flavin-adenine-dinucleotide and lauric-acid

Interactions between a soluble form of microsomal cytochrome b(5) (b(5)) from Musca domestica (housefly) and Bacillus megaterium flavocytochrome P450 BM3 and its component reductase (CPR), heme (P450) and FAD/NADPH-binding (FAD) domains were analyzed by a combination of steady-state and stopped-flow kinetics methods, and optical spectroscopy techniques. The high affinity binding of b(5) to P450 BM3 induced a low-spin to high-spin transition in the P450 heme iron (K(d) for b(5) binding = 0.44 microM and 0.72 microM for the heme domain and intact flavocytochrome, respectively). The b(5) had modest inhibitory effects on steady-state turnover of P450 BM3 with fatty acids, and the ferrous-carbon monoxy P450 complex was substantially stabilized on binding b(5). Single turnover reduction of b(5) by BM3 using stopped-flow absorption spectroscopy (k(lim) = 116 s(-1)) was substantially faster than steady-state reduction of b(5) by P450 BM3 (or its CPR and FAD domains), indicating rate-limiting step(s) other than BM3 flavin-to-b(5) heme electron transfer in the steady-state reaction. Steady-state b(5) reduction by P450 BM3 was considerably accelerated at high ionic strength. Pre-reduction of P450 BM3 by NADPH decreased the k(lim) for b(5) reduction approximately 10-fold, and also resulted in a lag phase in steady-state b(5) reduction that was likely due to BM3 conformational perturbations sensitive to the reduction state of the flavocytochrome. Ferrous b(5) could not reduce the ferric P450 BM3 heme domain under anaerobic conditions, consistent with heme iron reduction potentials of the two proteins. However, rapid oxidation of both hemoproteins occurred on aeration of the ferrous protein mixture (and despite the much slower autoxidation rate of b(5) in isolation), consistent with electron transfer occurring from b(5) to the oxyferrous P450 BM3 in the complex. The results demonstrate that strong interactions occur between a eukaryotic b(5) and a model prokaryotic P450. Binding of b(5) perturbs BM3 heme iron spin-state equilibrium, as is seen in many physiologically relevant b(5) interactions with eukaryotic P450s. These results are consistent with the conservation of structure of P450s (particularly at the heme proximal face) between prokaryotes and eukaryotes, and may point to as yet undiscovered roles for b(5)-like proteins in the control of activities of certain prokaryotic P450s.

Topics: Animals; Bacillus megaterium; Bacterial Proteins; Cytochrome P-450 Enzyme System; Cytochromes b5; Electron Transport; Flavin-Adenine Dinucleotide; Flavins; Heme; Houseflies; Kinetics; Lauric Acids; Mixed Function Oxygenases; NADP; NADPH-Ferrihemoprotein Reductase; Oxidation-Reduction; Protein Conformation; Spectrophotometry, Ultraviolet; Substrate Specificity

Cytochrome P450BM3 is a self-sufficient soluble fatty acid hydroxylase from Bacillus megaterium utilizing tightly bound FAD and FMN cofactors to transfer reducing equivalents from NADPH to the heme active site. Active-inactive transitions of cytochrome P450BM3 were exploited to identify catalytic intermediates of the enzyme. Shortly upon reduction by NADPH, a two-electron reduced active P450BM3 is formed with two flavin semiquinones, anionic and neutral, present simultaneously. P450BM3 inactivated by NADPH has a three-electron reduced flavoprotein domain. NADPH is unable to reduce P450BM3 rapidly unless the flavoprotein domain is fully oxidized. During steady-state hydroxylation of a poor substrate, tetradecanol, the flavoprotein reduction state does not exceed two, with two flavin semiquinones, anionic and neutral, present. Absorbance and EPR spectroscopic characterization of both anionic and neutral flavin semiquinone is presented. NADPH and NADH were compared as electron donors for P450BM3-catalyzed fatty acid hydroxylation and cytochrome c and heme iron reduction. The Km for NADH of 3-5 mM is about 3000 times higher than the Km of 1-1.5 microM for NADPH. Although NADH can support cytochrome c reduction and fatty acid hydroxylation with the rates as high as 22 and 13 s-1, respectively, these turnover numbers are only about 20% of those observed with NADPH. The results suggest that nucleotide binding plays an important role in catalysis by controlling electron-transfer properties of the flavin cofactors. In W574G and G570D mutant P450BM3 enzymes that are deficient in FMN, NADP+ binding stabilizes fully reduced FAD. P450BM3 catalyzes single-turnover and steady-state laurate hydroxylation with near stoichiometric product formation at NADPH concentrations below that of the enzyme. A mechanism of electron transfer by the flavoprotein domain of P450BM3 is proposed with the reduction state of the flavoprotein domain cycling in a 0-2-1-0 sequence. We also propose that an interaction of bound NADP+ with anionic FAD semiquinone is essential for splitting a pair of electrons that are then transferred in two one-electron transfer steps to the heme catalytic site.

Topics: Bacillus megaterium; Bacterial Proteins; Catalysis; Cytochrome c Group; Cytochrome P-450 Enzyme System; Electron Spin Resonance Spectroscopy; Electron Transport; Flavin-Adenine Dinucleotide; Hydroxylation; Kinetics; Lauric Acids; Mixed Function Oxygenases; NAD; NADP; NADPH-Ferrihemoprotein Reductase; Oxidation-Reduction; Spectrophotometry

The cyclic enzymatic function of a cytochrome P450, as it catalyzes the oxygen-dependent metabolism of many organic chemicals, requires the delivery of two electrons to the hemeprotein. In general these electrons are transferred from NADPH to the P450 via an FMN- and FAD-containing flavoprotein (NADPH-P450 reductase). The present paper shows that NADPH can be replaced by an electrochemically generated reductant [cobalt(II) sepulchrate trichloride] for the electrocatalytically driven omega-hydroxylation of lauric acid. Results are presented illustrating the use of purified recombinant proteins containing P450 4A1, such as the fusion protein (rFP450 [mRat4A1/mRatOR]L1) or a system reconstituted with purified P450 4A1 plus purified NADPH-P450 reductase. Rates of formation of 12-hydroxydodecanoic acid by the electrochemical method are comparable to those obtained using NADPH as electron donor. These results suggest the practicality of developing electrocatalytically dependent bioreactors containing different P450s as catalysts for the large-scale synthesis of stereo- and regio-selective hydroxylation products of many chemicals.

Topics: Animals; Catalysis; Cobalt; Cytochrome P-450 CYP4A; Cytochrome P-450 Enzyme System; Electrochemistry; Flavin-Adenine Dinucleotide; Hydroxylation; Kinetics; Lauric Acids; Mixed Function Oxygenases; NADP; NADPH-Ferrihemoprotein Reductase; Rats; Recombinant Fusion Proteins