Cytochrome b5 reductase and cytochrome b5 support the CYP2E1-mediated activation of nitrosamines in a recombinant Ames test

With CYP2E1 in vitro both the first and the second electron of the catalytic cycle can come from cytochrome b(5) via either NADPH-cytochrome P450 reductase or NADH-cytochrome b(5) reductase, and the presence of cytochrome b(5) stimulates CYP2E1 turnover both in vitro and in vivo. To determine whether electron input via the NADH-dependent pathway was similarly functional in whole cells and necessary for the stimulation by cytochrome b(5), we constructed five plasmids designed to express human CYP2E1 in various combinations with cytochrome b(5) reductase, cytochrome b(5), and cytochrome P450 reductase. CYP2E1 activity in Salmonella typhimurium cells transformed with each plasmid was assessed by mutagenic reversion frequency in the presence of dimethylnitrosamine. A fivefold increase in reversion frequency when cytochrome b(5) was coexpressed with P450 reductase was abolished by disruption of heme-binding in cytochrome b(5) by site-directed mutagenesis (His68Ala), suggesting that electron transfer to cytochrome b(5) was necessary for the stimulation. Addition of cytochrome b(5) reductase to the cytochrome b(5)/P450 reductase coexpression plasmid did not further increase the stimulation by cytochrome b(5), but b(5) reductase could support CYP2E1 activity in the absence of P450 reductase at a level equivalent to that obtained with just CYP2E1 and P450 reductase. Neither cytochrome b(5) reductase nor cytochrome b(5) alone could support CYP2E1 activity. These results demonstrate that the cytochrome b(5) reductase/cytochrome b(5) pathway can support CYP2E1 activity in bacterial cells.     

The interaction of microsomal cytochrome P450 2B4 with its redox partners, cytochrome P450 reductase and cytochrome b(5)

Cytochrome P450 2B4 is a microsomal protein with a multi-step reaction cycle similar to that observed in the majority of other cytochromes P450. The cytochrome P450 2B4-substrate complex is reduced from the ferric to the ferrous form by cytochrome P450 reductase. After binding oxygen, the oxyferrous protein accepts a second electron which is provided by either cytochrome P450 reductase or cytochrome b₅. In both instances, product formation occurs. When the second electron is donated by cytochrome b₅, catalysis (product formation) is ∼10- to 100-fold faster than in the presence of cytochrome P450 reductase. This allows less time for side product formation (hydrogen peroxide and superoxide) and improves by ∼15% the coupling of NADPH consumption to product formation. Cytochrome b₅ has also been shown to compete with cytochrome P450 reductase for a binding site on the proximal surface of cytochrome P450 2B4. These two different effects of cytochrome b₅ on cytochrome P450 2B4 reactivity can explain how cytochrome b₅ is able to stimulate, inhibit, or have no effect on cytochrome P450 2B4 activity. At low molar ratios (<1) of cytochrome b₅ to cytochrome P450 reductase, the more rapid catalysis results in enhanced substrate metabolism. In contrast, at high molar ratios (>1) of cytochrome b₅ to cytochrome P450 reductase, cytochrome b₅ inhibits activity by binding to the proximal surface of cytochrome P450 and preventing the reductase from reducing ferric cytochrome P450 to the ferrous protein, thereby aborting the catalytic reaction cycle. When the stimulatory and inhibitory effects of cytochrome b₅ are equal, it will appear to have no effect on the enzymatic activity. It is hypothesized that cytochrome b₅ stimulates catalysis by causing a conformational change in the active site, which allows the active oxidizing oxyferryl species of cytochrome P450 to be formed more rapidly than in the presence of reductase.     

Chlorzoxazone hydroxylation in microsomes and hepatocytes from cytochrome P450 oxidoreductase‐null mice

Previous studies have demonstrated that the NADH‐dependent cytochrome b₅ electron transfer pathway can support some cytochrome P450 monooxygenases in vitro in the absence of their normal redox partner, NADPH‐cytochrome P450 oxidoreductase. However, the ability of this pathway to support P450 activity in whole cells and in vivo remains unresolved. To address this question, liver microsomes and hepatocytes were prepared from hepatic cytochrome P450 oxidoreductase‐null mice and chlorzoxazone hydroxylation, a reaction catalyzed primarily by cytochrome P450 2E1, was evaluated. As expected, NADPH‐supported chlorzoxazone hydroxylation was absent in liver microsomes from oxidoreductase‐null mice, whereas NADH‐supported activity was about twofold higher than that found in normal (wild‐type) liver microsomes. This greater activity in oxidoreductase‐null microsomes could be attributed to the fourfold higher level of CYP2E1 and 1.4‐fold higher level of cytochrome b₅. Chlorzoxazone hydroxylation in hepatocytes from oxidoreductase‐null mice was about 5% of that in hepatocytes from wild‐type mice and matched the results obtained with wild‐type microsomes, where activity obtained with NADH was about 5% of that obtained when both NADH and NADPH were included in the reaction mixture. These results argue that the cytochrome b₅ electron transfer pathway can support a low but measurable level of CYP2E1 activity under physiological conditions. © 2009 Wiley Periodicals, Inc. J Biochem Mol Toxicol 23:357–363, 2009; Published online in Wiley InterScience ( www.interscience.wiley.com ). DOI 10.1002/jbt.20299     

Role of cytochrome b5 in catalysis by cytochrome P450 2B4

Cytochrome b5 has been shown to stimulate, inhibit or have no effect on catalysis by P450 cytochromes. Its action is known to depend on the isozyme of cytochrome P450, the substrate, and experimental conditions. Cytochrome P450 2B4 (CYP 2B4) has been used in our laboratory as a model isozyme to study the role of cytochrome b5 in cytochrome P450 catalysis using two substrates, methoxyflurane and benzphetamine. One substrate is the volatile anesthetic, methoxyflurane, whose metabolism is consistently markedly stimulated by cytochrome b5. The other is benzphetamine, whose metabolism is minimally modified by cytochrome b5. Determination of the stoichiometry of the metabolism of both substrates showed that the amount of product formed is the net result of the simultaneous stimulatory and inhibitory actions of cytochrome b5 on catalysis. Site-directed mutagenesis studies revealed that both cytochrome b5 and cytochrome P450 reductase interact with cytochrome P450 on its proximal surface on overlapping but non-identical binding sites. Comparison of the rate of reduction of oxyferrous CYP 2B4 and the rate of substrate oxidation by cyt b5 and reductase with stopped-flow spectrophotometric and rapid chemical quench experiments has demonstrated that although cytochrome b5 and reductase reduce oxyferrous CYP 2B4 at the same rate, substrate oxidation proceeds more slowly in the presence of the reductase.     

Interactions of mammalian cytochrome P450, NADPH-cytochrome P450 reductase, and cytochrome b(5) enzymes

An immobilized system was developed to detect interactions of human cytochromes P450 (P450) with the accessory proteins NADPH-P450 reductase and cytochrome b(5) (b(5)) using an enzyme-linked affinity approach. Purified enzymes were first bound to wells of a polystyrene plate, and biotinylated partner enzymes were added and bound. A streptavidin-peroxidase complex was added, and protein-protein binding was monitored by measuring peroxidase activity of the bound biotinylated proteins. In a model study, we examined protein-protein interactions of Pseudomonas putida putidaredoxin (Pdx) and putidaredoxin reductase (PdR). A linear relationship (r(2)=0.96) was observed for binding of PdR-biotin to immobilized Pdx compared with binding of Pdx-biotin to immobilized PdR (the estimated K(d) value for the Pdx.PdR complex was 0.054muM). Human P450 2A6 interacted strongly with NADPH-P450 reductase; the K(d) values (with the reductase) ranged between 0.005 and 0.1muM for P450s 2C19, 2D6, and 3A4. Relatively weak interaction was found between holo-b(5) or apo-b(5) (devoid of heme) with NADPH-P450 reductase. Among the rat, rabbit, and human P450 1A2 enzymes, the rat enzyme showed the tightest interaction with b(5), although no increases in 7-ethoxyresorufin O-deethylation activities were observed with any of the P450 1A2 enzymes. Human P450s 2A6, 2D6, 2E1, and 3A4 interacted well with b(5), with P450 3A4 yielding the lowest K(d) values followed by P450s 2A6 and 2D6. No appreciable increases in interaction between human P450s with b(5) or NADPH-P450 reductase were observed when typical substrates for the P450s were included. We also found that NADPH-P450 reductase did not cause changes in the P450.substrate K(d) values estimated from substrate-induced UV-visible spectral changes with rabbit P450 1A2 or human P450 2A6, 2D6, or 3A4. Collectively, the results show direct and tight interactions between P450 enzymes and the accessory proteins NADPH-P450 reductase and b(5), with different affinities, and that ligand binding to mammalian P450s did not lead to increased interaction between P450s and the reductase.     

Reduction of cytochrome b5 by NADPH-cytochrome P450 reductase

The reduction of mammalian cytochrome b5 (b5) by NADPH-cytochrome P450 (P450) reductase is involved in a number of biological reactions. The kinetics of the process have received limited consideration previously, and a combination of pre-steady-state (stopped-flow) and steady-state approaches was used to investigate the mechanism of b5 reduction. In the absence of detergent or lipid, a reductase-b5 complex is formed and rearranges slowly to an active form. Electron transfer to b5 is rapid within this complex (>30 s(-1) at 23 degrees C), as fast as to cytochrome c. With excess b5 present, a burst of reduction is observed, consistent with rapid electron transfer to one or two b5 molecules per reductase, followed by a subsequent rate-limiting event. In detergent vesicles, the reductase and b5 interact rapidly but electron transfer is slower (approximately 3 s(-1) at 23 degrees C). Experiments with dimyristyl lecithin vesicles yielded results intermediate between the non-vesicle and detergent systems. These steady-state and pre-steady-state kinetics provide views of the different natures of the reduction of b5 by the reductase in the absence and presence of vesicles. Without vesicles, the encounter of the reductase and b5 is rapid, followed by a slow reorganization of the initial complex (approximately 0.07 s(-1)), very fast reduction, and dissociation. In vesicles, encounter is rapid and the slow step (approximately 3 s(-1)) is reduction within a complex less favorable for reduction than in the non-vesicle systems.     

Differential effect of phenobarbital and beta-naphthoflavone on the mRNAs coding for cytochrome P450 and NADPH cytochrome P450 reductase

The induction in rat liver of a specific variant(s) of cytochrome P450 (PB-P450) by phenobarbital and its repression by β-naphthoflavone occur through corresponding changes in the levels of mRNA coding for the protein(s). The level of translatable mRNA coding for NADPH-cytochrome P450 reductase in rat liver increases on treatment with phenobarbital but not β-naphthoflavone.     

Stimulation of cytochrome P450 reactions by apo-cytochrome b5: evidence against transfer of heme from cytochrome P450 3A4 to apo-cytochrome b5 or heme oxygenase.

Many cytochrome P450 (P450)-dependent reactions have been shown to be stimulated by another microsomal protein, cytochrome b(5) (b(5)). Two major explanations are (i) direct electron transfer from b(5) and (ii) a conformational effect in the absence of electron transfer. Some P450s (e.g. 3A4, 2C9, 17A, and 4A7) are stimulated by either b(5) or b(5) devoid of heme (apo-b(5)), indicating a lack of electron transfer, whereas other P450s (e.g. 2E1) are stimulated by b(5) but not by apo-b(5). Recently, a proposal has been made by Guryev et al. (Biochemistry 40, 5018-5031, 2001) that the stimulation by apo-b(5) can be explained only by transfer of heme from P450 preparations to apo-b(5), enabling electron transfer. We have repeated earlier findings of stimulation of catalytic activity of testosterone 6beta-hydroxylation activities with four P450 preparations, in which nearly all of the heme was accounted for as P450. Spectral analysis of mixtures indicated that only approximately 5% of the heme can be transferred to apo-b(5), which cannot account for the observed stimulation. The presence of the heme scavenger apomyoglobin did not inhibit the stimulation of P450 3A4-dependent testosterone or nifedipine oxidation activity. Further evidence against the presence of loosely bound P450 3A4 heme was provided in experiments with apo-heme oxygenase, in which only 3% of the P450 heme was converted to biliverdin. Finally, b(5) supported NADH-b(5) reductase/P450 3A4-dependent testosterone 6beta-hydroxylation, but apo-b(5) did not. Thus, apo-b(5) can stimulate P450 3A4 reactions as well as b(5) in the absence of electron transfer, and heme transfer from P450 3A4 to apo-b(5) cannot be used to explain the catalytic stimulation.     

Inhibition studies on the involvement of flavoprotein reductases in menadione- and nitrofurantoin-stimulated oxyradical production by hepatic microsomes of flounder (Platichthys flesus)

Inhibitors of mammalian cytochrome P450 and P450 reductase were used to investigate the enzymes in flounder (Platichthys flesus) hepatic microsomes involved in the stimulation of NAD(P)H-dependent iron/EDTA-mediated 2-keto-4-methiolbutyric acid (KMBA) oxidation (hydroxyl radical production) by the redox cycling compounds menadione and nitrofurantoin. Inhibitors were first tested for their effects on flounder microsomal P450 and flavoprotein reductase activities. Ellipticine gave type II difference binding spectra (app. K_s 5.36 μM; ΔA max 0.16 nmol-1 P450) and markedly inhibited NADPH-cytochrome c reductase, NADPH-cytochrome P450 reductase, and monooxygenase (benzo[a]pyrene metabolism) activities. 3-aminopyridine adenine dinucleotide phosphate (AADP; competitive inhibitor of P450 reductase) inhibited NADPH-cytochrome c but not NADH-cytochrome c or NADH-ferricyanide reductase activities. Alkaline phosphatase (inhibitor of rabbit P450 reductase) stimulated NADPH-cytochrome c reductase activity seven fold but had less effect on NADH-reductase activities. AADP inhibited nitrofurantoin- and menadione-stimulated KMBA oxidation by 45 and 17%, respectively, indicating the involvement of P450 reductase at least in the former. In contrast, ellipticine had relatively little effect, possibly because, unlike cytochrome c, the smaller xenobiotic molecules can access the hydrophilic binding site of P450 reductase. Alkaline phosphatase stimulated NAD(P)H-dependent basal and xenobiotic-stimulated KMBA oxidation, showing general consistency with the results for reductase activities. Overall, the studies indicate both similarities (ellipticine, AADP) and differences (alkaline phosphatase) between the flounder and rat hepatic microsomal enzyme systems.     

Biochemical characteristics of purified beef liver NADPH-cytochrome P450 reductase

NADPH-cytochrome P450 reductase, an obligatory component of the cytochrome P450 dependent monooxygenase system, was purified to electrophoretic homogeneity from beef liver microsomes. The purification procedure involved the ion exchange chromatography of the detergent-solubilized microsomes on first and second DEAE-cellulose columns, followed by 2',5'-ADP Sepharose affinity chromatography. Further concentration of the enzyme and removal of Emulgen 913 and 2'-AMP were accomplished on the final hydroxylapatite column. The enzyme was purified 239-fold and the yield was 13.5%. Monomer molecular weight of the enzyme was estimated to be 76000 +/- 3000 (N = 5) by SDS-PAGE. The absolute absorption spectrum of beef reductase showed two peaks at 455 and 378 nm, with a shoulder at 478 nm, characteristics of flavoproteins. The effects of cytochrome c concentration, pH, and ionic strength on enzyme activity were studied. Reduction of cytochrome c with the enzyme followed Michaelis-Menten kinetics, and the apparent K(m) of the purified enzyme was found to be 47.7 microM for cytochrome c when the enzyme activity was measured in 0.3 M potassium phosphate buffer (pH 7.7). Stability of cytochrome c reductase activity was examined at 25 and 37 degrees C in the presence and absence of 20% glycerol. The presence of glycerol enhanced the stability of cytochrome c reductase activity at both temperatures. Sheep lung microsomal cytochrome P4502B and NADPH-cytochrome P450 reductase were also purified by the already existing methods developed in our laboratory. Both beef liver and sheep lung reductases were found to be effective in supporting benzphetamine and cocaine N-demethylation reactions in the reconstituted systems containing purified sheep lung cytochrome P4502B and synthetic lipid, phosphatidylcholine dilauroyl.     

Biodiversity of the P450 catalytic cycle: yeast cytochrome b5/NADH cytochrome b5 reductase complex efficiently drives the entire sterol 14-demethylation (CYP51) reaction

The widely accepted catalytic cycle of cytochromes P450 (CYP) involves the electron transfer from NADPH cytochrome P450 reductase (CPR), with a potential for second electron donation from the microsomal cytochrome b5/NADH cytochrome b5 reductase system. The latter system only supported CYP reactions inefficiently. Using purified proteins including Candida albicans CYP51 and yeast NADPH cytochrome P450 reductase, cytochrome b5 and NADH cytochrome b5 reductase, we show here that fungal CYP51 mediated sterol 14alpha-demethylation can be wholly and efficiently supported by the cytochrome b5/NADH cytochrome b5 reductase electron transport system. This alternative catalytic cycle, where both the first and second electrons were donated via the NADH cytochrome b5 electron transport system, can account for the continued ergosterol production seen in yeast strains containing a disruption of the gene encoding CPR.     

Differential effect of phenobarbital and β-naphthoflavone on the mRNAs coding for cytochrome P450 and NADPH cytochrome P450 reductase

The induction in rat liver of a specific variant(s) of cytochrome P450 (PB-P450) by phenobarbital and its repression by β-naphthoflavone occur through corresponding changes in the levels of mRNA coding for the protein(s). The level of translatable mRNA coding for NADPH-cytochrome P450 reductase in rat liver increases on treatment with phenobarbital but not β-naphthoflavone.     

Examining the mechanism of stimulation of cytochrome P450 by cytochrome b5: the effect of cytochrome b5 on the interaction between cytochrome P450 2B4 and P450 reductase

Dissociation constants K(d) for cytochrome P450 reductase (reductase) and cytochrome P450 2B4 are measured in the presence of various substrates. Aminopyrine increases the dissociation constant for binding of the two proteins. Furthermore, cytochrome b(5) (b(5)) stimulates metabolism of this substrate and dramatically decreases the substrate-related K(d) values. Experiments are performed to test if the b(5)-mediated stimulation is effected through a conformational change of P450. The effects of a redox-inactive analogue of b(5) (Mn b(5)) on product formation and reaction stoichiometry are determined. Variations in the concentration of Mn b(5) stock solution that have been shown to effect the aggregation state of the protein alter the rate of P450-mediated NADPH oxidation but have no effect on the rate of product formation. Thus, the electron transfer capability of b(5) is necessary for stimulation of metabolism. Furthermore, stopped flow spectrometry measurements of the rate of first electron reduction of the P450 by reductase indicate that the coupling of P450 2B4-mediated metabolism improves, in the presence of Mn b(5), with slower delivery of the first electron of the catalytic cycle by the reductase. These results are consistent with a model involving the regulation of the P450 catalytic cycle by conformational changes of the P450 enzyme. We propose that the conformational change(s) necessary for progression of the catalytic cycle is inhibited when reduced, but not oxidized, reductase is bound to the P450.     

Co-incorporation of heterologously expressed Arabidopsis cytochrome P450 and P450 reductase into soluble nanoscale lipid bilayers

Heterologous expression of CYP73A5, an Arabidopsis cytochrome P450 monooxygenase, in baculovirus-infected insect cells yields correctly configured P450 detectable by reduced CO spectral analysis in microsomes and cell lysates. Co-expression of a housefly NADPH P450 reductase substantially increases the ability of this P450 to hydroxylate trans-cinnamic acid, its natural phenylpropanoid substrate. For development of high-throughput P450 substrate profiling procedures, membrane proteins derived from cells overexpressing CYP73A5 and/or NADPH P450 reductase were incorporated into soluble His(6)-tagged nanoscale lipid bilayers (Nanodiscs) using a simple self-assembly process. Biochemical characterizations of nickel affinity-purified and size-fractionated Nanodiscs indicate that CYP73A5 protein assembled into Nanodiscs in the absence of NADPH P450 reductase maintains its ability to bind its t-cinnamic acid substrate. CYP73A5 protein co-assembled with P450 reductase into Nanodiscs hydroxylates t-cinnamic acid using reduced pyridine nucleotide as an electron source. These data indicate that baculovirus-expressed P450s assembled in Nanodiscs can be used to define the chemical binding profiles and enzymatic activities of these monooxygenases.     

Thermal inactivation of the reductase domain of cytochrome P450 BM3

Although the reductase domain of cytochrome P450 BM3 (BMR) catalyzes the reduction of cytochrome c and 2,6-dichlorophenolindophenol, we observed a catalytically independent loss of activity. By varying the incubation time for the enzyme prior to reaction initiation, we measured an inactivation rate of 0.22 min(-1). We hypothesized that either an active BMR dimer dissociates to an inactive monomer or BMR undergoes denaturation. We were not able to trap or destabilize a dimer, and BMR inactivation proved to be irreversible. Addition of excess FMN only slightly decreased the rate of inactivation from 0.22 to 0.13 min(-1), indicating inactivation likely does not reflect loss of flavin. When inactivation rates as a function of temperature were fit to the Arrhenius equation, the energy required to inactivate BMR was 9.9 kcal mol(-1)--equivalent to a few hydrogen bonds. The potential instability of BMR under certain conditions raises concerns for the use of BMR as a model or surrogate P450 reductase in other systems.     

Reconstitution of the Brain Mixed Function Oxidase System: Purification of NADPH-Cytochrome P450 Reductase and Partial Purification of Cytochrome P450 from Whole Rat Brain

NADPH-cytochrome P450 reductase was purified to apparent homogeneity and cytochrome P450 partially purified from whole rat brain. Purified reductase from brain was identical to liver P450 reductase by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and western blot techniques. Kinetic studies using cerebral P450 reductase reveal Km values in close agreement with those determined with enzyme purified from rat liver. Moreover, the brain P450 reductase was able to function successfully in a reconstituted microsomal system with partially purified brain cytochrome P450 and with purified hepatic P450c (P450IA1) as measured by 7-ethoxycoumarin and 7-ethoxyresorufin O-deethylation. Our results indicate that the reductase and P450 components may interact to form a competent drug metabolism system in brain tissue.     

Comparison of intrinsic dynamics of cytochrome p450 proteins using normal mode analysis

Cytochrome P450 enzymes are hemeproteins that catalyze the monooxygenation of a wide‐range of structurally diverse substrates of endogenous and exogenous origin. These heme monooxygenases receive electrons from NADH/NADPH via electron transfer proteins. The cytochrome P450 enzymes, which constitute a diverse superfamily of more than 8,700 proteins, share a common tertiary fold but < 25% sequence identity. Based on their electron transfer protein partner, cytochrome P450 proteins are classified into six broad classes. Traditional methods of protein classification are based on the canonical paradigm that attributes proteins’ function to their three‐dimensional structure, which is determined by their primary structure that is the amino acid sequence. It is increasingly recognized that protein dynamics play an important role in molecular recognition and catalytic activity. As the mobility of a protein is an intrinsic property that is encrypted in its primary structure, we examined if different classes of cytochrome P450 enzymes display any unique patterns of intrinsic mobility. Normal mode analysis was performed to characterize the intrinsic dynamics of five classes of cytochrome P450 proteins. The present study revealed that cytochrome P450 enzymes share a strong dynamic similarity (root mean squared inner product > 55% and Bhattacharyya coefficient > 80%), despite the low sequence identity (< 25%) and sequence similarity (< 50%) across the cytochrome P450 superfamily. Noticeable differences in C_α atom fluctuations of structural elements responsible for substrate binding were noticed. These differences in residue fluctuations might be crucial for substrate selectivity in these enzymes.     

Crystal structure of the FMN-binding domain of human cytochrome P450 reductase at 1.93 A resolution

The crystal structure of the FMN-binding domain of human NADPH-cytochrome P450 reductase (P450R-FMN), a key component in the cytochrome P450 monooxygenase system, has been determined to 1.93 A resolution and shown to be very similar both to the global fold in solution (Barsukov I et al., 1997, J Biomol NMR 10:63-75) and to the corresponding domain in the 2.6 A crystal structure of intact rat P450R (Wang M et al., 1997, Proc Nat Acad Sci USA 94:8411-8416). The crystal structure of P450R-FMN reported here confirms the overall similarity of its alpha-beta-alpha architecture to that of the bacterial flavodoxins, but reveals differences in the position, number, and length of the helices relative to the central beta-sheet. The marked similarity between P450R-FMN and flavodoxins in the interactions between the FMN and the protein, indicate a striking evolutionary conservation of the FMN binding site. The P450R-FMN molecule has an unusual surface charge distribution, leading to a very strong dipole, which may be involved in docking cytochrome P450 into place for electron transfer near the FMN. Several acidic residues near the FMN are identified by mutagenesis experiments to be important for electron transfer to P4502D6 and to cytochrome c, a clear indication of the part of the molecular surface that is likely to be involved in substrate binding. Somewhat different parts are found to be involved in binding cytochrome P450 and cytochrome c.     

Adrenodoxin supports reactions catalyzed by microsomal steroidogenic cytochrome P450s

The interaction of adrenodoxin (Adx) and NADPH cytochrome P450 reductase (CPR) with human microsomal steroidogenic cytochrome P450s was studied. It is found that Adx, mitochondrial electron transfer protein, is able to support reactions catalyzed by human microsomal P450s: full length CYP17, truncated CYP17, and truncated CYP21. CPR, but not Adx, supports activity of truncated CYP19. Truncated and the full length CYP17s show distinct preference for electron donor proteins. Truncated CYP17 has higher activity with Adx compared to CPR. The alteration in preference to electron donor does not change product profile for truncated enzymes. The electrostatic contacts play a major role in the interaction of truncated CYP17 with either CPR or Adx. Similarly electrostatic contacts are predominant in the interaction of full length CYP17 with Adx. We speculate that Adx might serve as an alternative electron donor for CYP17 at the conditions of CPR deficiency in human.     

The cytochrome P450 2B4-NADPH cytochrome P450 reductase electron transfer complex is not formed by charge-pairing.

Attempts to covalently link NADPH-cytochrome P450 reductase to cytochrome P450 2B4 using a water-soluble carbodiimide, 1-ethyl-3-(3-dimethylisopropyl)carbodiimide, were unsuccessful, despite the fact that under the same conditions about 30% of P450 2B4 could be covalently linked with cytochrome b5 in a functionally active complex (Tamburini, P. P., and Schenkman, J. B. (1987) Proc. Natl. Acad. Sci. U. S. A. 84, 11-15). This suggested that the functional electron transfer complex between P450 2B4 and reductase is not stabilized by electrostatic forces. Raising the ionic strength of the medium is disruptive to salt bridges and was used to further test whether P450 2B4 and the reductase form charge-pairing complexes. Instead of inhibiting electron transfer, high ionic strength increased the apparent fast phase rate constant and the fraction of P450 2B4 reduced in the fast phase. The possibility that electron transfer between NADPH-cytochrome P450 reductase and P450 2B4 is diminished by charge repulsion was examined. Consistent with this hypothesis, the Km of P450 2B4 for reductase was decreased 26-fold by increasing the ionic strength from 10 to 100 mM sodium phosphate without affecting the Vmax. The rate of benzphetamine N-demethylation also was increased by elevation of the ionic strength. Electron transfer from the reductase to other charged redox acceptors, e.g. cytochrome c and ferricyanide, was also stimulated by increased ionic strength. However, no similar stimulation was observed with the uncharged acceptor 1,4-benzoquinone. Polylysine, a polypeptide that binds to anionic sites, enhanced electron transfer from NADPH to ferricyanide and the apparent fast phase of reduction of cytochrome P450. The results are consistent with the hypothesis that charges on NADPH-cytochrome P450 reductase and cytochrome P450 decrease the stability of the electron transfer complex.