The effect of NADPH concentration on the reduction of cytochrome P-450 LM2

Cytochrome P-450 LM2 reduction was measured at a series of NADPH concentrations in the absence of substrate and in the presence of 1 mM benzphetamine. In the absence of substrate reduction could be described as a biphasic process with 55% of the reaction occurring in the first phase (at 20 microM NADPH). When benzphetamine was present, the fraction of the reaction occurring in the first phase was increased to 91%. When examined either in the absence or presence of benzphetamine, the rate constant and fraction of LM2 reduced in the fast phase were decreased as the NADPH concentration was decreased. In each case the fraction of LM2 reduced in the second phase was not substantially altered over the NADPH concentrations examined. To explain the effect of NADPH concentration on the initial rate of LM2 reduction, the effect of NADPH on the reduction of NADPH-cytochrome P-450 reductase was examined. Due to the presence of two flavins within each reductase molecule, there would be nine possible oxidation-reduction states of the reductase which may be present at a given NADPH concentration. Based on the redox potentials for the flavin half-reactions and for NADPH oxidation, the relative concentrations of each of the reductase subspecies could be determined. Rate constants were assigned for the reduction of LM2 by the various reductase subspecies, and the theoretical initial rates of LM2 reduction at various NADPH concentrations were compared with values obtained experimentally. The experimental data are consistent with a model where, under the conditions of this assay, the fully reduced reductase is the form primarily responsible for the reduction of LM2.     

Effects of substrates on the heat stability and on the reactivities of thiol groups of 3-phosphoglycerate kinase

The kinetics of the reduction of cytochrome P-450 LM2 mediated by NADPH-cytochrome P-450 reductase in reconstituted phospholipid vesicles was examined. An inefficient reduction of the hemoprotein in phosphatidylcholine vesicles was observed. However, by introducing negatively charged phospholipids into the membrane, the rate of reduction increased in a concomitant manner to the resulting net negative charge of the vesicles. In the presence of benzphetamine, the extent of cytochrome P-450 LM2 reduced 1 s after the addition of NADPH to the system was a linear function of the electrophoretic mobilities of the vesicles used. A similar relationship between the net negative charge of the vesicles, as measured electrophoretically, and the reduction rate was also attained in the absence of substrate. The enhanced reduction was mainly reflected in an altered phase distribution of the reduction; the extent of fast phase reduction in the absence or in the presence of added substrate was dependent upon the electrophoretic mobilities of the vesicles. A similar change in the distribution of the reduction phases was observed upon decreasing the phosphatidylcholine content of the vesicles; the fast phase reduction being more pronounced in membranes with higher relative amounts of the protein components. A decrease of the rate of O-demethylation of p-nitroanisole catalyzed by P-450 LM2 parallel to the extent of fast phase reduction was observed upon dilution of neutral phosphatidylcholine membranes with phospholipid. By contrast, no effect of lipid dilution was evident in negatively charged membranes. The results are consistent with the hypothesis that the extent of fast phase reduction is governed by the amount of complex formed between NADPH-cytochrome P-450 reductase and cytochrome P-450 in the membranes; negative membranes appear to favor the formation of such complexes, whereas similar complexes are less formed, or are not functional, in neutral membranes.     

Relationship between state of aggregation and catalytic activity for cytochrome P-450LM2 and NADPH-cytochrome P-450 reductase

The detergent 1-O-n-octyl-beta-D-glucopyranoside (octylglucoside) was found to replace the phospholipid requirement in the demethylation of benzphetamine by cytochrome P-450LM2 and NADPH-cytochrome P-450 reductase purified from phenobarbital-treated rabbit liver. At low enzyme concentration (0.1 microM) in the absence of glycerol and phosphate, the maximum rate of benzphetamine-specific NADPH oxidation was approximately 35% of that observed in the presence of dilauroylglyceryl-3-phosphoryl choline. At higher enzyme concentration (2.5 microM) and in the presence of 0.15 M phosphate, 20% glycerol, octylglucoside was as effective as phospholipid in stimulating the production of formaldehyde from benzphetamine. The detergent concentration required for maximal enzymatic activity was 2.5-4.0 g/liter, depending on the cytochrome preparation used. At higher octylglucoside concentrations (5-7 g/liter), activity decreased to zero, although neither enzyme appeared to be irreversibly denatured at these detergent concentrations. Sedimentation equilibrium experiments with P-450LM2 alone or in the presence of equimolar reductase showed that increasing octylglucoside levels promoted disaggregation of the cytochrome. Pentamers and hexamers predominated at detergent concentrations where maximal activity was observed, while higher levels of detergent where activity was absent produced cytochrome dimers and, ultimately, monomers. The reductase was monomeric at detergent levels between at least 3 and 7 g/liter. Moreover, both gel filtration and sedimentation equilibrium experiments demonstrated that a stable complex between P-450LM2 and its reductase was not formed at octylglucoside concentrations where high activity was evident. These results are consistent with a model of P-450/reductase interaction in which functional aggregates of three to six cytochrome polypeptides move laterally in the microsomal membrane and interact with the reductase by random collision.     

Cytochrome P-450 LM2 reduction. Substrate effects on the rate of reductase-LM2 association

The effect of substrate on LM2 reduction was examined using a reconstituted system containing dilauroylphosphatidylcholine, NADPH-cytochrome P-450 reductase, and cytochrome P-450 LM2 in a 160:1.5:1 molar ratio. In general, most substrates increased the rate constants of both the first and second phases of reduction as well as the fraction of LM2 reduced in the first phase. The correlation between the high spin content of the cytochrome and each of these kinetic parameters was weaker than expected if spin state controlled LM2 reduction. Further, substrate was shown to exert a rapid effect on both the high spin content and stimulation of reduction indicating that the low spin to high spin shift cannot be responsible for the slow phase of reduction for this particular isoform. Cytochrome P-450 reduction was also examined in both phospholipid-containing and soluble systems where the LM2 and reductase were not present as a preformed complex. In these systems the reactions were substantially slower than with the standard reconstituted system. Addition of substrate enhanced the rate of reduction, indicating that the rate of association between LM2 and the reductase was increased by substrate addition. The strong correlation between the rate of LM2 reduction in a preformed complex and the logarithm of the rate of LM2 and reductase association implicates the rate of functional complex formation as the factor controlling the slow phase of reduction.     

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.     

The mechanism of hydroperoxide-dependent reactions with participation of cytochrome P-450

Cytochrome P-450 destruction kinetics by cumene hydroperoxide (CHP) has been studied at 25 degrees C in phosphate buffer, pH 7.25-7.50, in various systems: intact and induced rat or rabbit microsomes, highly purified LM2- and LM2- and LM4-forms of cytochrome P-450 from rabbit liver microsomes. The destruction kinetics is characterized by three phases in all systems. The CHP-influenced cytochrome P-450 destruction is a radical chain process with linear termination of the chains. The acidic phospholipids, phosphatidylserine and phosphatidylinositol and total microsomal phospholipids containing the acidic lipid components activate cytochrome P-450 in the hydroxylation of aniline and naphthalene by CHP. Phosphatidylcholine and sphingomyelin have no effect upon the cytochrome P-450 activity in the type I and II substrates oxidation by CHP. The phase transitions of the microsomal phospholipids influence the interaction of cytochrome P-450 with its reductase, altering the activation energy of type I substrates oxidation. The type II substrate oxidation is not affected by phase transitions in the full microsomal hydroxylating system.     

Zwitterionic detergent mediated interaction of purified cytochrome P-450LM4 from 5,6-benzoflavone-treated rabbits with MADPH-cytochrome P-450 reductase

Hydroxylation of acetanilide catalyzed by purified cytochrome P-450LM4 and NADPH-cytochrome P-450 reductase was reconstituted with the zwitterionic detergent 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS). The optimum rate of production of 4-hydroxyacetanilide was observed between 3 and 7 mM CHAPS and was about half that with 0.05 mM dilauroylglyceryl-3-phosphocholine (di-12-GPC). At higher detergent concentrations, hydroxylase activity decreased until at 15-20 mM CHAPS the system was inactive. The effect of CHAPS on the state of aggregation of P-450LM4 and on interaction between the cytochrome and P-450 reductase alone and under turnover conditions was investigated by ultracentrifugation. At 4 mM CHAPS, P-450LM4 was hexameric to heptameric (Mr 369,000). Neither reductase nor reductase plus acetanilide and NADPH altered the state of P-450LM4 aggregation, suggesting that a stable 1:1 P-450/reductase complex did not form under turnover conditions. Replacing CHAPS with 0.05 mM di-12-GPC resulted in formation of heterogeneous P-450 oligomers (Mr greater than 480,000). At CHAPS concentrations where substrate hydroxylation did not occur (15 and 22 mM), P-450LM4 was shown by sedimentation equilibrium measurements to be dimeric and monomeric, respectively. P-450 reductase was shown to reduce monomeric P-450LM4 in the presence of NADPH. Thus, the dependence of hydroxylase activity on [CHAPS] may be related to the state of aggregation of the cytochrome. An apparent correlation between P-450 aggregation state and NADPH-supported hydroxylation was also observed with phenobarbital-inducible P-450LM2 in the presence of detergents [Dean, W.L., & Gray, R.D. (1982) J. Biol. Chem. 257, 14679-14685; Wagner, S.L., Dean, W.L., & Gray, R.D. (1984) J. Biol. Chem. 259, 2390-2395].     

Mechanisms of hydroxyl radical formation and ethanol oxidation by ethanol-inducible and other forms of rabbit liver microsomal cytochromes P-450

The hydroxyl radical-mediated oxidation of 5,5-dimethyl-1-pyrroline N-oxide, benzene, ketomethiolbutyric acid, deoxyribose, and ethanol, as well as superoxide anion and hydrogen peroxide formation was quantitated in reconstituted membrane vesicle systems containing purified rabbit liver microsomal NADPH-cytochrome P-450 reductase and cytochromes P-450 LM2, P-450 LMeb , or P-450 LM4, and in vesicle systems devoid of cytochrome P-450. The presence of cytochrome P-450 in the membranes resulted in 4-8-fold higher rates of O-2, H2O2, and hydroxyl radical production, indicating that the oxycytochrome P-450 complex constitutes the major source for superoxide anions liberated in the system, giving as a consequence hydrogen peroxide and also, subsequently, hydroxyl radicals formed in an iron-catalyzed Haber-Weiss reaction. Depletion of contaminating iron in the incubation systems resulted in small or negligible rates of cytochrome P-450-dependent ethanol oxidation. However, small amounts (1 microM) of chelated iron (e.g. Fe3+-EDTA) enhanced ethanol oxidation specifically when membranes containing the ethanol and benzene-inducible form of cytochrome P-450 (cytochrome P-450 LMeb ) were used. Introduction of the Fe-EDTA complex into P-450 LMeb -containing incubation systems caused a decrease in hydrogen peroxide formation and a concomitant 6-fold increase in acetaldehyde production; consequently, the rate of NADPH consumption was not affected. In iron-depleted systems containing cytochrome P-450 LM2 or cytochrome P-450 LMeb , an appropriate stoichiometry was attained between the NADPH consumed and the sum of hydrogen peroxide and acetaldehyde produced. Horseradish peroxidase and scavengers of hydroxyl radicals inhibited the cytochrome P-450 LMeb -dependent ethanol oxidation both in the presence and in the absence of Fe-EDTA. The results are not consistent with a specific mechanism for cytochrome P-450-dependent ethanol oxidation and indicate that hydroxyl radicals, formed in an iron-catalyzed Haber-Weiss reaction and in a Fenton reaction, constitute the active oxygen species. Cytochrome P-450-dependent ethanol oxidation under in vivo conditions would, according to this concept, require the presence of non-heme iron and endogenous iron chelators.     

Kinetics of elementary steps in the cytochrome P-450 reaction sequence. III. NADPH reduction of cytochrome P-450LM at different integrational levels.

The aerobic NADPH reduction of cytochrome P-450LM has been investigated on microsomes, as well as on the solubilized enzyme system in the associated, disintegrated, and reconstituted state, respectively. P-450 exhibits biphasic reduction kinetics of about 70/30% phase distribution and rate constants differing 10-fold. The partial reactions are due to organizational asymmetries, the cytochrome being either incorporated into P-450/reductase associates (cluster) or localized outside (randomly distributed, homoassociated, weakly cluster-associated). Triton N-101 disintegrates the different associate structures, consequently followed by the disappearance of the rapid reaction phase. The enzyme system can be reconstituted; at microsomal stoichiometry the respective standard parameters are approached, depending on the composition and structural organization of the phospholipid. The reorganization without any membrane matrix is obviously thermodynamically determined.     

Comparative study of monomeric reconstituted and membrane microsomal monooxygenase systems of the rabbit liver. II. Kinetic parameters of reductase and monooxygenase reactions.

The kinetic parameters of NADPH-dependent cytochrome P450 LM2 (2B4) reduction and substrate oxidation in the monomeric reconstituted system, consisting of purified NADPH-cytochrome P450 reductase and cytochrome P450 LM2 monomers, and in phenobarbital-induced rabbit liver microsomes were compared. In the absence of benzphetamine, NADPH-dependent reduction of cytochrome P450 LM2 was monophasic in the monomeric reconstituted system and biphasic in the microsomes. The presence of the substrate in the monomeric reconstituted system caused the appearance of the fast phase. In this system substrate-free cytochrome P450 LM2 was entirely low-spin, and the addition of benzphetamine shifted the spin equilibrium to a high state very weakly. No correlation between high-spin content and the proportion of the fast phase of NADPH-dependent LM2 reduction was found in the system. Vmax values for the oxidation of type I substrates (benzphetamine, dimethylaniline, aminopyrine) in the monomeric reconstituted system were higher or the same as in the microsomes, whereas Km values for the substrates and NADPH were lower in the microsomes. Maximal activity of the monomeric reconstituted system was observed at a 1:1 NADPH-cytochrome P450 reductase/cytochrome P450 LM2 ratio. Measurements of benzphetamine oxidation as a function of NADPH-cytochrome P450 reductase/cytochrome P450 LM2 ratio at a constant total protein concentration allowed the Kd of the NADPH-cytochrome P450 reductase/cytochrome P450 LM2 complex to be estimated as 6.4 +/- 0.5 microM. Complex formation between the NADPH-cytochrome P450 reductase and cytochrome P450 LM2 monomers was not detected by recording the difference binding spectra of the reductase monomers with LM2 monomers or by treatment the mixture of the monomers of the proteins with the crosslinking reagent, water-soluble carbodiimide.     

The functional role of cytochrome b5 reincorporated into hepatic microsomal fractions

Incorporation of detergent-solubilized cytochrome b5 into phenobarbital-induced rabbit liver microsomal fractions decelerates hexobarbital-dependent reduction of ferric cytochrome P-450; this is accompanied by retardation of NADPH utilization and H2O2 formation in the assay media. Integration of manganese-substituted cytochrome b5 into the microsomal preparations fails to affect these parameters. Analysis of the cytochrome P-450 reduction kinetics in the presence of increasing amounts of cytochrome b5 reveals a gradual augmentation of the amplitude of slow-phase electron transfer at the expense of the relative contribution of the fast phase; finally, a slow, apparently monophasic reaction persists. This defect in enzymatic reduction is not due to detergent effects and also does not seem to reflect cytochrome b5-induced perturbation of anchoring of NADPH-cytochrome c(P-450) reductase to cytochrome P-450. Experiments with the highly purified cytochrome P-450 isozyme LM2, in which amino acid residue(s) close to the heme edge had undergone suicidal inactivation through covalent attachment of chloramphenicol metabolite(s) do not exclude the possibility that cytochrome b5 and reductase might compete for a common electron transmission site on the terminal acceptor. Hence, the inhibitory action of cytochrome b5 on the reduction of ferric cytochrome P-450 is tentatively attributed to partial substitution of the former pigment for reductase in direct transport of the first electron to the monooxygenase.     

Mechanism of rate control of the NADPH-dependent reduction of cytochrome P-450 by lipids in reconstituted phospholipid vesicles

The NADPH-supported reduction of cytochrome P-450 LM2 (liver microsomal isozyme 2) in reconstituted phospholipid vesicles in general exhibits two-exponential kinetics. The physiologically relevant rapid partial reaction is favoured in amount with increasing reductase/P-450 ratio. A lipid specificity was observed in that negatively charged lipids favour that process, too. The rate constant increases concomitantly. The data are consistent with the formation of a reactive 1:1 complex the amount of which determines the rate constant. The dissociation constants amount to 0.048 microM for a microsomal lipid extract, 0.051 microM for a 3:1 (w/w) mixture of dioleoylglycerophosphoethanolamine and phosphatidylserine, and 0.47 microM for dioleoylglycerophosphocholine, respectively, in the respective reconstituted systems. At low reductase/P-450 ratio the amount of the rapidly reduced P-450 exceeds the equilibrium concentration of a 1:1 complex. Preformed 1:1 associates, therefore, cannot fit the derived mechanism. Instead, a cluster model based on P-450 association does correspond to the data.     

Hydroxylation of prostaglandins by inducible isozymes of rabbit liver microsomal cytochrome P-450. Participation of cytochrome b5

The hydroxylation of prostaglandin (PG) E1, PGE2, and PGA1 was investigated in a reconstituted rabbit liver microsomal enzyme system containing phenobarbital-inducible isozyme 2 or 5,6-benzoflavone-inducible isoenzyme 4 of P-450, NADPH-cytochrome P-450 reductase, phosphatidylcholine, and NADPH. Significant metabolism of prostaglandins by isozyme 2 occurred only in the presence of cytochrome b5. Under these conditions, PGE1 hydroxylation was linear with time (up to 45 min) and protein concentration, and maximal rates were obtained with a 1:1:2 molar ratio of reductase: cytochrome b5:P-450LM2. Moreover, P-450LM2 catalyzed the conversion of PGE1, PGE2, and PGA1 to the respective 19- and 20-hydroxy metabolites in a ratio of about 5:1, and displayed comparable activities toward the three prostaglandins based on the total products formed in 60 min. Apocytochrome b5 or ferriheme could not substitute for intact cytochrome b5, while reconstitution of apocytochrome b5 with ferriheme led to activities similar to those obtained with the native cytochrome. Isozyme 4 of P-450 differed markedly from isozyme 2 in that it catalyzed prostaglandin hydroxylation at substantial rates in the absence of cytochrome b5, was regiospecific for position 19 of all three prostaglandins, and had an order of activity of PGA1 greater than PGE1 greater than PGE2. P-450LM4 preparations from untreated and induced animals had similar activities with PGE1 and PGE2, respectively. Addition of cytochrome b5 resulted in a 20 to 30% increase in the rate of PGE1 hydroxylation and an appreciably greater enhancement in the extent of all the P-450LM4-catalyzed reactions, the stimulation being greatest with PGE2 (3-fold) and least with PGA1 (1.6-fold). Cytochrome b5 was thus required for maximal metabolism of all three prostaglandins, but did not alter the regiospecificity or the order of activity of P-450 isozyme 4 with the individual substrates. In the presence of cytochrome b5, the prostaglandin hydroxylase activities of isozyme 4 were two to six times higher than those of isozyme 2.     

Role of cytochrome b5 in the cytochrome P-450-mediated C21-steroid 17,20-lyase reaction

The cytochrome P-450 (P-450_sccII) and its reductase, NADPH-cytochrome reductase [EC 1.6.2.4], associated with conversion of progesterone to 4-androstene-3,17-dione, were extensively purified from pig testis microsomes. Higher lyase activity (turnover number of 15 mol of the product formed/min/mol of P-450) could be restored by mixing the P-450_sccII, its reductase, pig liver cytochrome b₅ and cytochrome b₅-reductase [EC 1.6.2.2], and phospholipid in the presence of NADPH, NADH, and O₂. Omission of either cytochrome b₅ or NADH resulted in a significant loss of the lyase activity indicating actual participation of cytochrome b₅ in this P-450-mediated steroidogenic system in the testis.     

Properties of electrophoretically homogeneous phenobarbital-inducible and beta-naphthoflavone-inducible forms of liver microsomal cytochrome P-450.

Procedures are described for the isolation of two forms of rabbit liver microsomal liver microsomal cytochrome P-450 (P-450LM) in homogeneous state. They are designated by their relative electrophoretic mobilities on polyacrylamide gel in the presence of sodium dodecyl sulfate as P-450LM2 and P-450LM4. P-450LM2, which was isolated from phenobarbital-induced animals, has a subunit molecular weight of 48,700. The best preparations contain 20 nmol of the cytochrome per mg of protein and 1 molecule of heme per polypeptide chain. P-450LM4, which is induced by beta-naphthoflavone but is also present in phenobarbital-induced and untreated animals, was isolated from all three sources and found to have a subunit molecular weight of 55,300. The best preparations contain 17nmol of the cytochrome per mg of protein and 1 molecule of heme per polypeptide chain. Some of the purified preparations of the cytochromes, although electrophoretically homogeneous, contain apoenzyme due to heme loss during purification. The purified proteins contain no detectable NADPH-cytochrome P-450 reductase, cytochrome b5, or NADH-cytochrome b5 reductase, and only low levels of phospholipid (about 1 molecule per subunit). Amino acid analysis indicated that P-450LM2 and P-450LM4 are similar in composition, but the latter protein has about 60 additional residues. The COOH-terminal amino acid of P-450LM2 is arginine, as shown by carboxypeptidase treatment, whereas that of P-450LM4 is lysine. NH2-terminal amino acid residues could not be detected. Carbohydrate analysis indicated that both cytochromes contain 1 residue of glucosamine and 2 of mannose per polypeptide subunit. The optical spectra of the oxidized and reduced cytochromes and carbon monoxide complexes were determined. Oxidized P-450LM2 has maxima at 568, 535, and 418 nm characteristic of a low spin hemeprotein, and P450LM4 from beta-naphthoflavone-induced, phenobarbital-induced, or control microsomes has maxima at 645 and 394 nm, characteristic of the high spin state. The spectrum of -450lm4 becomes similar to that of P-450LM2 at high protein concentrations or upon the addition of detergent (Renex), whereas the spectrum of P-450LM2 is unaffected by the protein concentration or the presence of detergent. Electron paramagnetic resonance spectrometry of the purified cytochromes indicated that oxidized -450lm2 is in the low spin state, whereas P-450LM4 is largely, but not entirely, in the high spin state.     

Separate roles for FMN and FAD in catalysis by liver microsomal NADPH-cytochrome P-450 reductase

Rat liver microsomal NADPH-cytochrome P-450 reductase was prepared free of detectable amounts of FMN by a new procedure based on the exchange of this flavin into apoflavodoxin. The resulting FMN-free reductase binds NADP in the oxidized state with the same affinity (Kd = 5 microM) and stoichiometry (1:1 molar ratio) as does the native enzyme. Both the native and FMN-free reductase catalyze rapid reduction of ferricyanide, but the ability to reduce th 5,6-benzoflavone-inducible form of the liver microsomal cytochrome P-450 (P-450LM4) is lost upon removal of FMN. The FMN-free enzyme was reconstituted with artificial flavins which, in the free state, have oxidation-reduction potentials ranging from -152 to -290 mV, including 5-carba-5-deaza-FMN and several FMN analogs with a halogen or sulfur substituent on the dimethylbenzene portion of the ring system. Enzyme reconstituted with 5-carba-5-deaza-FMN has catalytic properties which are not significantly different from those of the FMN-free reductase, and is unable to reduce P-450LM4. On the other hand, the ability to reduce P-450LM4 and the other FMN-dependent activities of the native reductase are restored by substitution of several other analogs for FMN, but the kinetics of P-450LM4 reduction, studied under anaerobic conditions by stopped flow spectrophotometry, are significantly altered. The oxidation-reduction behavior of enzyme reconstituted with 7-nor-7-Br-FMN is substantially different from that of the native enzyme, and less thermodynamic stabilization of the semiquinone is observed with this flavin analog. In contrast, the oxidation-reduction properties of enzyme containing 8-nor-8-mercapto-FMN are similar to those of the native enzyme, but the spectral properties are significantly different. As shown in a stopped flow experiment, reduction of this FMN analog precedes reduction of P-450LM4 when a complex of the flavoprotein and P-450LM4 is allowed to react with NADPH. Our experiments support a sequence of electron transfer in this enzyme system as follows: NADPH leads to FAD leads to FMN leads to P-450. We propose that the enzyme cycles between a le- and a 3e-reduced state during turnover and that electrons are donated to acceptors via the reaction, FMNH2 leads to FMNH ..     

Catalytic properties of the liver microsomal hydroxylase system in reconstituted phospholipid vesicles.

Two types of cytochrome P-450, P-450LM2 and P-450LM3, have been purified from rabbit liver microsomes and incorporated into phospholipid vesicles by a cholate gel filtration technique together with purified preparations of NADPH-cytochrome P-450 reductase. The catalytic properties of the vesicles have been compared with a system reconstituted with small amounts of dilauroylphosphatidylcholine (DLPC). 6 beta-Hydroxylation of androstenedione proceeded at a rate 10 times higher in the vesicles compared to the DLPC-system. The kinetics for the reaction were the same in the vesicles as in intact microsomes i.e. sigmoidal substrate curves were obtained and Hill-coefficients of about 1.4 were calculated in these systems. In contrast, Michaelis-Menten kinetics were obtained for 6 beta-hydroxylation in the DLPC-system. The results could indicate cooperativity between different P-450 molecules in the intact membrane but not in the DLPC-system. P-450LM2-catalyzed 16-hydroxylation of androstenedione was in contrast to the situation with P-450LM3 inhibited in the vesicles as compared to the DLPC system. It is suggested that for evaluation of substrate specificity and other properties of different types of liver microsomal P-450, phospholipid vesicles may be a more relevant integration level than the DLPC-system.     

Hydrodynamic studies on interactions between the components of the liver microsomal cytochrome P-450 system

To understand the different behaviour of cytochrome P-450 systems in kinetics as well as in the demethylase activity, sedimentation and molecular weight experiments have been carried out with the following results: 1) Sedimentation coefficients of solubilized P-450 and P-450 LM2 fractions amount to 24 +/- 4 [S] and 12.8 +/- 1.2 [S], respectively. Molecular weights were determined to be 1.0 +/- 0.2 . 10(6) and 3.0 +/- 0.5 . 10(5) Dalton. 2) Triton N-101 provokes splitting of the associated structure both of solubilized P-450 and P-450 LM2; this effect is reversible. 3) The dissociation depends not only on the absolute concentration of Triton but rather on the Triton P-450 ratio. The dissociation curves of solubilized P-450 and P-450 LM2 are similar in shape and in the Triton/P-450 ratio dependence. 4) In the presence of small concentrations of Triton a more complicated dissociation behaviour was observed with broad integral distribution of the sedimentation coefficients. 5) The ionic detergent cholate splits the associated structure of P-450 LM2 at considerably higher concentrations in comparison with Triton-N 101. 6) Addition of reductase causes a decrease of sedimentation coefficients and molecular weights of solubilized P-450. The same effect in P-450 LM2 could be observed only in the presence of phospholipids.     

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.     

Cytochrome b5 increases the rate of product formation by cytochrome P450 2B4 and competes with cytochrome P450 reductase for a binding site on cytochrome P450 2B4

The kinetics of product formation by cytochrome P450 2B4 were compared in the presence of cytochrome b(5) (cyt b(5)) and NADPH-cyt P450 reductase (CPR) under conditions in which cytochrome P450 (cyt P450) underwent a single catalytic cycle with two substrates, benzphetamine and cyclohexane. At a cyt P450:cyt b(5) molar ratio of 1:1 under single turnover conditions, cyt P450 2B4 catalyzes the oxidation of the substrates, benzphetamine and cyclohexane, with rate constants of 18 +/- 2 and 29 +/- 4.5 s(-1), respectively. Approximately 500 pmol of norbenzphetamine and 58 pmol of cyclohexanol were formed per nmol of cyt P450. In marked contrast, at a cyt P450:CPR molar ratio of 1:1, cyt P450 2B4 catalyzes the oxidation of benzphetamine congruent with100-fold (k = 0.15 +/- 0.05 s(-1)) and cyclohexane congruent with10-fold (k = 2.5 +/- 0.35 s(-1)) more slowly. Four hundred picomoles of norbenzphetamine and 21 pmol of cyclohexanol were formed per nmol of cyt P450. In the presence of equimolar concentrations of cyt P450, cyt b(5), and CPR, product formation is biphasic and occurs with fast and slow rate constants characteristic of catalysis by cyt b(5) and CPR. Increasing the concentration of cyt b(5) enhanced the amount of product formed by cyt b(5) while decreasing the amount of product generated by CPR. Under steady-state conditions at all cyt b(5):cyt P450 molar ratios examined, cyt b(5) inhibits the rate of NADPH consumption. Nevertheless, at low cyt b(5):cyt P450 molar ratios 相似文献