Interaction between cytochrome P-450 (P-450C21) and NADPH-cytochrome P-450 reductase from adrenocortical microsomes in a reconstituted system

The interaction between P-450C21 and NADPH-cytochrome P-450 reductase, both purified from bovine adrenocortical microsomes, has been investigated in a reconstituted system with a nonionic detergent, Emulgen 913, by kinetic analysis and gel filtrations. Steady state kinetic data in progesterone 21-hydroxylation showed formation of an equimolar complex between the two enzyme proteins at low Emulgen concentration. Steady state kinetic studies on the electron transfer from NADPH to P-450C21 via the reductase showed that a stable complex formation between the two enzyme proteins was not involved in the steady state electron transfer at high Emulgen concentration. In stopped flow experiments, a time course of the P-450C21 reduction showed biphasic kinetics composed of fast and slow phases. The dependence of kinetic parameters on Emulgen concentration indicates that the fast phase corresponds to the electron transfer within the complex and the slow phase to the electron transfer through a random collision between P-450C21 and the reductase. The stable complex formation between P-450C21 and the reductase has been clearly demonstrated by gel filtration. The stable complex was composed of several molecules of the two enzyme proteins at an equimolar ratio, which was active for progesterone 21-hydroxylation and had a tendency to dissociate at high Emulgen concentration.     

Metabolism of benzo[c]phenanthrene by rat liver microsomes and by a purified monooxygenase system reconstituted with different isozymes of cytochrome P-450

Metabolism of the environmental pollutant and weak carcinogen benzo[c]-phenanthrene (B[c]Ph) by rat liver microsomes and by a purified and reconstituted cytochrome P-450 system is examined. B[c]Ph proved to be one of the best polycyclic aromatic hydrocarbon substrates for rat liver microsomes. It is metabolized by microsomes from control rats and by rats treated with phenobarbital or 3-methylcholanthrene at 3.9, 4.2 and 7.8 nmol/nmol cytochrome P-450/min, respectively. Principal metabolites are dihydrodiols along with small amounts (less than 10%) of phenols. The K-region 5,6-dihydrodiol is the major metabolite and accounts for 77-89% of the total metabolites. The 3,4-dihydrodiol with a bay-region 1,2-double bond is formed in much smaller amounts and accounts for only 6-17% of the total metabolites, the highest percentage being formed by microsomes from control rats. Highly purified monooxygenase systems reconstituted with cytochrome P-450a, P-450b and P-450c and epoxide hydrolase form predominantly the 5,6-dihydrodiol (95-97% of total metabolites) and only a small percentage of the 3,4-dihydrodiol (3-5% of total metabolites). The 3,4-dihydrodiol is formed with higher enantiomeric purity by microsomes from 3-methylcholanthrene-treated rats (88%) than by microsomes from control rats (78%) or phenobarbital-treated rats (60%). In each case the (3R,4R)-enantiomer predominates. B[c]Ph 5,6-dihydrodiol formed by all three microsomal preparations is nearly racemic.     

The 14alpha-demethylation of lanosterol by a reconstituted cytochrome P-450 system from yeast microsomes.

Native and zinc reconstituted carboxypeptidase B were nitrated with tetranitromethane. The inactivation of the reconstituted enzyme was faster than that of the native enzyme and was accompanied by the formation of a considerable amount of enzyme dimers. The inactivation and dimerization reflected changes in the reactivity of active site tyrosine residue(s), thus indicating microenvironmental changes which occur during metal substitution. The change in tyrosine reactivity could be correlated with the residence of the enzyme in the metal-free state.     

Multiple catalytic properties of the purified and reconstituted cytochrome P-450 (P-450sccII) system of pig testis microsomes

The catalytic properties of the testis microsomal P-450, termed P-450sccII, have been studied in a refined assay system which consists of P-450sccII (13 nmol of P-450 heme/mg of protein) and its reductase has been purified extensively from pig testis. The results indicated that P-450sccII was highly active in catalyzing hydroxylation of 11 beta-hydroxyprogesterone at the 17 alpha-position to give 21-deoxycortisol and cleavage of 17 alpha-hydroxyprogesterone at the 17-20 bond to give androstenedione with turnover numbers of 25 and 30 mol/min X mol of P-450, respectively. In contrast, many physiologically important corticosteroids we tested were found to be poor substrates for both the hydroxylase and lyase reactions. The possible reason for the importance of these substrate specificity of P-450sccII in production of both corticosteroids and androgens in the endocrine tissues is discussed. P-450sccII also catalyzed conversion of testosterone to androstenedione, but 18O experiments failed to show incorporation of atmospheric oxygen into the androstenedione formed. However, this does not preclude the possibility that the P-450-bound intermediate gem-diol stereoselectively dehydrates to give the nonlabeled ketosteroid. In addition to these steroid-oxidizing activities, P-450sccII revealed considerable specificities toward various xenobiotics, suggesting that P-450sccII and liver microsomal P-450 are basically similar as regards enzymatic functions and activities.     

Ring-andN-hydroxylation of 2-acetamidofluorene by rat liver reconstituted cytochrome P-450 enzyme system.

The N- and ring-hydroxylation of 2-acetamidofluorene were studied with a reconstituted cytochrome P-450 enzyme from microsomal fractions of liver from both control and 3-methylcholanthrene-pretreated rats. Proteinase treatment and Triton X-100 solubilization were two important steps for partial purification of the cytochrome P-450 fraction. Both cytochrome P-450 and NADPH-cytochrome c reductase fractions were required for optimum N- and ring-hydroxylation activity. Hydroxylation activity was determined by the source of cytochrome P-450 fraction; cytochrome P-450 fraction from pretreated animals was severalfold more active than the fraction from controls. Formation of N-hydroxylated metabolites with reconstituted systems from both control and pretreated animals was greater than that with their respective whole microsomal fractions.     

Induction of cytochrome P-450 in rat liver microsomes by perfluorodecalin

Perfluorodecalin was incorporated into phospholipid liposomes and injected intraperitoneally in various dozes. The maximal cytochrome P-450 induction is reached 48 hours after perfluorodecalin injection. Cytochrome P-450 content increases 4 times after perfluorodecalin injection in dose of 0.6 ml/kg in homogenate, and 6 times after perfluorodecalin injection in a dose of 0.4 ml/kg in microsomes. Phenobarbital and perfluorodecalin induce several cytochrome P-450 isozymes and cause the appearance of a new isozyme with mass 56 kD absent in microsomes of intact CBA mice. Perfluorodecalin induction strongly increased the rate of NADPH-dependent aminopyrine nN-demethylation (6-7 times per mg of microsomal protein and 1.5 times per nmol cytochrome P-450). The rate of NADPH-dependent hydroxylation of aniline was not affected by perfluorodecalin induction.     

Evidence for the involvement of cytochrome P-450 in reduction of benzo(a)pyrene 4,5-oxide by rat liver microsomes.

Benzo(a)pyrene 4,5-oxide is reduced to benzo(a)pyrene by microsomes in the presence of NADPH. Carbon monoxide and oxygen inhibit this reduction. The liver has highest activity which is almost lackng in new-born rats. Phenobarbital as well as 3-methylcholanthrene pretreatment increases the epoxide reduction. Additions of FMN or methylviologen stimulate the epoxide reduction; dimethylaniline N-oxide and cumene hydroperoxide are inhibitory. These results indicate that benzo(a)pyrene 4,5-oxide is reduced by the reduced form of cytochrome P-450.     

Hydroxylation of acetone by ethanol- and acetone-inducible cytochrome P-450 in liver microsomes and reconstituted membranes

Acetone oxidation in rat liver microsomes was induced 5- or 8-fold by the treatment of the animals with ethanol or acetone, respectively. The apparent Km of the reaction was 0.9 mM, a value lower than the concentration reported for plasma acetone under starvation conditions. The major acetone metabolite was identified as acetol by GC-MS. Acetone oxidation in microsomes was inhibited by typical P-450 inhibitors as well as by compounds (e.g. imidazole) known to interact with the ethanol-inducible P-450 form. Antibodies against this P-450 isozyme were inhibitory for the reaction in rabbit liver microsomes and this isozyme was the only one that showed acetone hydroxylation activity in reconstituted membranes. Imidazole inhibited the conversion of [14C]acetone into low-Mr compounds (e.g. glucose) in vivo. It is suggested that the ethanol- and acetone-inducible P-450 make use of acetone as an endogenous substrate in the utilization of the compound for, e.g. glucose production under conditions of starvation and diabetic ketoacidosis.     

Identification of cross-linked cytochrome P-450 in rat liver microsomes by enzyme-immunoassay

The topography of microsomal proteins was studied by 2-dimensional gelelectrophoresis. The second dimension was run in the presence of 2-mercaptoethanol, thus allowing detection of proteins previously cross-linked by disulfide bonds as off-diagonal spots. With hepatic microsomes from phenobarbital pretreated rats, several off-diagonal spots were seen. The most intense spot, with a molecular weight of 52,000, was derived from a dimer of this protein. It was identified as cytochrome P-450 (P-450) by a double antibody enzyme-immunoassay. The dimer is probably formed by oxidation of sulfhydryl groups of P-450 molecules during the preparation of microsomes. P-450 can also be cross-linked to form 105,000, 167,000, and 240,000 dal oligomers by treating microsomes with dithiobis(succinimidyl propionate) at 0°C. Cross-linking of P-450 to other proteins was also observed with one-dimensional gel-electrophoresis. The results suggest that the cross-linked proteins are close neighbors of P-450 in the membrane.     

Dimethylnitrosamine demethylation by reconstituted liver microsomal cytochrome P-450 enzyme system.

Oxidative demethylation of dimethylnitosamine was studied with both reconstituted and unresolved liver microsomal cytochrome P-450 enzyme systems from rats and hamsters. Proteinase treatment of liver microsomal preparations yielded cytochrome P-450 particulate fractions. Both cytochrome P-450 and NADPH- cytochrome c reductase fractions were required for optimum demethylation activity. Particulate cytochrome P-450 fractions were more effecient than either Triton X-100- or cholatesolubilized preparations of these particles in demethylation activity with rat and hamster liver preparations appear to be due to differences in specificity in their cytochrome P-450 fractions.     

Enzymatic oxidation of disulfides and thiolsulfinates by both rabbit liver microsomes and a reconstituted system with purified cytochrome P-450.

Both rabbit liver microsomes and reconstituted system with purified cytochrome P-450 and cofactors enzymatically oxidized o-dithiane (1, 2-dithiane), 3-methyl-o-dithiane, thiane and 2-methylthiane to the corresponding mono-oxygenated products; sulfides or disulfides were oxidized to the corresponding sulfoxides or thiosulfinates, while thiosulfinate was oxidized to thiolsulfonate. The reconstituted systems required oxygen and NADPH and were not affected by the catalase which decomposes H2O2, or by 1,4-diazabicyclo-[2,2,2]octane (DABCO), which is a good quencher of singlet oxygen. The differences in the binding of substrates such as sulfides and disulfides with the enzyme system are discussed in connection with differences in the spectra of the substrates in the reconstituted system with pure cytochrome P-450. A correlation was found between the rates of oxidation of the substrates and the rates of oxidation of NADPH.     

Detergents as probes of reconstituted rat liver cytochrome P-450 function

A series of 16 ionic, zwitterionic, and nonionic detergents have been used to perturb the catalytic activities of major cytochrome P-450 (P-450) forms from untreated (UT-A), phenobarbital-treated (PB-B) and beta-naphthoflavone-treated (BNF-B) rats in reconstituted systems with NADPH--P-450 reductase Detergent effects on R warfarin hydroxylase activities were correlated with detergent effects on the quaternary structures of P-450 and reductase, and on their 1:1 complexes as determined by gel exclusion chromatography using sodium cholate as a prototype detergent. The detergent concentrations used did not in most cases affect rates of NADPH-dependent reduction of cytochrome c by the reductase. With P-450 BNF-B, ionic and zwitterionic detergents enhanced warfarin hydroxylase activities at low concentrations and produced marked inhibition at higher concentrations, while nonionic detergents only inhibited. With P-450 UT-A, some nonionic and zwitterionic detergents increased rates at low concentrations and inhibited at higher concentrations. P-450 PB-B was inhibited by detergents of all three classes at low and high concentrations. The concentrations of a detergent required to affect 50% inhibition differed for the three P-450s, suggesting, together with the differential susceptibilities to detergent-mediated rate enhancing effects, that the reductase interacts functionally differently with the three P-450s. Chromatographic studies demonstrated that concentrations of sodium cholate which optimally enhanced metabolic rates with P-450 BNF-B facilitated the uptake of the P-450 into the functional reductase/P-450 complex, and higher concentrations of cholate, which completely inhibited activity, produced profound disruptions of the complex. The data have provided insight into the functional interactions required for monooxygenase activity.     

Purification of a new cytochrome P-450 from human liver microsomes

Using a classical methodology of purification consisting of three chromatographic steps (Octyl-Sepharose, DEAE-cellulose, CM-cellulose) we have purified a new cytochrome P-450 from human liver microsomes. It was called cytochrome P-450(9). It has been proven to be different from all precedingly purified human liver microsomal cytochrome P-450 isozymes by its immunological and electrophoretical properties. It does not cross-react with any rat liver cytochrome P-450 and anti-cytochrome P-450(9) does not recognize rat liver microsomes; thus this cytochrome P-450(9) is specific to humans. This cytochrome P-450 isozyme exists in low amounts in human liver microsomes and exhibits an important quantitative polymorphism. In reconstituted system, cytochrome P-450(9) is able to hydroxylate all substrates tested but is not specific of any; its exact role in xenobiotic metabolism in man remains to be elucidated.     

Metabolism of cyclophosphamide by purified cytochrome P-450 from microsomes of phenobarbital-treated rats

Incubation of [³H]-sidechain-labeled and [¹⁴C]-C(4)-ring-labeled cyclophosphamide (CPA) with purified cytochrome P-450 from liver microsomes of rats treated with phenobarbital resulted in the production of a major metabolite that contained both labels, was unaffected by diazomethane, possessed high polarity, was identical in TLC and HPLC behavior to a synthetic standard, didechlorodihydroxy-CPA, and was converted to CPA and bis(2-chloroethyl)amine by thionyl choloride. These results indicate that phenobarbital-inducible cytochrome P-450 is able to dechlorinate CPA and may account, in part, for the inability of phenobarbital to enhance the therapeutic activity and toxicity of this important anticancer and immunosuppressive agent.     

Interaction of aliphatid alcohols with cytochrome P-450 from rat liver microsomes]

The interaction of alyphatic alcohols and cyclohexanol with cytochrome P-450 in microsomes has been investigated. All alchohols induced the modified 11 type spectral changes by mixing with microsomes. These changes are characterized by lambdamax = 412 and lambdamin = 380-382 nm in difference spectra. The dissociation constants of the alcohol cytochrome P-450 complexes are determined. On this dissociation constants influence pH and Triton X-100 presence. The interaction of the alcohols with cytochrome P-450 in phosphate buffer pH = 6,0 in the detergents absence is characterized by one dissociation constant for MeOH, EtOH, n-BuOH and cyclohexanol and by two dissociation constants for i-PrOH, i-BuOH and tert.-BuOH. The interaction of the alcohols with cytochrome P-450 in Tris-HCL-buffer (pH 7.5) in the Triton X-100 presence is characterized for all above alcohols by the dissociations constants, which are described by Taft equation with coefficient rho =-1.55. This fact confirms the interaction of alcohols HO-groups with heme iron of cytochrome P-450. The scheme of interaction of alcohols with cytochrome P-450 is discussed.     

Anaerobic dehalogenation of halothane by reconstituted liver microsomal cytochrome P-450 enzyme system

Cytochrome P-450 from liver microsomes of phenobarbital-treated rabbits catalyzed anaerobic dehalogenation of halothane (2-bromo-2-chloro-1,1,1-trifluoroethane) when combined with NADPH and NADPH-cytochrome P-450 reductase. Cytochromes P-450B₁ and P-448 from liver microsomes of untreated rabbits were less active. Triton X-100 accelerated the reaction. Unlike anaerobic dehalogenation of halothane in microsomes, the major product was 2-chloro-1,1,1-trifluoroethane and 2-chloro-1,1-difluoroethylene was negligible. These products were not detected under aerobic conditions, and dehalogenation activity was inhibited by carbon monoxide, phenyl isocyanide and metyrapone.