The critical iron-oxygen intermediate in human aromatase

Aromatase (CYP19) is the target of several therapeutics used for breast cancer treatment and catalyzes the three-step conversion of androgens to estrogens, with an unusual C-C cleavage reaction in the third step. To better understand the CYP19 reaction, the oxy-ferrous complex of CYP19 with androstenedione substrate was cryotrapped, characterized by UV-vis spectroscopy, and cryoreduced to generate the next reaction cycle intermediate. EPR analysis revealed that the initial intermediate observed following cryoreduction is the unprotonated g₁ = 2.254 peroxo-ferric intermediate, which is stable up to 180 K. Upon gradual cryoannealing, the low-spin (g₁ = 2.39) product complex is formed, with no evidence for accumulation of the g₁ = 2.30 hydroperoxo-ferric intermediate. The relative stabilization of the peroxo-ferric heme and the lack of observed hydroperoxo-ferric heme distinguish CYP19 from other P450s, suggesting that the proton delivery pathway is more hindered in CYP19 than in most other P450s.     

Cryogenic absorption spectra of hydroperoxo-ferric heme oxygenase,the active intermediate of enzymatic heme oxygenation

Using radiolysis with (32)P enriched phosphate as an internal source of ionizing radiation, the formation of hydroperoxo-ferric complex from oxy-ferrous precursor with a high yield was monitored at 77 K in heme oxygenase (HO) by means of optical absorption spectroscopy. Well-resolved absorption spectra (maxima at 421 nm, 530 nm, 557 nm) of hydroperoxo-ferric intermediate of this heme enzyme were measured in 70% glycerol/buffer frozen glasses. After annealing at 210-215 K this complex converts to the product complex, alpha-meso hydroxyheme-HO. No heme degradation products were formed in control experiments with ferric HO or other heme proteins.     

Modification of the heme active site to increase the peroxidase activity of thermophilic cytochrome P450: A rational approach

The site specific mutants of the thermophilic P450 (P450 175A1 or CYP175A1) were designed to introduce residues that could act as acid-base catalysts near the active site to enhance the peroxidases activity. The Leu80 in the distal heme pocket of CYP175A1 was located at a position almost equivalent to the Glu183 that is involved in stabilization of the ferryl heme intermediate in chloroperoxidase (CPO). The Leu80 residue of CYP175A1 was mutated with histidine (L80H) and glutamine (L80Q) that could potentially form hydrogen bond with hydrogen peroxide and facilitate formation and stabilization of the putative redox intermediate of the peroxidase cycle. The mutants L80H and L80Q of CYP175A1 showed higher peroxidase activity compared to that of the wild type (WT) CYP175A1 enzyme at 25 °C. The activity constants (k_cat) for the L80H and L80Q mutants of CYP175A1 were higher than those of myoglobin and wild type cytochrome b562 at 25 °C. The optimum temperature for the peroxidase activity of the WT and mutants of CYP175A1 was ~ 70 °C. The rate of catalysis at temperatures above ~ 70 °C was higher for L80Q mutant of CYP175A1 compared to that of the well known natural peroxidase, horseradish peroxidase (HRP) that denatures at such high temperature. The peroxidase activities of the mutants of CYP175A1 were maximum at pH 9, unlike that of HRP which is at pH ~ 5. The results have been discussed in the light of understanding the structure-function relationship of the peroxidase properties of these thermostable heme proteins.     

Spectroscopic characterization of cytochrome P450 Compound I

The cytochrome P450 protein-bound porphyrin complex with the iron-coordinated active oxygen atom as Fe(IV)O is called Compound I (Cpd I). Cpd I is the intermediate species proposed to hydroxylate directly the inert carbon–hydrogen bonds of P450 substrates. In the natural reaction cycle of cytochrome P450 Cpd I has not yet been detected, presumably because it is very short-lived. A great variety of experimental approaches has been applied to produce Cpd I artificially aiming to characterize its electronic structure with spectroscopic techniques. In spite of these attempts, none of the spectroscopic studies of the last decades proved capable of univocally identifying the electronic state of P450 Cpd I. Very recently, however, Rittle and Green [9] have shown that Cpd I of CYP119, the thermophillic P450 from Sulfolobus acidocaldarius, is univocally a Fe(IV)O–porphyrin radical with the ferryl iron spin (S = 1) antiferromagnetically coupled to the porphyrin radical spin (S′ = 1/2) yielding a S_tot = 1/2 ground state very similar to Cpd I of chloroperoxidase from Caldariomyces fumago. In this mini-review the efforts to characterize Cpd I of cytochrome P450 by spectroscopic methods are summarized.     

A novel intermediate in the reaction of seleno CYP119 with m-chloroperbenzoic acid

Cytochrome P450-mediated monooxygenation generally proceeds via a reactive ferryl intermediate coupled to a ligand radical [Fe(IV)═O]+? termed Compound I (Cpd I). The proximal cysteine thiolate ligand is a critical determinant of the spectral and catalytic properties of P450 enzymes. To explore the effect of an increased level of donation of electrons by the proximal ligand in the P450 catalytic cycle, we recently reported successful incorporation of SeCys into the active site of CYP119, a thermophilic cytochrome P450. Here we report relevant physical properties of SeCYP119 and a detailed analysis of the reaction of SeCYP119 with m-chloroperbenzoic acid. Our results indicate that the selenolate anion reduces rather than stabilizes Cpd I and also protects the heme from oxidative destruction, leading to the generation of a new stable species with an absorbance maximum at 406 nm. This stable intermediate can be returned to the normal ferric state by reducing agents and thiols, in agreement with oxidative modification of the selenolate ligand itself. Thus, in the seleno protein, the oxidative damage shifts from the heme to the proximal ligand, presumably because (a) an increased level of donation of electrons more efficiently quenches reactive species such as Cpd I and (b) the protection of the thiolate ligand provided by the protein active site structure is insufficient to shield the more oxidizable selenolate ligand.     

Low temperature photo-oxidation of chloroperoxidase Compound II

Oxidation of the heme-thiolate enzyme chloroperoxidase (CPO) from Caldariomyces fumago with peroxynitrite (PN) gave the Compound II intermediate, which was photo-oxidized with 365 nm light to give a reactive oxidizing species. Cryo-solvents at pH ≈ 6 were employed, and reactions were conducted at temperatures as low as − 50 °C. The activity of CPO as evaluated by the chlorodimedone assay was unaltered by treatment with PN or by production of the oxidizing transient and subsequent reaction with styrene. EPR spectra at 77 K gave the amount of ferric protein at each stage in the reaction sequence. The PN oxidation step gave a 6:1 mixture of Compound II and ferric CPO, the photolysis step gave an approximate 1:1 mixture of active oxidant and ferric CPO, and the final mixture after reaction with excess styrene contained ferric CPO in 80% yield. In single turnover reactions at − 50 °C, styrene was oxidized to styrene oxide in high yield. Kinetic studies of styrene oxidation at − 50 °C displayed saturation kinetics with an equilibrium constant for formation of the complex of K_bind = 3.8 × 10⁴ M^− 1 and an oxidation rate constant of k_ox = 0.30 s^− 1. UV-Visible spectra of mixtures formed in the photo-oxidation sequence at ca. − 50 °C did not contain the signature Q-band absorbance at 690 nm ascribed to CPO Compound I prepared by chemical oxidation of the enzyme, indicating that different species were formed in the chemical oxidation and the photo-oxidation sequence.     

Low frequency spectral density of ferrous heme: perturbations induced by axial ligation and protein insertion

Femtosecond coherence spectroscopy is used to probe low frequency (20-400 cm⁻¹) modes of the ferrous heme group in solution, with and without 2-methyl imidazole (2MeIm) as an axial ligand. The results are compared to heme proteins (CPO, P450_cam, HRP, Mb) where insertion of the heme into the protein results in redistribution of the low frequency spectral density and in (∼60%) longer damping times for the coherent signals. The major effect of imidazole ligation to the ferrous heme is the “softening” of the low frequency force constants by a factor of ∼0.6 ± 0.1. The functional consequences of imidazole ligation are assessed and it is found that the enthalpic CO rebinding barrier is increased significantly when imidazole is bound. The force constant softening analysis, combined with the kinetics results, indicates that the iron is displaced by only ∼0.2 Å from the heme plane in the absence of the imidazole ligand, whereas it is displaced by ∼0.4 Å when imidazole (histidine) is present. This suggests that binding of imidazole (histidine) as an axial ligand, and the concomitant softening of the force constants, leads to an anharmonic distortion of the heme group that has significant functional consequences.     

The ferrous–dioxy complex of Leishmania major globin coupled heme containing adenylate cyclase: The role of proximal histidine on its stability

Recently we have described the globin-coupled heme containing adenylate cyclase from Leishmania major (HemAC-Lm) that shows an O₂ dependent cAMP signaling (Sen Santara, et. al. Proc. Natl. Acad. Sci. U.S.A. 110, 16790–16795 (2013)). The heme iron of HemAC-Lm is expected to participate in oxygen binding and activates adenylate cyclase activity during catalysis, but its interactions with O₂ are uncharacterized. We have utilized the HemAC-Lm and stopped-flow methods to study the formation and decay of the HemAC-Lm oxygenated complex at 25 °C. Mixing of the ferrous HemAC-Lm with air-saturated buffer generates a very stable oxygenated complex with absorption maxima at 414, 540 and 576 nm. The distal axial ligand in the deoxygenated ferrous HemAC-Lm is displaced by O₂ at a rate of ~ 10 s^− 1. To prepare apoprotein of heme iron in HemAC-Lm, we have mutated the proximal His161 to Ala and characterized the mutant protein. The apo as well as heme reconstituted ferric state of the mutant protein shows a ~ 30 fold lower catalytic activity compared to oxygenated form of wild type protein. The oxygenated form of heme reconstituted mutant protein is highly unstable (decay rate = 6.1 s^− 1). Decomposition of the oxygenated intermediate is independent of O₂ concentration and is monophasic. Thus, the stabilization of ferrous-oxy species is an essential requirement in the wild type HemAC-Lm for a conformational alteration in the sensor domain that, sequentially, activates the adenylate cyclase domain, resulting in the synthesis of cAMP.     

Formation and decay of hydroperoxo-ferric heme complex in horseradish peroxidase studied by cryoradiolysis

Using radiolytic reduction of the oxy-ferrous horseradish peroxidase (HRP) at 77 K, we observed the formation and decay of the putative intermediate, the hydroperoxo-ferric heme complex, often called "Compound 0." This intermediate is common for several different enzyme systems as the precursor of the Compound I (ferryl-oxo pi-cation radical) intermediate. EPR and UV-visible absorption spectra show that protonation of the primary intermediate of radiolytic reduction, the peroxo-ferric complex, to form the hydroperoxo-ferric complex is completed only after annealing at temperatures 150-180 K. After further annealing at 195-205 K, this complex directly transforms to ferric HRP without any observable intervening species. The lack of Compound I formation is explained by inability of the enzyme to deliver the second proton to the distal oxygen atom of hydroperoxide ligand, shown to be necessary for dioxygen bond heterolysis on the "oxidase pathway," which is non-physiological for HRP. Alternatively, the physiological substrate H2O2 brings both protons to the active site of HRP, and Compound I is subsequently formed via rearrangement of the proton from the proximal to the distal oxygen atom of the bound peroxide.     

Selective oxygen transfer catalysed by heme peroxidases: synthetic and mechanistic aspects

The synthetic and mechanistic aspects of the use of heme peroxidases as functional mimics of the cytochrome P450 monooxygenases in oxygen-transfer reactions have been described. The chloroperoxidase from Caldariomyces fumago (CPO) is the catalyst of choice in sulfoxidation, hydroxylation and epoxidation on account of its high activity and enantioselectivity. Other heme peroxidases were less active by orders of magnitude; protein engineering has resulted in impressive improvements but even the most active mutant was still at least an order of magnitude less active than CPO. The 'oxygen-rebound' mechanisms of oxygen transfer mediated by heme enzymes - as originally conceived - have proved to be untenable. Dual pathway mechanisms, via oxoferryl species that insert oxygen as well as iron hydroperoxide species that insert OH(+), have been proposed that accommodate all of the known experimental data.     

Replacement of tyrosine residues by phenylalanine in cytochrome P450cam alters the formation of Cpd II-like species in reactions with artificial oxidants

Our previous rapid-scanning stopped-flow studies of the reaction of substrate-free cytochrome P450cam with peracids [Spolitak et al. (2005) J Biol Chem 280:20300-20309; (2006) J Inorg Biochem 100:2034-2044] spectrally characterized compound I [ferryl iron plus a porphyrin pi-cation radical (Fe(IV) = O/Por(+))], as well as Cpd ES (Fe(IV) = O/Tyr.). In the present studies, we report how the substitutions in Y75F, Y96F, and Y96F/Y75F P450cam variants permit the formation of a species we attribute to Cpd II (Fe(IV) = O) in reactions with peracids and cumene hydroperoxide. These variants produce changes in hydrogen bonding patterns and increased hydrophobicity that affect the ratio of heterolytic to homolytic pathways in reactions with cumene hydroperoxide, resulting in a shift of this ratio from 84/16 for WT to 72/28 for the Y96F/Y75F double mutant. Various ways of generating the Cpd II-like species were explored, and it was possible, especially with the more hydrophobic variants, to generate large fractions of the P450cam variants as Cpd II. The Cpd II-like species is ineffective at hydroxylating camphor, but can be readily reduced by ascorbate (as well as other peroxidase substrates) to ferric P450cam, which could then bind camphor to form the high-spin heme. The difference in the spectral properties of Cpd ES and Cpd II was rationalized as possibly being due to different states of protonation.     

Cytochrome P450cin (CYP176A1) D241N: Investigating the role of the conserved acid in the active site of cytochrome P450s

P450_cin (CYP176A) is a rare bacterial P450 in that contains an asparagine (Asn242) instead of the conserved threonine that almost all other P450s possess that directs oxygen activation by the heme prosthetic group. However, P450_cin does have the neighbouring, conserved acid (Asp241) that is thought to be involved indirectly in the protonation of the dioxygen and affect the lifetime of the ferric-peroxo species produced during oxygen activation. In this study, the P450_cin D241N mutant has been produced and found to be analogous to the P450_cam D251N mutant. P450_cin catalyses the hydroxylation of cineole to give only (1R)-6β-hydroxycineole and is well coupled (NADPH consumed: product produced). The P450_cin D241N mutant also hydroxylated cineole to produce only (1R)-6β-hydroxycineole, was moderately well coupled (31 ± 3%) but a significant reduction in the rate of the reaction (2% as compared to wild type) was observed. Catalytic oxidation of a variety of substrates by D241N P450_cin were used to examine if typical reactions ascribed to the ferric-peroxo species increased as this intermediate is known to be more persistent in the P450_cam D251N mutant. However, little change was observed in the product profiles of each of these substrates between wild type and mutant enzymes and no products consistent with chemistry of the ferric-peroxo species were observed to increase.     

Modulation of redox potential and alteration in reactivity via the peroxide shunt pathway by mutation of cytochrome P450 around the proximal heme ligand

In the thermophilic cytochrome P450 from the thermoacidophilic crenarchaeon Sulfolobus tokodaii strain 7 (P450st), a phenylalanine residue at position 310 and an alanine residue at position 320 are located close to the heme thiolate ligand, Cys317. Single site-directed mutants F310A and A320Q and double mutant F310A/A320Q have been constructed. All mutant enzymes as well as wild-type (WT) P450st were expressed at high levels. The substitution of F310 with Ala and of A320 with Gln induced shifts in redox potential and blue shifts in Soret absorption of ferrous-CO forms, while spectral characterization showed that in the resting state, the mutants almost retained the structural integrity of the active site. The redox potential of the heme varied as follows: -481 mV (WT), -477 mV (A320Q), -453 mV (F310A), and -450 mV (F310A/A320Q). The trend in the Soret band of the ferrous-CO form was as follows: 450 nm (WT) < 449 nm (A320Q) < 446 nm (F310A) < 444 nm (F310A/A320Q). These results established that the reduction potential and electron density on the heme iron are modulated by the Phe310 and Ala320 residues in P450st. The electron density on the heme decreases in the following order: WT > A320Q > F310A > F310A/A320Q. The electron density on the heme iron infers an essential role in P450 activity. The decrease in electron density interferes with the formation of a high-valent oxo-ferryl species called Compound I. However, steady-state turnover rates of styrene epoxidation with H2O2 show the following trend: WT approximately equal to A320Q < F310A approximately equal to F310A/A320Q. The shunt pathway which can provide the two electrons and oxygen required for a P450 reaction instead of NAD(P)H and dioxygen can rule out the first and second heme reduction in the catalytic process. Because the electron density on the heme iron might be deeply involved in the k cat values in this system, the intermediate Compound 0 which is the precursor species of Compound I mainly appears to participate dominantly in epoxidation with H2O2.     

Reaction of ferric cytochrome P450cam with peracids: kinetic characterization of intermediates on the reaction pathway

Reactions of substrate-free ferric cytochrome P450cam with peracids to generate Fe=O intermediates have previously been investigated with contradictory results. Using stopped-flow spectrophotometry, the reaction with m-chloroperoxybenzoic acid demonstrated an Fe(IV)=O + porphyrin pi-cation radical (Cpd I) (Egawa, T., Shimada, H., and Ishimura, Y. (1994) Biochem. Biophys. Res. Commun. 201, 1464-1469). By contrast, with peracetic acid, Fe(IV)=O plus a tyrosyl radical were observed by freeze-quench Mossbauer and EPR spectroscopy (Schunemann, V., Jung, C., Trautwein, A. X., Mandon, D., and Weiss, R. (2000) FEBS Lett. 479, 149-154). Our detailed kinetic studies have resolved these contradictory results. At pH >7, a significant fraction of Cpd I is formed transiently, whereas at low pH only a species with a Soret band at 406 nm, presumably Fe(IV)=O + tyrosyl radical, is observed. Evidence for formation of an acylperoxo complex en route to Cpd I was obtained. Because of rapid heme destruction, steps subsequent to formation of the highly oxidized forms could not be fully characterized. Heme destruction was avoided by including peroxidase substrates (e.g. guaiacol), which were oxidized to characteristic peroxidase products as the Fe(III)-P450 was regenerated. Addition of ascorbate to either of the high valent species also reforms the Fe(III) state with only a small loss of heme absorbance. These results indicate that typical peroxidase chemistry occurs with P450cam and offer an explanation for the contrasting results reported earlier. The delineation of improved conditions (pH, temperature, choice of peracid) for generating highly oxidized species with P450cam should be valuable for their further characterization.     

Resonance Raman detection of the Fe-S bond in endothelial nitric oxide synthase

We report the first low-frequency resonance Raman spectra of ferric endothelial nitric oxide synthase (eNOS) holoenzyme, including the frequency of the Fe-S vibration in the presence of the substrate L-arginine. This is the first direct measurement of the strength of the Fe-S bond in NOS. The Fe-S vibration is observed at 338 cm(-1) with excitation at 363.8 nm. The assignment of this band to the Fe-S stretching vibration was confirmed by the observation of isotopic shifts in eNOS reconstituted with 54Fe- and 57Fe-labeled hemin. Furthermore, the frequency of this vibration is close to those observed in cytochrome P450(cam) and chloroperoxidase (CPO). The frequency of this vibration is lower in eNOS than in P450(cam) and CPO, which can be explained by differences in hydrogen bonding to the proximal cysteine heme ligand. On addition of substrate to eNOS, we also observe several low-frequency vibrations, which are associated with the heme pyrrole groups. The enhancement of these vibrations suggests that substrate binding results in protein-mediated changes of the heme geometry, which may provide the protein with an additional tuning element for the redox potential of the heme iron. The implications of our findings for the function of eNOS will be discussed by comparison with P450(cam) and model compounds.     

Molecular basis for the inability of an oxygen atom donor ligand to replace the natural sulfur donor heme axial ligand in cytochrome P450 catalysis. Spectroscopic characterization of the Cys436Ser CYP2B4 mutant

All cytochrome P450s (CYPs) contain a cysteinate heme iron proximal ligand that plays a crucial role in their mechanism of action. Conversion of the proximal Cys436 to Ser in NH₂-truncated microsomal CYP2B4 (ΔCYP2B4) transforms the enzyme into a two-electron NADPH oxidase producing H₂O₂ without monooxygenase activity [K.P. Vatsis, H.M. Peng, M.J. Coon, J. Inorg. Biochem. 91 (2002) 542–553]. To examine the effects of this ligation change on the heme iron spin-state and coordination structure of ΔC436S CYP2B4, the magnetic circular dichroism and electronic absorption spectra of several oxidation/ligation states of the variant have been measured and compared with those of structurally defined heme complexes. The spectra of the substrate-free ferric mutant are indicative of a high-spin five-coordinate structure ligated by anionic serinate. The spectroscopic properties of the dithionite-reduced (deoxyferrous) protein are those of a five-coordinate (high-spin) state, and it is concluded that the proximal ligand has been protonated to yield neutral serine (ROH-donor). Low-spin six-coordinate ferrous complexes of the mutant with neutral sixth ligands (NO, CO, and O₂) examined are also likely ligated by neutral serine, as would be expected for ferric complexes with anionic sixth ligands such as the hydroperoxo-ferric catalytic intermediate. Ligation of the heme iron by neutral serine vs. deprotonated cysteine is likely the result of the large difference in their acidity. Thus, without the necessary proximal ligand push of the cysteinate, although the ΔC436S mutant can accept two electrons and two protons, it is unable to heterolytically cleave the O–O bond of the hydroperoxo-ferric species to generate Compound I and hydroxylate the substrate.     

Characterization of the microsomal cytochrome P450 2B4 O2 activation intermediates by cryoreduction and electron paramagnetic resonance

The oxy-ferrous complex of cytochrome P450 2B4 (2B4) has been prepared at -40 degrees C with and without bound substrate [butylated hydroxytoluene (BHT)] and radiolytically one-electron cryoreduced at 77 K. Electron paramagnetic resonance (EPR) shows that in both cases the observed product of cryoreduction is the hydroperoxo-ferriheme species, indicating that the microsomal P450 contains an efficient distal-pocket proton-delivery network. In the absence of substrate, two distinct hydroperoxo-ferriheme signals are observed, reflecting the presence of two major conformational substates in the oxy-ferrous precursor. Only one species is observed when BHT is bound, indicating a more ordered active site. BHT binding also changes the g-tensor components of the hydroperoxo-ferric 2B4 intermediate, indicating that the substrate modulates the properties of this intermediate. Step annealing the cryoreduced ternary 2B4 complex at >or=175 K causes the loss of hydroperoxo-ferric 2B4 and the parallel appearance of high-spin ferric 2B4; liquid chromatography-tandem mass spectroscopy (LC-MS/MS) analysis shows that in this process BHT is quantitatively converted to two products, hydroxymethyl BHT (1) and 3-hydroxy- tert-butyl BHT (2). This implies that the hydroperoxo-ferric 2B4 prepared by cryoreduction is catalytically active and that the high-spin state observed after annealing contains an enzyme-bound product of BHT monooxygenation. The ratio of products generated during cryoreduction and annealing (6.2/1) is significantly different from the ratio (2.5/1) at ambient temperature. These findings suggest that substrate is held more rigidly relative to the oxidizing species at low temperatures and/or that dissociation of FeOOH is inhibited at low temperature. As in experiments under ambient conditions, product formation is not observed with the inactive F429H 2B4 mutant.     

Characterization of the oxygenated intermediate of the thermophilic cytochrome P450 CYP119.

Using UV-Vis, resonance Raman, and EPR spectroscopy we have studied the properties of the oxygenated ferrous cytochrome P450 from Sulfolobus solfataricus, (CYP119). The recently determined crystal structure of CYP119 is compared with other available structures of P450s, and detailed structural and spectroscopic analyses are reported. With several structural similarities to CYP102, such as in-plane iron position and a shorter iron-proximal ligand bond, CYP119 shows low-spin conformation preference in the ferric form and partially in the ferrous form at low temperatures. These structural features can explain the fast autoxidation of the oxyferrous complex of CYP119. Finally, we report the first UV-Vis and EPR spectra of the cryoradiolytically reduced oxygenated intermediate of CYP119. The primary reduced intermediate, a hydroperoxo-ferric complex of CYP119, undergoes a 'peroxide shunt' pathway during gradual annealing at 170-195 K and returns to the low-spin ferric form.     

Flavonoid-induced conversion of catalase to its inactive form—Compound II

Abstract

Flavonoids (FlaOHs), plant polyphenols, are ubiquitous components of human diet and are known as antioxidants. However, their prooxidant activity has also been reported. We have recently found that FlaOHs inhibit catalase, the heme enzyme which catalyzes the decomposition of hydrogen peroxide (H₂O₂) into water and molecular oxygen. The catalytic cycle proceeds with the formation of the intermediate, Compound I (Cpd I), an oxoferryl porphyrin π-cation radical, the two-electron oxidation product of a heme group. Under conditions of low H₂O₂ fluxes and in the presence of an appropriate substrate, Cpd I can undergo one-electron reduction to inactive Compound II (Cpd II), oxoferryl derivative without radical site. Here we show that in vitro, under low fluxes of H₂O₂, FlaOHs reduce Cpd I to inactive Cpd II. Measurable amounts of Cpd II can be formed even in the presence of reduced nicotinamide adenine dinucleotide phosphate (NADPH) at concentration comparable with the investigated FlaOHs. Possible mechanisms of electron transfer from FlaOH molecule to the heme are discussed.     

Kinetic and equilibrium studies of acrylonitrile binding to cytochrome c peroxidase and oxidation of acrylonitrile by cytochrome c peroxidase compound I

Ferric heme proteins bind weakly basic ligands and the binding affinity is often pH dependent due to protonation of the ligand as well as the protein. In an effort to find a small, neutral ligand without significant acid/base properties to probe ligand binding reactions in ferric heme proteins we were led to consider the organonitriles. Although organonitriles are known to bind to transition metals, we have been unable to find any prior studies of nitrile binding to heme proteins. In this communication we report on the equilibrium and kinetic properties of acrylonitrile binding to cytochrome c peroxidase (CcP) as well as the oxidation of acrylonitrile by CcP compound I. Acrylonitrile binding to CcP is independent of pH between pH 4 and 8. The association and dissociation rate constants are 0.32 ± 0.16 M⁻¹ s⁻¹ and 0.34 ± 0.15 s⁻¹, respectively, and the independently measured equilibrium dissociation constant for the complex is 1.1 ± 0.2 M. We have demonstrated for the first time that acrylonitrile can bind to a ferric heme protein. The binding mechanism appears to be a simple, one-step association of the ligand with the heme iron. We have also demonstrated that CcP can catalyze the oxidation of acrylonitrile, most likely to 2-cyanoethylene oxide in a “peroxygenase”-type reaction, with rates that are similar to rat liver microsomal cytochrome P450-catalyzed oxidation of acrylonitrile in the monooxygenase reaction. CcP compound I oxidizes acrylonitrile with a maximum turnover number of 0.61 min⁻¹ at pH 6.0.