NADPH oxidase-derived H2O2 subverts pathogen signaling by oxidative phosphotyrosine conversion to PB-DOPA.

Strengthening the host immune system to fully exploit its potential as antimicrobial defense is vital in countering antibiotic resistance. Chemical compounds released during bidirectional host-pathogen cross-talk, which follows a sensing-response paradigm, can serve as protective mediators. A potent, diffusible messenger is hydrogen peroxide (H2O2), but its consequences on extracellular pathogens are unknown. Here we show that H2O2, released by the host on pathogen contact, subverts the tyrosine signaling network of a number of bacteria accustomed to low-oxygen environments. This defense mechanism uses heme-containing bacterial enzymes with peroxidase-like activity to facilitate phosphotyrosine (p-Tyr) oxidation. An intrabacterial reaction converts p-Tyr to protein-bound dopa (PB-DOPA) via a tyrosinyl radical intermediate, thereby altering antioxidant defense and inactivating enzymes involved in polysaccharide biosynthesis and metabolism. Disruption of bacterial signaling by DOPA modification reveals an infection containment strategy that weakens bacterial fitness and could be a blueprint for antivirulence approaches.

Cj1411c encodes for a cytochrome P450 involved in Campylobacter jejuni 81-176 pathogenicity.

Cytochrome P450s are b-heme-containing enzymes that are able to introduce oxygen atoms into a wide variety of organic substrates. They are extremely widespread in nature having diverse functions at both biochemical and physiological level. The genome of C. jejuni 81-176 encodes a single cytochrome P450 (Cj1411c) that has no close homologues. Cj1411c is unusual in its genomic location within a cluster involved in the biosynthesis of outer surface structures. Here we show that E. coli expressed and affinity-purified C. jejuni cytochrome P450 is lipophilic, containing one equivalent Cys-ligated heme. Immunoblotting confirmed the association of cytochrome P450 with membrane fractions. A Cj1411c deletion mutant had significantly reduced ability to infect human cells and was less able to survive following exposure to human serum when compared to the wild type strain. Phenotypically following staining with Alcian blue, we show that a Cj1411c deletion mutant produces significantly less capsular polysaccharide. This study describes the first known membrane-bound bacterial cytochrome P450 and its involvement in Campylobacter virulence.

Oxygen activation in neuronal NO synthase: resolving the consecutive mono-oxygenation steps.

The vital signalling molecule NO is produced by mammalian NOS (nitric oxide synthase) enzymes in two steps. L-arginine is converted into NOHA (Nω-hydroxy-L-arginine), which is converted into NO and citrulline. Both steps are thought to proceed via similar mechanisms in which the cofactor BH4 (tetrahydrobiopterin) activates dioxygen at the haem site by electron transfer. The subsequent events are poorly understood due to the lack of stable intermediates. By analogy with cytochrome P450, a haem-iron oxo species may be formed, or direct reaction between a haem-peroxy intermediate and substrate may occur. The two steps may also occur via different mechanisms. In the present paper we analyse the two reaction steps using the G586S mutant of nNOS (neuronal NOS), which introduces an additional hydrogen bond in the active site and provides an additional proton source. In the mutant enzyme, BH4 activates dioxygen as in the wild-type enzyme, but an interesting intermediate haem species is then observed. This may be a stabilized form of the active oxygenating species. The mutant is able to perform step 2 (reaction with NOHA), but not step 1 (with L-arginine) indicating that the extra hydrogen bond enables it to discriminate between the two mono-oxygenation steps. This implies that the two steps follow different chemical mechanisms.

An in situ electrochemical cell for Q- and W-band EPR spectroscopy.

A simple design for an in situ, three-electrode spectroelectrochemical cell is reported that can be used in commercial Q- and W-band (ca. 34 and 94 GHz, respectively) electron paramagnetic resonance (EPR) spectrometers, using standard sample tubing (1.0 and 0.5 mm inner diameter, respectively) and within variable temperature cryostat systems. The use of the cell is demonstrated by the in situ generation of organic free radicals (quinones and diimines) in fluid and frozen media, transition metal ion radical anions, and on the enzyme nitric oxide synthase reductase domain (NOSrd), in which a pair of flavin radicals are generated.

Cytochrome P450 BM3, NO binding and real-time NO detection.

Nitric oxide is known to coordinate to ferrous heme proteins very tightly, following which it is susceptible to reaction with molecular oxygen or free NO. Its coordination to ferric heme is generally weaker but the resultant complexes are more stable in the presence of oxygen. Here we report determination of the binding constants of Cytochrome P450 BM3 for nitric oxide in the ferric state in the presence and absence of substrate. Compared to other 5-coordinate heme proteins, the K(d) values are particularly low at 16 and 40 nM in the presence and absence of substrate respectively. This most likely reflects the high hydrophobicity of the active site of this enzyme. The binding of NO is tight enough to enable P450 BM3 oxygenase domain to be used to determine NO concentrations and in real-time NO detection assays, which would be particularly useful under conditions of low oxygen concentration, where current methods break down.

Conformation-dependent hydride transfer in neuronal nitric oxide synthase reductase domain.

Calmodulin (CaM) activates the constitutive isoforms of mammalian nitric oxide synthase by triggering electron transfer from the reductase domain FMN to the heme. This enables the enzymes to be regulated by Ca(2+) concentration. CaM exerts most of its effects on the reductase domain; these include activation of electron transfer to electron acceptors, and an increase in the apparent rate of flavin reduction by the substrate NADPH. It has been shown that the former is caused by a transition from a conformationally locked form of the enzyme to an open form as a result of CaM binding, improving FMN accessibility, but the latter effect has not been explained satisfactorily. Here, we report the effect of ionic strength and isotopic substitution on flavin reduction. We found a remarkable correlation between the rate of steady-state turnover of the reductase domain and the rate of flavin reduction over a range of different ionic strengths. The reduction of the enzyme by NADPH was biphasic, and the amplitudes of the phases determined through global analysis of stopped-flow data correlated with the proportions of enzyme known to exist in the open and closed conformations. The different conformations of the enzyme molecule appeared to have different rates of reaction with NADPH. Thus, proximity of FMN inhibits hydride transfer to the FAD. In the CaM-free enzyme, slow conformational motion (opening and closing) limits turnover. It is now clear that this motion also controls hydride transfer during steady-state turnover, by limiting the rate at which NADPH can access the FAD.

NO synthase: structures and mechanisms.

Production of NO from arginine and molecular oxygen is a complex chemical reaction unique to biology. Our understanding of the chemical and regulation mechanisms of the NO synthases has developed over the past two decades, uncovering some extraordinary features. This article reviews recent progress and highlights current issues and controversies. The structure of the enzyme has now been determined almost in entirety, although it is as a selection of fragments, which are difficult to assemble unambiguously. NO synthesis is driven by electron transfer through FAD and FMN cofactors, which is controlled by calmodulin binding in the constitutive mammalian enzymes. Many of the unique structural features involved have been characterised, but the mechanics of calmodulin-dependent activation are largely unresolved. Ultimately, NO is produced in the active site by the reaction of arginine with activated heme-bound oxygen in two distinct cycles. The unique role of the tetrahydrobiopterin cofactor as an electron donor in this process has now been established, but the subsequent chemical events are currently a matter of intense speculation and debate.

Steady-state and stopped-flow kinetic studies of three Escherichia coli NfsB mutants with enhanced activity for the prodrug CB1954.

The enzyme nitroreductase, NfsB, from Escherichia coli has entered clinical trials for cancer gene therapy with the prodrug CB1954 [5-(aziridin-1-yl)-2,4-dinitrobenzamide]. However, CB1954 is a poor substrate for the enzyme. Previously we made several NfsB mutants that show better activity with CB1954 in a cell-killing assay in E. coli. Here we compare the kinetic parameters of wild-type NfsB with CB1954 to those of the most active single, double, and triple mutants isolated to date. For wild-type NfsB the global kinetic parameters for both k(cat) and K(m) for CB1954 are about 20-fold higher than previously estimated; however, the measured specificity constant, k(cat)/K(m) is the same. All of the mutants are more active with CB1954 than the wild-type enzyme, the most active mutant showing about 100-fold improved specificity constant with CB1954 over the wild-type protein with little effect on k(cat). This enhancement in specificity constants for the mutants is not seen with the antibiotic nitrofurazone as substrate, leading to reversed nitroaromatic substrate selectivity for the double and triple mutants. However, similar enhancements in specificity constants are found with the quinone menadione. Stopped-flow kinetic studies suggest that the rate-determining step of the reaction is likely to be the release of products. The most active mutant is also selective for the 4-nitro group of CB1954, rather than the 2-nitro group, giving the more cytotoxic reduction product. The double and triple mutants should be much more effective enzymes for use with CB1954 in prodrug-activation gene therapy.

Importance of the domain-domain interface to the catalytic action of the NO synthase reductase domain.

Calmodulin (CaM) activates NO synthase (NOS) by binding to a 20 amino acid interdomain hinge in the presence of Ca (2+), inducing electrons to be transferred from the FAD to the heme of the enzyme via a mobile FMN domain. The activation process is influenced by a number of structural features, including an autoinhibitory loop, the C-terminal tail of the enzyme, and a number of phosphorylation sites. Crystallographic and other recent experimental data imply that the regulatory elements lie within the interface between the FAD- and FMN-binding domains, restricting the movement of the two cofactors with respect to each other. Arg1229 of rat neuronal NOS is a conserved residue in the FAD domain that forms one of only two electrostatic contacts between the domains. Mutation of this residue to Glu reverses its charge and is expected to induce an interdomain repulsion, allowing the importance of the interface and domain-domain motion to be probed. The charge-reversal mutation R1229E has three dramatic effects on catalysis: (i) hydride transfer from NADPH to FAD is activated in the CaM-free enzyme, (ii) FAD to FMN electron transfer is inhibited in both forms, and (iii) electron transfer from FMN to the surrogate acceptor cytochrome c is activated in the CaM-free enzyme. As a result, during steady-state turnover with cytochrome c, calmodulin now deactivates the enzyme and causes cytochrome c-dependent inhibition. Evidently, domain-domain separation is large enough in the mutant to accommodate another protein between the cofactors. The effects of this single charge reversal on three distinct catalytic events illustrate how each is differentially dependent on the enzyme conformation and support a model for catalytic motion in which steps i, ii, and iii occur in the hinged open, closed, and open states, respectively. This model is also likely to apply to related enzymes such as cytochrome P450 reductase.

6-Acetyl-7,7-dimethyl-5,6,7,8-tetrahydropterin is an activator of nitric oxide synthases.

6-Acetyl-7,7-dimethyl-7,8-dihydropterin 3 has been shown to be able to substitute for the natural cofactor of nitric oxide synthases, tetrahydrobiopterin 1, in cells and tissues that contain active nitric oxide synthases (NOSs). In both macrophages, which produce iNOS, and endothelial cells, which produce eNOS, in which tetrahydrobiopterin biosynthesis has been blocked by inhibition of GTP cyclohydrolase 1, dihydropterin 3 restored production of nitric oxide by these cells. In tissues, 3 caused relaxation in preconstricted rat aortic rings, again in which tetrahydrobiopterin biosynthesis had been inhibited, an effect that was blocked by the NOS inhibitor, L-NAME. However, dihydropterin 3 was not itself an active cofactor in purified NOS (nNOS) preparations free of tetrahydrobiopterin suggesting that intracellular reduction to 6-acetyl-7,7-dimethyl-5,6,7,8-tetrahydropterin 4 is required for activity. Compound 4 was prepared by reduction of the corresponding 7,8-dihydropterin with sodium cyanoborohydride and has been shown to be a competent cofactor for nitric oxide production by nNOS. Together, the results show that the 7,7-dimethyl-7,8-dihydropterin is a novel structural framework for effective tetrahydrobiopterin analogues.

The role of Thr268 and Phe393 in cytochrome P450 BM3.

In flavocytochrome P450 BM3 there are several active site residues that are highly conserved throughout the P450 superfamily. Of these, a phenylalanine (Phe393) has been shown to modulate heme reduction potential through interactions with the implicitly conserved heme-ligand cysteine. In addition, a distal threonine (Thr268) has been implicated in a variety of roles including proton donation, oxygen activation and substrate recognition. Substrate binding in P450 BM3 causes a shift in the spin state from low- to high-spin. This change in spin-state is accompanied by a positive shift in the reduction potential (DeltaE(m) [WT+arachidonate (120 microM)]=+138 mV). Substitution of Thr268 by an alanine or asparagine residue causes a significant decrease in the ability of the enzyme to generate the high-spin complex via substrate binding and consequently leads to a decrease in the substrate-induced potential shift (DeltaE(m) [T268A+arachidonate (120 microM)]=+73 mV, DeltaE(m) [T268N+arachidonate (120 microM)]=+9 mV). Rate constants for the first electron transfer and for oxy-ferrous decay were measured by pre-steady-state stopped-flow kinetics and found to be almost entirely dependant on the heme reduction potential. More positive reduction potentials lead to enhanced rate constants for heme reduction and more stable oxy-ferrous species. In addition, substitutions of the threonine lead to an increase in the production of hydrogen peroxide in preference to hydroxylated product. These results suggest an important role for this active site threonine in substrate recognition and in maintaining an efficiently functioning enzyme. However, the dependence of the rate constants for oxy-ferrous decay on reduction potential raises some questions as to the importance of Thr268 in iron-oxo stabilisation.

The formation of a complex between calmodulin and neuronal nitric oxide synthase is determined by ESI-MS.

Calmodulin (CaM) is an acidic ubiquitous calcium binding protein, involved in many intracellular processes, which often involve the formation of complexes with a variety of protein and peptide targets. One such system, activated by Ca2+ loaded CaM, is regulation of the nitric oxide synthase (NOS) enzymes, which in turn control the production of the signalling molecule and cytotoxin NO. A recent crystallographic study mapped the interaction of CaM with endothelial NOS (eNOS) using a 20 residue peptide comprising the binding site within eNOS. Here the interaction of CaM to the FMN domain of neuronal nitric oxide synthase (nNOS) has been investigated using electrospray ionization mass spectrometry (ESI-MS). The 46 kDa complex formed by CaM-nNOS has been retained in the gas-phase, and is shown to be exclusively selective for CaM.4Ca2+. Further characterization of this important biological system has been afforded by examining a complex of CaM with a 22 residue synthetic peptide, which represents the linker region between the reductase and oxygenase domains of nNOS. This nNOS linker peptide, which is found to be random coil in aqueous solution by both circular dichroism and molecular modelling, also exhibits great discrimination for the form of CaM loaded with 4[Ca2+]. The peptide binding loop is presumed to be configured to an alpha-helix on binding to CaM as was found for the related eNOS binding peptide. Our postulate is supported by gas-phase molecular dynamics calculations performed on the isolated nNOS peptide. Collision induced dissociation was employed to probe the strength of binding of the nNOS binding peptide to CaM.4Ca2+. The methodology taken here is a new approach in understanding the CaM-nNOS binding site, which could be employed in future to inform the specificity of CaM binding to other NOS enzymes.

Thermodynamic and kinetic analysis of the nitrosyl, carbonyl, and dioxy heme complexes of neuronal nitric-oxide synthase. The roles of substrate and tetrahydrobiopterin in oxygen activation.

Mammalian NO synthases catalyze the monooxygenation of L-arginine (L-Arg) to N-hydroxyarginine (NOHA) and the subsequent monooxygenation of this to NO and citrulline. Both steps proceed via formation of an oxyferrous heme complex and may ultimately lead to a ferrous NO complex, from which NO must be released. Electrochemical reduction of NO-bound neuronal nitricoxide synthase (nNOS) oxygenase domain was used to form the ferrous heme NO complex, which was found to be stable only in the presence of low NO concentrations, due to catalytic degradation of NO at the nNOS heme site. The reduction potential for the heme-NO complex was approximately -140 mV, which shifted to 0 mV in the presence of either L-Arg or NOHA. This indicates that the complex is stabilized by 14 kJ mol(-1) in the presence of substrate, consistent with a strong H-bonding interaction between NO and the guanidino group. Neither substrate influenced the reduction potential of the ferrous heme CO complex, however. Both L-Arg and NOHA appear to interact with bound NO in a similar way, indicating that both bind as guanidinium ions. The dissociation constant for NO bound to ferrous heme in the presence of l-Arg was determined electrochemically to be 0.17 nM, and the rate of dissociation was estimated to be 10(-4) s(-1), which is much slower than the rate of catalysis. Stopped-flow kinetic analysis of oxyferrous formation and decay showed that both l-Arg and NOHA also stabilize the ferrous heme dioxy complex, resulting in a 100-fold decrease in its rate of decay. Electron transfer from the active-site cofactor tetrahydrobiopterin (H4B) has been proposed to trigger the monoxygenation process. Consistent with this, substitution by the analogue/inhibitor 4-amino-H4B stabilized the oxyferrous complex by a further two orders of magnitude. H4B is required, therefore, to break down both the oxyferrousand ferrous nitrosyl complexes of nNOS during catalysis. The energetics of these processes necessitates an electron donor/acceptor operating within a specific reduction potential range, defining the role of H4B.

The unusual redox properties of flavocytochrome P450 BM3 flavodoxin domain.

Flavocytochrome P450 BM3 FMN domain is unique among the family of flavodoxins and homologues, in not forming a stable neutral blue FMN semiquinone radical. Anaerobic, one-electron reduction of the isolated domain over the pH 7-9.5 range showed that it forms an anionic red semiquinone that disproportionates slowly (0.014s(-1) at pH 7). The rate of disproportionation decreased at higher pH, indicating that protonation of the anionic semiquinone is an important feature of the mechanism. The reduction potential for the oxidised-semiquinone couple was determined to be -240mV and was largely independent of pH. The semiquinone appears, therefore, to be kinetically trapped by a slow protonation event, enabling it to act as a low-potential electron donor to the P450 heme.

4-cyanopyridine, a versatile spectroscopic probe for cytochrome P450 BM3.

The nitrogenous pi -acceptor ligand 4-cyanopyridine (4CNPy) exhibits reversible ligation to ferrous heme in the flavocytochrome P450 BM3 (Kd=1.8 microm for wild type P450 BM3) via its pyridine ring nitrogen. The reduced P450-4CNPy adduct displays unusual spectral properties that provide a useful spectroscopic handle to probe particular aspects of this P450. 4CNPy is competitively displaced upon substrate binding, allowing a convenient route to the determination of substrate dissociation constants for ferrous P450 highlighting an increase in P450 substrate affinity on heme reduction. For wild type P450 BM3, Kd(red)(laurate)=82.4 microm (cf. Kd(ox)=364 microm). In addition, an unusual spectral feature in the red region of the absorption spectrum of the reduced P450-4CNPy adduct is observed that can be assigned as a metal-to-ligand charge transfer (MLCT). It was discovered that the energy of this MLCT varies linearly with respect to the P450 heme reduction potential. By studying the energy of this MLCT for a series of BM3 active site mutants with differing reduction potential (Em), the relationship EMLCT + (3.53 x = Em 17,005 cm)(-1) was derived. The use of this ligand thus provides a quick and accurate method for predicting the heme reduction potentials of a series of P450 BM3 mutations using visible spectroscopy, without the requirement for redox potentiometry.

Redox properties of the isolated flavin mononucleotide- and flavin adenine dinucleotide-binding domains of neuronal nitric oxide synthase.

Electron transfer through neuronal nitric oxide synthase (nNOS) is regulated by the reversible binding of calmodulin (CaM) to the reductase domain of the enzyme, the conformation of which has been shown to be dependent on the presence of substrate, NADPH. Here we report the preparation of the isolated flavin mononucleotide (FMN)-binding domain of nNOS with bound CaM and the electrochemical analysis of this and the isolated flavin adenine dinucleotide (FAD)-binding domain in the presence and absence of NADP(+) and ADP (an inhibitor). The FMN-binding domain was found to be stable only in the presence of bound CaM/Ca(2+), removal of which resulted in precipitation of the protein. The FMN formed a kinetically stabilized blue semiquinone with an oxidized/semiquinone reduction potential of -179 mV. This is 80 mV more negative than the potential of the FMN in the isolated reductase domain, that is, in the presence of the FAD-binding domain. The FMN semiquinone/hydroquinone redox couple was found to be similar in both constructs. The isolated FAD-binding domain, generated by controlled proteolysis of the reductase domain, was found to have similar FAD reduction potentials to the isolated reductase domain. Both formed a FAD-hydroquinone/NADP(+) charge-transfer complex with a long-wavelength absorption band centered at 780 nm. Formation of this complex resulted in thermodynamic destabilization of the FAD semiquinone relative to the hydroquinone and a 30 mV increase in the FAD semiquinone/hydroquinone reduction potential. Binding of ADP, however, had little effect. The possible role of the nicotinamide/FADH(2) stacking interaction in controlling electron transfer and its likely dependence on protein conformation are discussed.

An appraisal of multiple NADPH binding-site models proposed for cytochrome P450 reductase, NO synthase, and related diflavin reductase systems.

The diflavin reductases exemplified by mammalian cytochrome P450 reductase catalyze NADPH dehydrogenation and electron transfer to an associated monooxygenase. It has recently been proposed that double occupancy of the NADPH dehydrogenation site inhibits the NADPH to FAD hydride transfer step in this series of enzymes. This has important implications for the mechanism of enzyme turnover. However, the conclusions are drawn from a series of pre-steady-state stopped-flow experiments in which the data analysis and interpretation are flawed. Recent data published for P450-BM3 reductase show a decrease in the rate constant for pre-steady-state flavin oxidation with increasing NADP(+) concentration. This is interpreted as evidence of inhibition by multiple substrate binding. A detailed reanalysis shows that the data are in fact consistent with a simple single-binding-site model in which reversible hydride transfer causes the observed effect. Data for the related systems are also discussed.

Oxygen activation and electron transfer in flavocytochrome P450 BM3.

In flavocytochrome P450 BM3, there is a conserved phenylalanine residue at position 393 (Phe393), close to Cys400, the thiolate ligand to the heme. Substitution of Phe393 by Ala, His, Tyr, and Trp has allowed us to modulate the reduction potential of the heme, while retaining the structural integrity of the enzyme's active site. Substrate binding triggers electron transfer in P450 BM3 by inducing a shift from a low- to high-spin ferric heme and a 140 mV increase in the heme reduction potential. Kinetic analysis of the mutants indicated that the spin-state shift alone accelerates the rate of heme reduction (the rate determining step for overall catalysis) by 200-fold and that the concomitant shift in reduction potential is only responsible for a modest 2-fold rate enhancement. The second step in the P450 catalytic cycle involves binding of dioxygen to the ferrous heme. The stabilities of the oxy-ferrous complexes in the mutant enzymes were also analyzed using stopped-flow kinetics. These were found to be surprisingly stable, decaying to superoxide and ferric heme at rates of 0.01-0.5 s(-)(1). The stability of the oxy-ferrous complexes was greater for mutants with higher reduction potentials, which had lower catalytic turnover rates but faster heme reduction rates. The catalytic rate-determining step of these enzymes can no longer be the initial heme reduction event but is likely to be either reduction of the stabilized oxy-ferrous complex, i.e., the second flavin to heme electron transfer or a subsequent protonation event. Modulating the reduction potential of P450 BM3 appears to tune the two steps in opposite directions; the potential of the wild-type enzyme appears to be optimized to maximize the overall rate of turnover. The dependence of the visible absorption spectrum of the oxy-ferrous complex on the heme reduction potential is also discussed.

Potentiometric analysis of UDP-galactopyranose mutase: stabilization of the flavosemiquinone by substrate.

UDP-galactopyranose mutase is a flavoprotein which catalyses the interconversion of UDP-galactopyranose and UDP-galactofuranose. The enzyme is of interest because it provides the activated biosynthetic precursor of galactofuranose, a key cell wall component of many bacterial pathogens. The reaction mechanism of this mutase is intriguing because the anomeric oxygen forms a glycosidic bond, which means that the reaction must proceed by a novel mechanism involving ring breakage and closure. The structure of the enzyme is known, but the mechanism, although speculated on, is not resolved. The overall reaction is electrically neutral but a crypto-redox reaction is suggested by the requirement that the flavin must adopt the reduced form for activity. Herein we report a thermodynamic analysis of the enzyme's flavin cofactor with the objective of defining the system and setting parameters for possible reaction schemes. The analysis shows that the neutral semiquinone (FADH(*)) is stabilized in the presence of substrate and the fully reduced flavin is the anionic FADH(-) rather than the neutral FADH(2). The anionic FADH(-) has the potential to act as a rapid 1-electron donor/acceptor without being slowed by a coupled proton transfer and is therefore an ideal crypto-redox cofactor.

P450 BM3: the very model of a modern flavocytochrome.

Flavocytochrome P450 BM3 is a bacterial P450 system in which a fatty acid hydroxylase P450 is fused to a mammalian-like diflavin NADPH-P450 reductase in a single polypeptide. The enzyme is soluble (unlike mammalian P450 redox systems) and its fusion arrangement affords it the highest catalytic activity of any P450 mono-oxygenase. This article discusses the fundamental properties of P450 BM3 and how progress with this model P450 has affected our comprehension of P450 systems in general.