol was transformed into a more polar compound tentatively identified as 26-hydroxycholesterol.     

Purification and properties of cytochrome P-450(11beta) from adrenocortical mitochondria.

A cytochrome P-450, which is functional in the steroid methylene 11β-hydroxylation (P-450_11β), has been purified to a protein weight of 85 kg per heme from bovine adrenocortical mitochondria. The purification is accomplished in the presence of deoxycorticosterone as a substrate stabilizer. The procedure involved solubilization of sonicated mitochondrial pellets, ammonium sulfate fractionation, alumina Cγ gel treatment and aniline-substituted Sepharose 4B chromatography.The purified preparation when freed from deoxycorticosterone, has a low spin type absorption spectrum which can rapidly be converted into a typical high spin substrate-bound form by the addition of an 11β-hydroxylatable steroid, either deoxycorticosterone or testosterone. The preparation exhibits high 11β-hydroxylase activity and is free from the cholesterol side-chain cleavage cytochrome P-450 (P-450_scc).The purified P-450_11β, when submitted to SDS-polyacrylamide gel electrophoresis, exhibits a single protein band (molecular weight of 46 kilodaltons) which is clearly distinguished from P-450_scc. As determined by the sedimentation equilibrium method, the molecular weight of the guanidine-treated P-450_11β is estimated to be 43 kilodaltons.     

Absorption spectral studies on heme ligand interactions of P-450nor

Heme-external ligand interactions of P-450_nor were examined spectrophotometrically and compared with those of other P-450s. Most nitrogenous ligands induced type II spectral changes on binding to ferric P-450_nor, as did other P-450s. In contrast with other P-450s, 2-methylpyridine and 1-butanol induced type I changes in the spectrum of P-450_nor. No spectral interaction of ferrous P-450_nor with these ligands was observed. The absorption spectra of the alkyl isocyanide complexes of ferrous P-450_nor exhibited the Soret peak at 427 nm with a slight shoulder at around 455 nm at neutral pH, and this shoulder was intensified as the pH was increased, suggesting that the isocyanide complexes of P-450_nor existed in two states (the 430 and 455 nm states) which were in pH-dependent equilibrium in a similar manner to microsomal P-450s. However, the equilibrium was shifted mostly to the 430 nm state in the complexes of P-450_nor. The findings suggest that P-450_nor, especially its ferrous form, has some distinct features from P-450_cam and microsomal P-450s in the distal heme environment.     

Cytochrome P-450 from mitochondria of bovine adrenal cortex: comparison of cholesterol side-chain cleavage P-450 with steroid 11beta-hydroxylation P-450 and immunochemical cross-reactivity between adrenal mitochondrial and liver microsomal cytochromes P-450.

Adrenocortical mitochondrial cytochrome P-450 specific to the cholesterol side-chain cleavage (desmolase) reaction differs from that for the 11beta-hydroxylation reaction of deoxycorticosterone. The former cytochrome appears to be more loosely bound to the inner membrane than the latter. Upon ageing at 0 degrees C or by aerobic treatment with ferrous ions, the desmolase P-450 was more stable than the 11beta-hydroxylase P-450. By utilizing artificial hydroxylating agents such as cumene hydroperoxide, H2O2, and sodium periodate, the hydroxylation reaction of deoxycorticosterone to corticosterone in the absence of NADPH was observed to a comparable extent with the reaction in the presence of adrenodoxin reductase, adrenodoxin and NADPH. However, the hydroxylation reaction of cholesterol to pregnenolone was not supported by these artificial agents. Immunochemical cross-reactivity of bovine adrenal desmolase P-450 with rabbit liver microsomal P-450LM4 was also investigated. We found a weak but significant cross-reactivity between the adrenal mitochondrial P-450 and liver microsomal P-450LM4, indicating to some extent a homology between adrenal and liver cytochromes P-450.     

NADPH-cytochrome P-450 reductase of yeast microsomes.

NADPH-cytochrome c reductase of yeast microsomes was purified to apparent homogeneity by solubilization with sodium cholate, ammonium sulfate fractionation, and chromatography with hydroxylapatite and diethylaminoethyl cellulose. The purified preparation exhibited an apparent molecular weight of 83,000 on polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. The reductase contained one molecule each of flavin-adenine dinucleotide and riboflavin 5′-phosphate, though these were dissociative from the apoenzyme. The purified reductase showed a specific activity of 120 to 140 μmol/min/mg of protein for cytochrome c as the electron acceptor. The reductase could reduce yeast cytochrome P-450, though with a relatively slow rate. The reductase also reacted with rabbit liver cytochrome P-450 and supported the cytochrome P-450-dependent benzphetamine N-demethylation. It can, therefore, be concluded that the NADPH-cytochrome c reductase is assigned for the cytochrome P-450 reductase of yeast. The enzyme could also reduce the detergent-solubilized cytochrome b₅ of yeast. So, this reductase must contribute to the electron transfer from NADPH to cytochrome b₅ that observed in the yeast microsomes.     

Purification and properties of cytochrome P-450 (SCC) from pig testis mitochondria

Cytochrome P-450 was purified from pig testis mitochondria to a specific content of 13.1 n mol/mg of protein. The purified preparation was found to contain a single species of P-450, on sodium dodecyl sulfate polyacrylamide gel electrophoresis, with an apparent molecular weight of about 53000 +/- 2000. The cholesterol side chain-cleavage system could be reconstituted by mixing the purified cytochrome P-450, adrenodoxin reductase, adrenodoxin, cholesterol and NADPH. The rate of conversion of cholesterol to pregnenolone was 6.2 n mol/min/n mol of P-450 under the conditions employed. The absorption spectrum of the oxidized cytochrome P-450 had maxima at 416, 530 and 568 nm. The reduced CO-complex of the cytochrome P-450 exhibited an absorption maximum at 448 nm. The purified P-450 was subjected to microsequence analysis and its NH2-terminal amino acid sequence was found to show considerable homology with that of bovine adrenal P-450 (SCC).     

Studies of cytochrome P-450 in testis microsomes

Studies on the role of cytochrome P-450 in mouse, rat, and chick testis microsomes showed that this CO-binding hemoprotein is involved in the activity of the 17α-hydroxylase. A 70–80% inhibition by CO of the 17α-hydroxylase activity was detected in rat and chick testis microsomes. In the mouse testis, the level of the enzyme activity is ten times greater than that of the rat. This partly explains why an acceleration of NADPH oxidation by progesterone can be observed in mouse but not in rat testis microsomes. In rat testis microsomes, type I binding spectra of cytochrome P-450 was observed with pregnenolone, progesterone, 17-hydroxyprogesterone, androstenedione, and testosterone. The apparent K_s values for progesterone and 17-hydroxyprogesterone were 0.50 and 1.00 μm, respectively.When NADPH is used to measure cytochrome P-450 levels in rat testis microsomes, CO formation resulting from a stimulation in lipid peroxidation by phosphate or Fe²⁺ was sufficient to bind with 50% of the total amount of cytochrome P-450. Substitution of phosphate by Tris reduced the amount of lipid peroxidation to minimal levels. On a comparable basis, no CO formation was observed in avian testis microsomes.An increase in the testicular levels of cytochrome P-450 resulted upon the administration of HCG and cyclic-AMP to 1-day-old chicks. The lack of stimulation of the cytochrome P-450 levels by progesterone and pregnenolone suggest that the hormonal stimulation of the P-450 levels is not due to substrate induction.     

The neurosteroid pregnenolone is synthesized by a mitochondrial P450 enzyme other than CYP11A1 in human glial cells

Neurosteroids, modulators of neuronal and glial cell functions, are synthesized in the nervous system from cholesterol. In peripheral steroidogenic tissues, cholesterol is converted to the major steroid precursor pregnenolone by the CYP11A1 enzyme. Although pregnenolone is one of the most abundant neurosteroids in the brain, expression of CYP11A1 is difficult to detect. We found that human glial cells produced pregnenolone, detectable by mass spectrometry and ELISA, despite the absence of observable immunoreactive CYP11A1 protein. Unlike testicular and adrenal cortical cells, pregnenolone production in glial cells was not inhibited by CYP11A1 inhibitors DL-aminoglutethimide and ketoconazole. Furthermore, addition of hydroxycholesterols increased pregnenolone synthesis, suggesting desmolase activity that was not blocked by DL-aminoglutethimide or ketoconazole. We explored three different possibilities for an alternative pathway for glial cell pregnenolone synthesis: (1) regulation by reactive oxygen species, (2) metabolism via a different CYP11A1 isoform, and (3) metabolism via another CYP450 enzyme. First, we found oxidants and antioxidants had no significant effects on pregnenolone synthesis, suggesting it is not regulated by reactive oxygen species. Second, overexpression of CYP11A1 isoform b did not alter synthesis, indicating use of another CYP11A1 isoform is unlikely. Finally, we show nitric oxide and iron chelators deferoxamine and deferiprone significantly inhibited pregnenolone production, indicating involvement of another CYP450 enzyme. Ultimately, knockdown of endoplasmic reticulum cofactor NADPH-cytochrome P450 reductase had no effect, while knockdown of mitochondrial CYP450 cofactor ferredoxin reductase inhibited pregnenolone production. These data suggest that pregnenolone is synthesized by a mitochondrial cytochrome P450 enzyme other than CYP11A1 in human glial cells.     

Hydroxylation of 19-norandrostenedione by adrenal cortex mitochondrial P-450(11)beta

The activity of purified bovine adrenocortical P-450(11)beta on the C18-steroid, 4-estrene-3,17-dione (19-norandrostenedione), is described. The major steroid products were separated by HPLC and identified by GC-MS, and 1H- and 13C-NMR as 11 beta-, 18- and 6 beta-hydroxylated derivatives of 19-norandrostenedione. The turnover numbers of the 11 beta-, 18- and 6 beta-hydroxylase reactions were 45, 7.5 and 1.9 (mol/min/mol of P-450(11)beta), respectively, with a common Km of 44 microM. All of these activities required the presence of the electron donating system consisting of NADPH, adrenal ferredoxin (adrenodoxin) and its reductase. These findings provide additional insights into the versatile catalytic roles of P-450(11)beta in the adrenal cortex, in which it may act on C18-19-nor-steroids in addition to its known activities on C21- and C19-steroids.     

Adrenal P-450scc catalyzes deoxycorticosterone 6 beta-hydroxylase reaction

Purified bovine P-450scc, the cholesterol side-chain cleaving P-450 in adrenal cortex mitochondria, was found to catalyze a deoxycorticosterone 6 beta-hydroxylase reaction. A turnover number (moles of product formed/min/mol of P-450) of 12 was found similar to that for cholesterol side chain cleavage activity. Conversion was dose-dependent in terms of P-450scc and no reaction took place when any one of the required electron donating components such as NADPH, NADPH-adrenodoxin reductase, or adrenodoxin was omitted. These results confirm and extend earlier observations that 21-hydroxypregnenolone is transformed into both deoxycorticosterone and 6 beta-hydroxydeoxycorticosterone by incubation of adrenal gland slices.     

Purification of characterization of a minor form of hepatic microsomal cytochrome P-450 from rats treated with polychlorinated biphenyls

A minor form of hepatic microsomal cytochrome P-450 has been purified to apparent homogeneity from rats treated with the polychlorinated biphenyl mixture, Aroclor 1254. This newly isolated hemoprotein, cytochrome P-450_e, is inducible in rat liver by Aroclor 1254 and phenobarbital, but not by 3-methylcholanthrene. Two other hemoproteins, cytochromes P-450_b and P-450_c, have also been highly purified during the isolation of cytochrome P-450_e based on chromatographic differences among these proteins. By Ouchterlony double-diffusion analysis with antibody to cytochrome P-450_b, highly purified cytochrome P-450_e is immunochemically identical to cytochrome P-450_b but does not cross-react with antibodies prepared against other rat liver cytochromes P-450 (P-450_a, P-450_c, P-450_d) or epoxide hydrolase. Purified cytochrome P-450_e is a single protein-staining band in sodium dodecyl sulfate-polyacrylamide gels with a minimum molecular weight (52,500) slightly greater than cytochromes P-450_b or P-450_d (52,000) but clearly distinct from cytochromes P-450_a (48,000) and P-450_c (56,000). The carbon monoxide-reduced difference spectral peak of cytochrome P-450_e is at 450.6 nm, whereas the peak of cytochrome P-450_b is at 450 nm. Ethyl isocyanide binds to ferrous cytochromes P-450_e and P-450_b to yield two spectral maxima at 455 and 430 nm. At pH 7.4, the 455:430 ratio is 0.7 and 1.4 for cytochromes P-450_b and P-450_e, respectively. Metyrapone binds to reduced cytochromes P-450_e and P-450_b (absorption maximum at 445–446 nm) but not cytochromes P-450_a, P-450_c, or P-450_d. Metabolism of several substrates catalyzed by cytochrome P-450_e or P-450_b reconstituted with NADPH-cytochrome c reductase and dilauroylphosphatidylcholine was compared. The substrate specificity of cytochrome P-450_e usually paralleled that of cytochrome P-450_b except that the rate of metabolism of benzphetamine, benzo[a]pyrene, 7-ethoxycoumarin, hexobarbital, and testosterone at the 16α-position catalyzed by cytochrome P-450_e was only 15–25% that of cytochrome P-450_b. In contrast, cytochrome P-450_e catalyzed the 2-hydroxylation of estradiol-17β more efficiently (threefold) than cytochrome P-450_b. Cytochrome P-450_d, however, catalyzed the metabolism of estradiol-17β at the greatest rate compared to cytochromes P-450_a, P-450_b, P-450_c, or P-450_e. The peptide fragments of cytochromes P-450_e and P-450_b, generated by either proteolytic or chemical digestion of the hemoproteins, were very similar but not identical, indicating that these two proteins show minor structural differences.