Kinetics of oxygen binding to ferrous myeloperoxidase

Myeloperoxidase (MPO), which is involved in host defence and inflammation, is a unique peroxidase in having a globin-like standard reduction potential of the ferric/ferrous couple. Intravacuolar and exogenous MPO released from stimulated neutrophils has been shown to exist in the oxyferrous form, called compound III. To investigate the reactivity of ferrous MPO with molecular oxygen, a stopped-flow kinetic analysis was performed. In the absence of dioxygen, ferrous MPO decays to ferric MPO (0.04 s(-1) at pH 8 versus 1.4 s(-1) at pH 5). At pH 7.0 and 25 degrees C, compound III formation (i.e., binding of dioxygen to ferrous MPO) occurs with a rate constant of (1.1+/-0.1) x 10(4)M(-1)s(-1). The rate doubles at pH 5.0 and oxygen binding is reversible. At pH 7.0, the dissociation equilibrium constant of the oxyferrous form is (173+/-12)microM. The rate constant of dioxygen dissociation from compound III is much higher than conversion of compound III to ferric MPO (which is not affected by the oxygen concentration). This allows an efficient transition of compound III to redox intermediates which actually participate in the peroxidase or halogenation cycle of MPO.     

Redox properties of the couples compound I/compound II and compound II/native enzyme of human myeloperoxidase

Myeloperoxidase (MPO) is an important component of the neutrophil's antimicrobial armory and has been implicated in promoting tissue damage in numerous inflammatory diseases. For the first time the standard reduction potential of the redox couple compound II/native enzyme has been determined to be (0.97+/-0.01)V at pH 7.0 and 25 degrees C. This was achieved by rapid mixing of preformed compound II with either tyrosine or nitrite by using the sequential-mixing stopped-flow technique and measuring spectrophotometrically the concentrations of the reacting species and products at equilibrium. Using the recently determined standard reduction potential for the couple compound I/native enzyme (1.16 V), the reduction potential of the couple compound I/compound II was calculated to be 1.35 V at pH 7 and 25 degrees C. These data reveal substantial differences between the two known heme peroxidase superfamilies and reflect the dramatic differences observed in the oxidisability of substrates by the MPO redox intermediates compound I and compound II.     

Redox intermediates of plant and mammalian peroxidases: a comparative transient-kinetic study of their reactivity toward indole derivatives.

A comparative study on the reactivity of five indole derivatives (tryptamine, N-acetyltryptamine, tryptophan, melatonin, and serotonin), with the redox intermediates compound I (k2) and compound II (k3) of the plant enzyme horseradish peroxidase (HRP) and the two mammalian enzymes lactoperoxidase (LPO) and myeloperoxidase (MPO), was performed using the sequential-mixing stopped-flow technique. The calculated bimolecular rate constants (k2, k3) revealed substantial differences regarding the oxidazibility of the substrates by redox intermediates at pH 7.0 and 25 degrees C. With HRP it was shown that k2 and k3 are mainly determined by the reduction potential (Eo') of the substrate with k2 being 7-45 times higher than k3. Compound I of mammalian peroxidases was a much better oxidant than HRP compound I with the consequence that the influence of the indole structure on k2 of LPO and MPO was small varying by a factor of only 88 and 38, respectively, which is in strong contrast to a factor of 160,000 determined for k2 of HRP. Interestingly, the k3 values for all three enzymes were very similar. Oxidation of substrates by mammalian peroxidase compound II is strongly constrained by the nature of the substrate. The k3 values for the five indoles varied by a factor of 3,570 (LPO) and 200,000 (MPO), suggesting that the reduction potential of compound II of mammalian peroxidase is less positive than that of compound I, which is in contrast to the plant enzyme.     

Peroxynitrite efficiently mediates the interconversion of redox intermediates of myeloperoxidase

Nitric oxide-derived oxidants (e.g., peroxynitrite) are believed to participate in antimicrobial activities as part of normal host defenses but also in oxidative tissue injury in inflammatory disorders. A similar role is ascribed to the heme enzyme myeloperoxidase (MPO), the most abundant protein of polymorphonuclear leukocytes, which are the terminal phagocytosing effector cells of the innate immune system. Concomitant production of peroxynitrite and release of millimolar MPO are characteristic events during phagocytosis. In order to understand the mode of interaction between MPO and peroxynitrite, we have performed a comprehensive stopped-flow investigation of the reaction between all physiological relevant redox intermediates of MPO and peroxynitrite. Both iron(III) MPO and iron(II) MPO are rapidly converted to compound II by peroxynitrite in monophasic reactions with calculated rate constants of (6.8+/-0.1) x 10(6) M(-1)s(-1) and (1.3+/-0.2) x 10(6) M(-1)s(-1), respectively (pH 7.0 and 25 degrees C). Besides these one- and two-electron reduction reactions of peroxynitrite, which produce nitrogen dioxide and nitrite, a one-electron oxidation to the oxoperoxonitrogen radical must occur in the fast monophasic transition of compound I to compound II mediated by peroxynitrite at pH 7.0 [(7.6+/-0.1) x 10(6) M(-1)s(-1)]. In addition, peroxynitrite induced a steady-state transition from compound III to compound II with a rate of (1.0+/-0.3) x 10(4) M(-1)s(-1). Thus, the interconversion among the various oxidation states of MPO that is prompted by peroxynitrite is remarkable. Reaction mechanisms are proposed and the physiological relevance is discussed.     

Comparison of the binding and reactivity of plant and mammalian peroxidases to indole derivatives by computational docking

The oxidation of melatonin by the mammalian myeloperoxidase (MPO) provides protection against the damaging effects of reactive oxygen species. Indole derivatives, such as melatonin and serotonin, are also substrates of the plant horseradish peroxidase (HRP), but this enzyme exhibits remarkable differences from MPO in the specificity and reaction rates for these compounds. A structural understanding of the determinants of the reactivity of these enzymes to indole derivatives would greatly aid their exploitation for biosynthetic and drug design applications. Consequently, after validation of the docking procedure, we performed computational docking of melatonin and serotonin to structural models of the ferric and compound I and II (co I and co II, respectively) states of HRP and MPO. The substrates dock at the heme edge on the distal side, but with different orientations in the two proteins. The distal cavity is larger in MPO than in HRP; however, in MPO, the substrates make closer contacts with the heme involving ring stacking, whereas in HRP, no ring stacking is observed. The observed differences in substrate binding may contribute to the higher reaction rates and lower substrate specificity of MPO relative to those of HRP. The docking results, along with the previously measured heme-protein reduction potentials, suggest that the differentially lowered reaction rates of co II of HRP and MPO with respect to those of co I could stem from as yet undetermined conformational or electrostatic differences between the co I and co II states of MPO, which are absent in HRP.     

Thiocyanate modulates the catalytic activity of mammalian peroxidases

We investigated the potential role of the co-substrate, thiocyanate (SCN-), in modulating the catalytic activity of myeloperoxidase (MPO) and other members of the mammalian peroxidase superfamily (lactoperoxidase (LPO) and eosinophil peroxidase (EPO)). Pre-incubation of SCN- with MPO generates a more complex biological setting, because SCN- serves as either a substrate or inhibitor, causing diverse impacts on the MPO heme iron microenvironment. Consistent with this hypothesis, the relationship between the association rate constant of nitric oxide binding to MPO-Fe(III) as a function of SCN- concentration is bell-shaped, with a trough comparable with normal SCN- plasma levels. Rapid kinetic measurements indicate that MPO, EPO, and LPO Compound I formation occur at rates slower than complex decay, and its formation serves to simultaneously catalyze SCN- via 1e- and 2e- oxidation pathways. For the three enzymes, Compound II formation is a fundamental feature of catalysis and allows the enzymes to operate at a fraction of their possible maximum activities. MPO and EPO Compound II is relatively stable and decays gradually within minutes to ground state upon H2O2 exhaustion. In contrast, LPO Compound II is unstable and decays within seconds to ground state, suggesting that SCN- may serve as a substrate for Compound II. Compound II formation can be partially or completely prevented by increasing SCN- concentration, depending on the experimental conditions. Collectively, these results illustrate for the first time the potential mechanistic differences of these three enzymes. A modified kinetic model, which incorporates our current findings with the mammalian peroxidases classic cycle, is presented.     

Interrogation of heme pocket environment of mammalian peroxidases with diatomic ligands

Recent studies demonstrate that myeloperoxidase (MPO), eosinophil peroxidase (EPO), and lactoperoxidase (LPO), homologous members of the mammalian peroxidase superfamily, can all serve as catalysts for generating nitric oxide- (nitrogen monoxide, NO) derived oxidants. These enzymes contain heme prosthetic groups that are ligated through a histidine nitrogen and use H(2)O(2) as the electron acceptor in the catalysis of oxidative reactions. Here we show that heme reduction of these peroxidases results in distinct electronic and/or conformational changes in their heme pockets using a combination of rapid kinetics measurements, optical absorbance, and diatomic ligand binding studies. Addition of reducing agent to each peroxidase at ground state [Fe(III) state] causes immediate buildup of the corresponding Fe(II) complexes. Spectral changes indicate that two LPO-Fe(II) species are present in solution at equilibrium. Analyses of stopped-flow traces collected when EPO, MPO, or LPO solutions rapidly mixed with NO were accurately fit by single-exponential functions. Plots of the apparent rate constants as a function of NO concentration for all Fe(III) and Fe(II) forms were linear with positive intercepts, consistent with NO binding to each form in a simple reversible one-step mechanism. Fe(II) forms of MPO and LPO, but not EPO, displayed significantly lower affinity toward NO compared to Fe(III) forms, suggesting that heme reduction causes a dramatic change in the heme pocket electronic environment that alters the affinity and/or accessibility of heme iron toward NO. Optical absorbance spectra indicate that CO binds to the Fe(II) forms of both LPO and EPO, but not with MPO, and generates their respective low-spin six-coordinate complexes. Kinetic analyses indicate that the binding of CO to EPO is monophasic while CO binding to LPO is biphasic. Collectively, these results illustrate for the first time functional differences in the heme pocket environments of Fe(II) forms of EPO, LPO, and MPO toward binding of diatomic ligands. Our results suggest that, upon reduction, the heme pocket of MPO collapses, LPO adopts two spectroscopically and kinetically distinguishable forms (one partially open and the other relatively closed), and EPO remains open.     

A theoretical three-dimensional model for lactoperoxidase and eosinophil peroxidase,built on the scaffold of the myeloperoxidase X-ray structure

 Lactoperoxidase (LPO), eosinophil peroxidase (EPO) and myeloperoxidase (MPO) belong to the class of haloperoxidases, a group of mammalian enzymes able to catalyze the peroxidative oxidation of halides and pseudohalides, such as thiocyanate. They all play a key role in the development of antibacterial activity. The homology in their functional role is emphasized by the striking similarity of their primary structures. A theoretical model for the three-dimensional structure of LPO and EPO has been developed on the basis of the X-ray structure of MPO, a high degree of similarity having been found in their sequences. Evidence supporting the hypothesis of an ester linkage between heme and apoprotein in LPO and EPO, originally proposed by Hultquist and Morrison is discussed. Received: 2 May 1996 / Accepted: 25 July 1996     

Electrochemical characterization of lignin peroxidase from the white-rot basidiomycete Phanerochaete chrysosporium

Electrochemical analysis of lignin peroxidase (LiP) was performed using a pyrolytic graphite electrode coated with peroxidase-embedded tributylmethyl phosphonium chloride membrane. The formal redox potential of ferric/ferrous couples of LiP was −126 mV (versus SHE), which was comparable with that of manganese peroxidase (MnP) and horseradish peroxidase (HRP). Yet, only LiP is capable of oxidizing non-phenolic substrates with a high redox potential. Since with decreasing pH, the redox potential increased, an incredibly low pH optimum of LiP as peroxidase at 3.0 or lower was proposed as the clue to explain LiP mechanisms. A low pH might be the key for LiP to possess a high redox potential. The pK_a values for the distal His in peroxidases were calculated using redox data and the Nernst equation, to be 5.8 for LiP, 4.7 for MnP, and 3.8 for HRP. A high pK_a value of the distal His might be crucial for LiP compound II to uptake a proton from the solvent. As a result, LiP is able to complete its catalytic cycle during the oxidation of non-proton-donating substrates. In compensation, LiP has diminished its reactivity toward hydrogen peroxide.     

The activity of mammalian peroxidases (lactoperoxidase and myeloperoxidase) and their compounds III toward 2-t-butyl-4-methoxyphenol (butylated hydroxyanisole) and its dimer (2,2'-dihydroxy-3,3'-di-t-butyl-5,5'-dimethoxydiphenyl).

Spectral evidence is presented which shows that butylated hydroxyanisole (BHA) and its dimer act as electron donors for lactoperoxidase (LPO) and myeloperoxidase (MPO) by two different pathways: peroxidative and oxidative. LPO compound II and MPO compound II are converted to native enzymes in their reactions with BHA without detectable intermediates. This confirms a normal peroxidatic oxidation of this commonly used antioxidant. We also report spectral data indicating the reductions of peroxidase compound III to the native state in reactions with BHA (LPO, MPO) or with di-BHA (LPO). This oxidative reaction has significant physiological relevance, ensuring return of peroxidases to the native state for re-entry into the normal peroxidatic cycle or into halogenating reactions.     

Propofol inhibits the myeloperoxidase activity by acting as substrate through a redox process

BackgroundPropofol (2,6-diisopropylphenol) is frequently used as intravenous anesthetic agent, especially in its injectable form (Diprivan), to initiate and maintain sedative state during surgery or in intensive care units. Numerous studies have reported the antioxidant and anti-inflammatory effect of propofol. The oxidant enzyme myeloperoxidase (MPO), released from activated neutrophils, plays a key role in host defense. An increase of the circulating MPO concentration has been observed in patients admitted in intensive care unit and presenting a systemic inflammatory response related to septic shock or trauma.MethodsThis study investigates the immunomodulatory action of propofol and Diprivan as inhibitor of the oxidant activity of MPO. The understanding of the redox action mechanism of propofol and Diprivan on the myeloperoxidase chlorination and peroxidase activities has been refined using the combination of fluorescence and absorption spectroscopies with docking and cyclic voltammetry.ResultsPropofol acts as a reversible MPO inhibitor. The molecule interacts as a reducing substrate in the peroxidase cycle and promotes the accumulation of compound II. At acidic pH (5.5), propofol and Diprivan do not inhibit the chlorination activity, but their action increases at physiological pH (7.4). The main inhibitory action of Diprivan could be attributed to its HOCl scavenging property.General significancePropofol can act as a reversible MPO inhibitor at clinical concentrations. This property could, in addition to other previously proven anti-inflammatory actions, induce an immunomodulatory action, beneficial during clinical use, particularly in the treatment of systemic inflammation response syndrome.     

Myeloperoxidase-catalyzed taurine chlorination: initial versus equilibrium rate

Myeloperoxidase (MPO) catalyzes the two-electron oxidation of chloride, thereby producing hypochlorous acid (HOCl). Taurine (2-aminoethane-sulfonic acid, Tau) is thought to act as a trap of HOCl forming the long-lived oxidant monochlorotaurine [(N-Cl)-Tau], which participates in pathogen defense. Here, we amend and extend previous studies by following initial and equilibrium rate of formation of (N-Cl)-Tau mediated by MPO at pH 4.0-7.0, varying H(2)O(2) concentration. Initial rate studies show no saturation of the active site under assay conditions (i.e. [H(2)O(2)] > or = 2000 [MPO]). Deceleration of Tau chlorination under equilibrium is quantitatively described by the redox equilibrium established by H(2)O(2)-mediated reduction of compound I to compound II. At equilibrium regime the maximum chlorination rate is obtained at [H(2)O(2)] and pH values around 0.4mM and pH 5. The proposed mechanism includes known acid-base and binding equilibria taking place at the working conditions. Kinetic data ruled out the currently accepted mechanism in which a proton participates in the molecular step (MPO-I+Cl(-)) leading to the formation of the chlorinating agent. Results support the formation of a chlorinating compound I-Cl(-) complex (MPO-I-Cl) and/or of ClO(-), through the former or even independently of it. ClO(-) diffuses away and rapidly protonates to HOCl outside the heme pocket. Smaller substrates will be chlorinated inside the enzyme by MPO-I-Cl and outside by HOCl, whereas bulkier ones can only react with the latter.     

Unraveling the catalytic mechanism of lactoperoxidase and myeloperoxidase.

Although belonging to the widely investigated peroxidase superfamily, lactoperoxidase (LPO) and myeloperoxidase (MPO) share structural and functional features that make them peculiar with respect to other enzymes of the same group. A survey of the available literature on their catalytic intermediates enabled us to ask some questions that remained unanswered. These questions concern controversial features of the LPO and MPO catalytic cycle, such as the existence of Compound I and Compound II isomers and the identification of their spectroscopic properties. After addressing each of these questions, we formulated a hypothesis that describes an integrated vision of the catalytic mechanism of both enzymes. The main points are: (a) a re-evaluation of the role of superoxide as a reductant in the catalytic cycle; (b) the existence of Cpd I isomers; (c) reciprocal interactions between catalytic intermediates and (d) a mechanistic explanation for catalase activity in both enzymes.     

Interaction of ceruloplasmin with eosinophil peroxidase as compared to its interplay with myeloperoxidase: Reciprocal effect on enzymatic properties

Abstract

Myeloperoxidase (MPO) and eosinophil peroxidase (EPO) are involved in the development of halogenative stress during inflammation. We previously described a complex between MPO and ceruloplasmin (CP). Considering the high structural homology between MPO and EPO, we studied the latter's interaction with CP and checked whether EPO becomes inhibited in a complex with CP. Disc-electrophoresis and gel filtration showed that CP and EPO form a complex with the stoichiometry 1:1. Affinity chromatography of EPO on CP-agarose (150 mM NaCl, 10 mM Na-phosphate buffer, of pH 7.4) resulted in retention of EPO. EPO protects ceruloplasmin from limited proteolysis by plasmin. Only intact CP shifted the Soret band typical of EPO from 413 to 408 nm. The contact with CP likely causes changes in the heme pocket of EPO. Peroxidase activity of EPO with substrates such as guaiacol, orcinol, o-dianisidine, 4-chloro-1-naphtol, 3,3’,5,5’-tetramethylbenzidine, and 2,2’-azino-bis(3-ethylbenzthiazoline-6-sulfonate) is inhibited by CP in a dose-dependent manner. Similar to the interaction with MPO, the larger a substrate molecule, the stronger the inhibitory effect of CP upon EPO. The limited proteolysis of CP abrogates its capacity to inhibit the peroxidase activity of EPO. The peptide RPYLKVFNPR (corresponding to amino acids 883–892 in CP) inhibits the peroxidase and chlorinating activity of EPO. Only the chlorinating activity of EPO is efficiently inhibited by CP, while the capacity of EPO to oxidize bromide and thiocyanate practically does not depend on the presence of CP. EPO enhances the p-phenylenediamine-oxidase activity of CP. The structural homology between the sites in the MPO and EPO molecules enabling them to contact CP is discussed.     

pH-dependent regulation of myeloperoxidase activity

The balance between peroxidase and chlorinating activities of myeloperoxidase (MPO) is very important for the enhancement of antimicrobial action and prevention of damage caused by hypochlorite. In the present paper, the peroxidase and chlorinating activities have been studied at various pH values. The possibility of using neutrophil protein solution for the evaluation of MPO activity has been demonstrated. It is shown that at neutral pH MPO had higher affinity to peroxidase substrate guaiacol: at pH 7.4, chloride ions did not compete with guaiacol up to the concentration of 150 mM. At acidic pH, chlorinating activity of MPO dominates: only hypochlorite production can be detected at equal chloride and guaiacol concentrations of 15 mM. However, horseradish peroxidase does not exhibit any difference in activity in the presence of chloride ions even at acidic pH values. It was demonstrated by MALDI-TOF mass-spectrometry that the amount of hypochlorite produced is sufficient to modify phospholipids (with formation of Cl- and Br-hydrins and lyso-derivatives) only at acidic pH (5.0). Thus, in the presence of phenolic peroxidase substrate, MPO chlorinating activity can be displayed at acidic pH only. It can lead to elimination of hypochlorite production in normal tissues at neutral pH (7.4) and its enhancement in phagosomes where the pH range is 4.7-6.0.     

Roles of distal arginine in activity and stability of Coprinus cinereus peroxidase elucidated by kinetic and NMR analysis of the Arg51Gln, -Asn, -Leu, and -Lys mutants

In heme peroxidases, a distal His residue plays an essential role in the initial two electron oxidation of resting state enzyme to compound I by hydrogen peroxide. A distal Arg residue assists in this process. The contributions of the charge, H-bonding capacity, size, and mobility of this Arg residue to Coprinus cinereus peroxidase (CIP) reactivity and stability have been examined by substituting Arg51 with Gln (retains H-bond donor at N epsilon position), Asn (small size, H-bond donor and acceptor), Leu (similar to Asn, but hydrophobic), and Lys (charge and H-bond donor, but at N zeta position). UV-visible spectroscopy was used to monitor pH-linked heme changes, compound I formation and reduction, fluoride binding, and thermostability. (1)H NMR spectroscopy enabled heme pocket differences in both resting and cyanide-ligated states of the enzymes to be evaluated and compared with wild-type CIP. We found that the H-bonding capacity of distal Arg is key to fast compound I formation and ligand binding to heme, whereas charge is important for lowering the pK(a) of distal His and for the binding and stabilisation of anionic ligands at heme iron. The properties of the distal Arg residue in CIP, cytochrome c peroxidase (CCP) and horseradish peroxidase (HRP) differ significantly in their pH induced transitions and dynamics.     

Mechanism of reaction of horseradish peroxidase with chlorite and chlorine dioxide

It is demonstrated that horseradish peroxidase (HRP) mixed with chlorite follows the whole peroxidase cycle. Chlorite mediates the two-electron oxidation of ferric HRP to compound I (k(1)) thereby releasing hypochlorous acid. Furthermore, chlorite acts as one-electron reductant of both compound I (k(2)) and compound II (k(3)) forming chlorine dioxide. The strong pH-dependence of all three reactions clearly suggests that chlorous acid is the reactive species. Typical apparent bimolecular rate constants at pH 5.6 are 1.4 x 10(5)M(-1)s(-1) (k(1)), 2.25 x 10(5)M(-1)s(-1) (k(2)), and 2.4 x 10(4)M(-1)s(-1) (k(3)), respectively. Moreover, the reaction products hypochlorous acid and chlorine dioxide, which are known to induce heme bleaching and amino acid modification upon longer incubation times, also mediate the oxidation of ferric HRP to compound I (2.4 x 10(7)M(-1)s(-1) and 2.7 x 10(4)M(-1)s(-1), respectively, pH 5.6) but do not react with compounds I and II. A reaction scheme is presented and discussed from both a mechanistic and thermodynamic point of view. It helps to explain the origin of contradictory data so far found in the literature on this topic.     

N-methyltetrahydro-beta-carboline analogs of 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) neurotoxin are oxidized to neurotoxic beta-carbolinium cations by heme peroxidases

2-Methyl-1,2,3,4-tetrahydro-beta-carboline (2-Me-THbetaC) and 2,9-dimethyl-1,2,3,4-tetrahydro-beta-carboline (2,9-diMe-THbetaC) are naturally occurring analogs of the Parkinsonian neurotoxin 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), whereas their corresponding aromatic 2-methyl-beta-carbolinium cations resemble 1-methyl-4-phenylpyridinium (MPP(+)) and are considered potential toxins involved in Parkinson's disease (PD). To become toxicants, 2-methyltetrahydro-beta-carbolines need to be oxidized (aromatized) by human metabolic enzymes to pyridinium-like (beta-carbolinium) cations as occur with MPTP/MPP(+) model. In contrast to MPTP, human MAO-A or -B were not able to oxidize 2-Me-THbetaC to pyridinium-like cations. Neither, cytochrome P-450 2D6 or a mixture of six P450 enzymes carried out this oxidation in a significant manner. However, 2-Me-THbetaC and 2,9-diMe-THbetaC were efficiently oxidized by horseradish peroxidase (HRP), lactoperoxidase (LPO), and myeloperoxidase (MPO) to 2-methyl-3,4-dihydro-beta-carbolinium cations (2-Me-DHbetaC(+), 2,9-diMe-DHbetaC(+)) as the main products, and detectable amount of 2-methyl-beta-carbolinium cations (2-Me-betaC(+), 2,9-diMe-betaC(+)). The apparent kinetic parameters (k(cat), k(4)) were similar for HRP and LPO and higher for MPO. Peroxidase inhibitors (hydroxylamine, sodium azide, and ascorbic acid) highly reduced or abolished this oxidation. Although MPTP was not oxidized by peroxidases; its intermediate metabolite 1-methyl-4-phenyl-2,3-dihydropyridinium cation (MPDP(+)) was efficiently oxidized to MPP(+) by heme peroxidases. It is concluded that heme peroxidases could be key catalysts responsible for the aromatization (bioactivation) of endogenous and naturally occurring N-methyltetrahydro-beta-carbolines and related protoxins to toxic pyridinium-like cations resembling MPP(+), suggesting a role for these enzymes in toxicological and neurotoxicological processes.     

Nature of the ferryl heme in compounds I and II

Heme enzymes are ubiquitous in biology and catalyze a vast array of biological redox processes. The formation of high valent ferryl intermediates of the heme iron (known as Compounds I and Compound II) is implicated for a number of catalytic heme enzymes, but these species are formed only transiently and thus have proved somewhat elusive. In consequence, there has been conflicting evidence as to the nature of these ferryl intermediates in a number of different heme enzymes, in particular the precise nature of the bond between the heme iron and the bound oxygen atom. In this work, we present high resolution crystal structures of both Compound I and Compound II intermediates in two different heme peroxidase enzymes, cytochrome c peroxidase and ascorbate peroxidase, allowing direct and accurate comparison of the bonding interactions in the different intermediates. A consistent picture emerges across all structures, showing lengthening of the ferryl oxygen bond (and presumed protonation) on reduction of Compound I to Compound II. These data clarify long standing inconsistencies on the nature of the ferryl heme species in these intermediates.