New activities of a catalytic antibody with a peroxidase activity: formation of Fe(II)-RNO complexes and stereoselective oxidation of sulfides.

In order to estimate the size of the cavity remaining around the heme of the 3A3-microperoxidase 8 (MP8) hemoabzyme, the formation of 3A3-MP8-Fe(II)-nitrosoalkane complexes upon oxidation of N-monosubstituted hydroxylamines was examined. This constituted a new reaction for hemoabzymes and is the first example of fully characterized Fe(II)-metabolite complexes of antibody-porphyrin. Also, via a comparison of the reactions with N-substituted hydroxylamines of various size and hydrophobicity, antibody 3A3 was confirmed to bring about a partial steric hindrance on the distal face of MP8. Subsequently, the influence of the antibody on the stereoselectivity of the S-oxidation of sulfides was examined. Our results showed that MP8 alone and the antibody-MP8 complex catalyze the oxidation of thioanisole by H(2)O(2) and tert-butyl hydroperoxide, following a peroxidase-like two-step oxygen-transfer mechanism involving a radical-cation intermediate. The best system, associating H(2)O(2) as oxidant and 3A3-MP8 as a catalyst, in the presence of 5% tert-butyl alcohol, led to the stereoselective S-oxidation of thioanisole with a 45% enantiomeric excess in favour of the R isomer. This constitutes the highest enantiomeric excess reported to date for the oxidation of sulfides catalyzed by hemoabzymes.     

Acetaminophen and analogs as cosubstrates and inhibitors of prostaglandin H synthase

Previous studies have shown that acetaminophen (APAP) is converted by prostaglandin H synthase (PGHS) to both one-electron oxidized products and the two-electron oxidized product, N-acetyl-p-benzoquinone imine (NAPQI). The present study further characterizes this reaction and shows that relatively low concentrations (20-200 microM) of APAP stimulate PGHS activity in ram seminal vesicle microsomes, whereas high concentrations (greater than 10 mM) inhibit the conversion of arachidonic acid (AA) to 15-hydroperoxy-9,11-peroxidoprosta-5,13-dienoic acid (PGG2). Stimulatory and inhibitory activities apparently involve the reduction of oxidized complexes of PGHS, and stimulatory and inhibitory activities roughly correlate with the electrochemical half-wave oxidation potentials of a series of hydroxyacetanilides. Using APAP as a probe, it was found that at low concentrations, APAP is converted in a cooxidation reaction with arachidonic acid to a dimer, 4'4"'-dihydroxy-3', 3"'-biacetanilide (bi-APAP), and other polymeric products. Moreover, an electrophilic metabolite of acetaminophen, NAPQI, was detected directly and also detected indirectly by its reaction with glutathione (GSH) to form 3'-(S-glutathionyl)acetaminophen (GS-APAP). The formation of all products was inhibited by indomethacin and the reductants, ascorbic acid and butylated hydroxyanisole (BHA). However, in the presence of GSH, ascorbic acid only partially inhibited the formation of GS-APAP while almost completely inhibiting the formation of bi-APAP. The same products of APAP (bi-APAP and NAPQI) were formed by PGHS and hydrogen peroxide in reactions that were not inhibited by indomethacin. At high concentrations of APAP that inhibit PGHS, the formation of products in the presence of arachidonic acid but not H2O2 was inhibited. These findings are generally consistent with a mechanism of acetaminophen oxidation by PGHS that involves common intermediate enzyme forms for both cyclooxygenase- and hydroperoxidase-catalyzed reactions. At least one of the intermediate complexes is reduced by relatively low concentrations of APAP and stimulates PGHS, whereas another intermediate complex is reduced by APAP at higher concentrations to inhibit the enzyme.     

Cytochrome P-455 nm complex formation in the metabolism of phenylalkylamines. XI. Peroxygenase versus monooxygenase function of cytochrome P-450 in rat liver microsomes

Cytochrome P-455 nm complex formation in phenobarbital induced rat liver microsomes was investigated using both an NADPH/O2-dependent monooxygenase system and a peroxygenase/peroxidase system where hydrogen peroxide was substituted for NADPH. The substrates tested were the enantiomers of four 1-alkyl-substituted 2-phenylethanamines (unbranched 1-alkyl substituents, comprising one to four carbons), S(+)- and R(-)-N-hydroxyamphetamine and racemic mixtures of N-hydroxy-1-phenyl-2-butanamine and N-hydroxy-3-methyl-1-phenyl-2-butanamine. During NADPH/O2-dependent metabolism the amines showed a positive correlation between extent of complex formation and lipophilicity; furthermore the S(+)-isomers gave rise to larger amounts of complex than the corresponding R(-)-analogues. With the hydroxylamines the ability to form complexes was greater than with any of the amines but no definite difference was seen among the hydroxylamines. In the peroxygenase system the hydroxylamines still gave larger amounts of complex than the amines but the differences seen within the homologous series of chiral amines when using the monooxygenase system were no longer observed. Although the quantitative trends in complex formation seen in the monooxygenase system were non-existent when H2O2 was substituted for NADPH, mere qualitative rules still seemed to apply; substrates which failed to give the complex during NADPH-dependent metabolism (2-phenylethanamine, phentermine, N-hydroxyphentermine and phenylacetone oxime) were inactive also in the peroxygenase system. The results substantiate the notion that the monooxygenase and peroxygenase reaction mechanisms of cyt. P-450 follow similar but not identical pathways.     

Cytochrome P-455 nm complex formation in the metabolism of phenylalkylamines. XII. Enantioselectivity and temperature dependence in microsomes and reconstituted cytochrome P-450 systems from rat liver.

Formation of metabolic intermediate (MI) complexes was studied with the enantiomers of amphetamine, 1-phenyl-2-pentanamine, N-hydroxyamphetamine, and 2-nitroso-1-phenylpropane (the C-nitroso analogue of amphetamine). Three different enzyme systems were used; liver microsomes from phenobarbital pretreated rats and two reconstituted systems containing the P450 2B1 and P450 2C11 forms of cytochrome P-450. Enantioselective complex formation in microsomes was shown for the amines and the nitroso compound, but not for the hydroxylamine. The highly purified P450 2B1 system formed the MI complex with all substrates tested, and the enantioselectivity observed with the microsomal system was reproduced. In the P450 2C11 system the nitroso compounds were completely inactive, whereas the enantiomers of N-hydroxyamphetamine still produced the complex at a high rate. Changes in temperature were shown to affect (R)-2-nitroso-1-phenylpropane more than its enantiomer. Both enantiomers showed biphasic Arrhenius plots for MI complex formation in microsomes (breaks around 22 degrees C), but the activation energies of the (R)-isomer were about five times higher than those of the (S)-isomer. A theory is presented which suggests different modes of interaction with the active site of P-450 to account for the different behaviour of the various substrates.     

Reactions catalyzed by the heme domain of inducible nitric oxide synthase: evidence for the involvement of tetrahydrobiopterin in electron transfer

The heme domain (iNOS(heme)) of inducible nitric oxide synthase (iNOS) was expressed in Escherichia coli and purified to homogeneity. Characterization of the expressed iNOS(heme) shows it to behave in all respects like full-length iNOS. iNOS(heme) is isolated without bound pterin but can be readily reconstituted with (6R)-5,6,7,8-tetrahydro-L-biopterin (H(4)B) or other pterins. The reactivity of pterin-bound and pterin-free iNOS(heme) was examined, using sodium dithionite as the reductant. H(4)B-bound iNOS(heme) catalyzes both steps of the NOS reaction, hydroxylating arginine to N(G)-hydroxy-L-arginine (NHA) and oxidizing NHA to citrulline and *NO. Maximal product formation (0.93 plus minus 0.12 equiv of NHA from arginine and 0.83 plus minus 0.08 equiv of citrulline from NHA) requires the addition of 2 to 2.5 electron equiv. Full reduction of H(4)B-bound iNOS(heme) with dithionite also requires 2 to 2.5 electron equiv. These data together demonstrate that fully reduced H(4)B-bound iNOS(heme) is able to catalyze the formation of 1 equiv of product in the absence of electrons from dithionite. Arginine hydroxylation requires the presence of a bound, redox-active tetrahydropterin; pterin-free iNOS(heme) or iNOS(heme) reconstituted with a redox-inactive analogue, 6(R,S)-methyl-5-deaza-5,6,7,8-tetrahydropterin, did not form NHA under these conditions. H(4)B has an integral role in NHA oxidation as well. Pterin-free iNOS(heme) oxidizes NHA to citrulline, N(delta)-cyanoornithine, an unidentified amino acid, and NO(-). Maximal product formation (0.75 plus minus 0.01 equiv of amino acid products) requires the addition of 2 to 2.5 electron equiv, but reduction of pterin-free iNOS(heme) requires only 1 to 1.5 electron equiv, indicating that both electrons for the oxidation of NHA by pterin-free iNOS(heme) are derived from dithionite. These data provide strong evidence that H(4)B is involved in electron transfer in NOS catalysis.     

Prostaglandin endoperoxide H synthases: peroxidase hydroperoxide specificity and cyclooxygenase activation

The cyclooxygenase (COX) activity of prostaglandin endoperoxide H synthases (PGHSs) converts arachidonic acid and O2 to prostaglandin G2 (PGG2). PGHS peroxidase (POX) activity reduces PGG2 to PGH2. The first step in POX catalysis is formation of an oxyferryl heme radical cation (Compound I), which undergoes intramolecular electron transfer forming Intermediate II having an oxyferryl heme and a Tyr-385 radical required for COX catalysis. PGHS POX catalyzes heterolytic cleavage of primary and secondary hydroperoxides much more readily than H2O2, but the basis for this specificity has been unresolved. Several large amino acids form a hydrophobic "dome" over part of the heme, but when these residues were mutated to alanines there was little effect on Compound I formation from H2O2 or 15-hydroperoxyeicosatetraenoic acid, a surrogate substrate for PGG2. Ab initio calculations of heterolytic bond dissociation energies of the peroxyl groups of small peroxides indicated that they are almost the same. Molecular Dynamics simulations suggest that PGG2 binds the POX site through a peroxyl-iron bond, a hydrogen bond with His-207 and van der Waals interactions involving methylene groups adjoining the carbon bearing the peroxyl group and the protoporphyrin IX. We speculate that these latter interactions, which are not possible with H2O2, are major contributors to PGHS POX specificity. The distal Gln-203 four residues removed from His-207 have been thought to be essential for Compound I formation. However, Q203V PGHS-1 and PGHS-2 mutants catalyzed heterolytic cleavage of peroxides and exhibited native COX activity. PGHSs are homodimers with each monomer having a POX site and COX site. Cross-talk occurs between the COX sites of adjoining monomers. However, no cross-talk between the POX and COX sites of monomers was detected in a PGHS-2 heterodimer comprised of a Q203R monomer having an inactive POX site and a G533A monomer with an inactive COX site.     

Cytochrome P-455 nm complex formation in the metabolism of phenylalkylamines. IX. A comparative study with enantiomeric 2-nitroso-1-phenylpropane in microsomes and a reconstituted cytochrome P-450 system from rat liver

Formation of cytochrome P-455 nm complexes was investigated with enantiomeric 2-nitroso-1-phenylpropane--the C-nitroso analogue of amphetamine--and optically active N-hydroxyamphetamine, in the presence of NADPH. For comparative reasons, three different drug-metabolizing enzyme systems were used, namely microsomes from control and phenobarbital-treated rats, and a reconstituted system containing the main phenobarbital-induced form of cytochrome P-450 from rat liver. In microsomes obtained from phenobarbital-treated rats, pronounced differences in the kinetics of complex formation were observed between the enantiomeric C-nitroso compounds, but not between the isomers of N-hydroxyamphetamine. In the reconstituted enzyme system the S-nitroso compound formed the P-455 nm chromophore at the highest initial rate, while the R analogue was devoid of complexing activity. The rates of complex formation from the N-hydroxylamine enantiomers were high and equal.     

Replacement of the proximal histidine iron ligand by a cysteine or tyrosine converts heme oxygenase to an oxidase

The H25C and H25Y mutants of human heme oxygenase-1 (hHO-1), in which the proximal iron ligand is replaced by a cysteine or tyrosine, have been expressed and characterized. Resonance Raman studies indicate that the ferric heme complexes of these proteins, like the complex of the H25A mutant but unlike that of the wild type, are 5-coordinate high-spin. Labeling of the iron with 54Fe confirms that the proximal ligand in the ferric H25C protein is a cysteine thiolate. Resonance-enhanced tyrosinate modes in the resonance Raman spectrum of the H25Y.heme complex provide direct evidence for tyrosinate ligation in this protein. The H25C and H25Y heme complexes are reduced to the ferrous state by cytochrome P450 reductase but do not catalyze alpha-meso-hydroxylation of the heme or its conversion to biliverdin. Exposure of the ferrous heme complexes to O2 does not give detectable ferrous-dioxy complexes and leads to the uncoupled reduction of O2 to H2O2. Resonance Raman studies show that the ferrous H25C and H25Y heme complexes are present in both 5-coordinate high-spin and 4-coordinate intermediate-spin configurations. This finding indicates that the proximal cysteine and tyrosine ligand in the ferric H25C and H25Y complexes, respectively, dissociates upon reduction to the ferrous state. This is confirmed by the spectroscopic properties of the ferrous-CO complexes. Reduction potential measurements establish that reduction of the mutants by NADPH-cytochrome P450 reductase, as observed, is thermodynamically allowed. The two proximal ligand mutations thus destabilize the ferrous-dioxy complex and uncouple the reduction of O2 from oxidation of the heme group. The proximal histidine ligand, for geometric or electronic reasons, is specifically required for normal heme oxygenase catalysis.     

Reaction of monosubstituted hydrazines and diazenes with rat-liver cytochrome P450. Formation of ferrous-diazene and ferric sigma-alkyl complexes

The alkyldiazenes RN = NH (R = CH3 or C2H5) react with reduced microsomal cytochrome P450 leading to complexes exhibiting a Soret peak at 446 nm. Upon oxidation of the [cytochrome P450-Fe(II)(CH3N = NH)] complex with limited amounts of dioxygen, a new complex characterized by a Soret peak at 486 nm is formed. The latter complex was also formed upon slow reaction of methyldiazene with microsomal cytochrome P450-Fe(III) or in situ oxidation of methylhydrazine by limited amounts of O2 or ferricyanide. This complex is rapidly destroyed by O2 or ferricyanide in excess and more slowly by excess dithionite in the presence of CO. Reactions of ethyldiazene or benzyldiazene with cytochrome P450-Fe(III) afforded similar complexes characterized by Soret peaks around 480 nm. These results, when compared to those recently described on reactions of monosubstituted hydrazines RNHNH2 and diazenes RN = NH with hemoglobin and iron-porphyrins, are consistent with a [cytochrome P450-Fe(II)(RN = NH)] structure for the 446-nm-absorbing complexes and a sigma-alkyl cytochrome P450-Fe(III)-R structure for the complexes characterized by a Soret peak around 480 nm. They also suggest a sigma-cytochrome P450-Fe(III)-Ph structure for the complex derived from phenylhydrazine oxidation, recently described in the literature. Finally, they provide the first evidence that cytochrome P450-Fe(III)-R complexes are formed upon microsomal oxidation of alkyl or phenylhydrazines.     

Formation of iron(II)-nitrosoalkane complexes: a new activity of microperoxidase 8

Microperoxidase 8 (MP8) is a heme octapeptide, obtained by enzymatic hydrolysis of heart cytochrome c, in which a histidine is axially coordinated to the heme iron, and acts as its fifth ligand. It exhibits two kinds of activities: a peroxidase-like activity and a cytochrome P450-like activity. We here show that MP8 is not only able to oxidize various aliphatic and aromatic hydroxylamines with the formation of MP8-Fe(II)-nitrosoalkane or -arene complexes absorbing around 414 nm, but also that these complexes can be obtained by reduction of nitroalkanes. This is the first example of fully characterized iron(II)-metabolite complexes of MP8. Such complexes constitute good models for those obtained upon oxidation of amphetamine or macrolids by cytochromes P450. In addition, this is a new catalytic activity of MP8, which validates the use of this mini-enzyme as a convenient model for hemoproteins of interest in toxicology and pharmacology such as cytochromes P450 and peroxidases.     

Kinetics of reduction of cytochrome c oxidase by dithionite and the effect of hydrogen peroxide

The reduction of cytochrome c oxidase by dithionite was reinvestigated with a flow-flash technique and with varied enzyme preparations. Since cytochrome a3 may be defined as the heme in oxidase which can form a photolabile CO adduct in the reduced state, it is possible to follow the time course of cytochrome a3 reduction by monitoring the onset of photosensitivity. The onset of photosensitivity and the overall rate of heme reduction were compared for Yonetani and Hartzell-Beinert preparations of cytochrome c oxidase and for the enzyme isolated from blue marlin and hammerhead shark. For all of these preparations the faster phase of heme reduction, which is dithionite concentration-dependent, is almost completed when the fraction of photosensitive material is still small. We conclude that cytochrome a3 in the resting enzyme is consistently reduced by an intramolecular electron transfer mechanism. To determine if this is true also for the pulsed enzyme, we examined the time course of dithionite reduction of the peroxide complex of the pulsed enzyme. It has been previously shown that pulsed cytochrome c oxidase can interact with H2O2 and form a stable room temperature peroxide adduct (Bickar, D., Bonaventura, J., and Bonaventura, C. (1982) Biochemistry 21, 2661-2666). Rather complex kinetics of heme reduction are observed when dithionite is added to enzyme preparations that contain H2O2. The time courses observed provide unequivocal evidence that H2O2 can, under these conditions, be used by cytochrome c oxidase as an electron acceptor. Experiments carried out in the presence of CO show that a direct dithionite reduction of cytochrome a3 in the peroxide complex of the pulsed enzyme does not occur.     

Novel heme ligation in a c-type cytochrome involved in thiosulfate oxidation: EPR and MCD of SoxAX from Rhodovulum sulfidophilum

The SoxAX complex of the bacterium Rhodovulum sulfidophilum is a heterodimeric c-type cytochrome that plays an essential role in photosynthetic thiosulfate and sulfide oxidation. The three heme sites of SoxAX have been analyzed using electronic absorption, electron paramagnetic resonance, and magnetic circular dichroism spectroscopies. Heme-3 in the ferric state is characterized by a Large g(max) EPR signal and has histidine and methionine axial heme iron ligands which are retained on reduction to the ferrous state. Hemes-1 and -2 both have thiolate plus nitrogenous ligand sets in the ferric state and give rise to rhombic EPR spectra. Heme-1, whose ligands derive from cysteinate and histidine residues, remains ferric in the presence of dithionite ion. Ferric heme-2 exists with a preparation-dependent mixture of two different ligand sets, one being cysteinate/histidine, the other an unidentified pair with a weaker crystal-field strength. Upon reduction of the SoxAX complex with dithionite, a change occurs in the ligands of heme-2 in which the thiolate is either protonated or replaced by an unidentified ligand. Sequence analysis places the histidine/methionine-coordinated heme in SoxX and the thiolate-liganded hemes in SoxA. SoxAX is the first naturally occurring c-type cytochrome in which a thiolate-coordinated heme has been identified.     

Ordered complexes of cytochrome c fragments. Kinetics of formation of the reduced (ferrous) forms

The kinetics of formation of noncovalently bound ferrous complexes derived from fragments of horse heart cytochrome c have been investigated. When the reactions are initiated by combining ferrous heme fragments with an appropriate apofragment, in the presence of 50 mM imidazole, second order rate processes are observed with rate constants essentially the same as those reported with ferric heme fragments (Parr, G. R., and Taniuchi, H. (1979) J. Biol. Chem. 254, 4836-4842). An additional, probably consecutive, kinetic process is also demonstrated. If imidazole is not present in the reaction buffer, the kinetic profiles are dramatically altered. While this is partially due to aggregation (dimerization) of the ferrous heme fragments, it can nevertheless be demonstrated that the complementation reactions with apofragments are much faster than those observed with the corresponding ferric heme fragments (in the absence of imidazole). These results reflect the effect of the oxidation state of the heme iron on the folding mechanism and, thus, the manifold nature of protein folding pathways. The rate of reduction of productive ferric complexes by sodium ascorbate was investigated and biphasic reactions were found in all cases. The data indicate an equilibrium between two forms of the ferric complexes. The results of an experiment in which the complementation of ferric (1-25)H and (23-104) was carried out in the presence of sodium ascorbate indicate that the intermediate complex (Parr, G. R., and Taniuchi, H. (1980) J. Biol. Chem. 255, 8914-8918) is not reducible by ascorbate. Thus, the increase in oxidation-reduction potential occurring on formation of the productive complex from the unbound heme fragment occurs at a late stage of the overall reaction, possibly coinciding with ligation of methionine 80 to the heme iron.     

Magnetic circular dichroism of myoglobin-thiolate complexes.

Various complexes of myoglobin (Mb) with thiolate were studied by use of magnetic circular dichroism (MCD) spectroscopy. 1. MetMb-ethyl, n-propyl and isopropylmercaptan complexes offered MCD spectra similar to that of cytochrome P-450 (P-450) with respect to shape and intensity ratio of Soret MCD to Q0-0 MCD. The MCD spectra did not show any pH dependence. The complexes reduced by sodium dithionite exhibited the MCD spectrum of deoxyMb, indicative of release of thiolate anion from the heme iron. 2. Cysteine and cysteine methyl ester coordinated to the heme iron at pH 9.18 but not at pH 6.86 and 11.45. The complex formed at pH 9.18 gave an MCD spectrum similar to that of P-450, and an MCD spectrum of deoxy Mb on reduction with sodium dithionite. 3. The 2-mercaptoethanol complex exhibited three A terms associated with the Q0-0-1, and Soret transitions at pH 6.86 similar to those of Fe(II) cytochrome c, which indicates that Mb was reduced by this reagent at pH 6.86. At pH 9.18 2-mercaptoethanol gave an MCD spectrum similar to that of alkyl mercaptan just after the addition. With the time changed into deoxy Mb through some intermediate of reduced Mb-thiolate complex. At pH 11.45 2-mercaptoethanol formed complex which exhibited an MCD spectrum similar to those of other alkylmercaptans. 4. Sodium sulfide gave an MCD spectrum which resembled that of the normal thiol Mb complex just after addition at pH 6.86. The complex was gradually reduced to give 610 nm trough in addition to the MCD of deoxy Mb. The Mb-sulfur complex formed at pH 9.18 was gradually reduced to give an MCD spectrum which was fairly different from that of deoxy Mb. A similar MCD spectrum was observed at pH 11.45 just after the addition of Na2S. These results were considered to suggest the saturation of one of the conjugated double bonds of the porphyrin by sulfur.     

The role of N-hydroxyamphetamine in the metabolic deamination of amphetamine

The formation of 1-phenyl-2-propanol from amphetamine and N-hydroxyamphetamine was measured to examine the role of N-hydroxyamphetamine in the deamination of amphetamine. The alcohol was measured because phenylacetone is rapidly and completely reduced in the incubation mixture. In separate incubations, alcohol formation was more rapid from amphetamine than from N-hydroxyamphetamine. When deuterium labelled amphetamine was incubated in the presence of N-hydroxyamphetamine, the ²H/¹H ratio for alcohol decreased while that for hydroxylamine increased with time. These experiments indicate that although the alcohol or ketone can form from N-hydroxyamphetamine, it is not an obligatory intermediate from amphetamine.     

Interaction of heme nonapeptide derived from cytochrome c with microsomal reductases

The interaction of heme nonapeptide (a proteolytic product of cytochrome c) with purified NADH:cytochrome b5 (EC 1.6.2.2) and NADPH:cytochrome P-450 (EC 1.6.2.4) reductases was investigated. In the presence of heme nonapeptide, NADH or NADPH were enzymatically oxidized to NAD+ and NADP+, respectively. NAD(P)H consumption was coupled to oxygen uptake in both enzyme reactions. In the presence of carbon monoxide the spectrum of a carboxyheme complex was observed during NAD(P)H oxidation, indicating the existence of a transient ferroheme peptide. NAD(P)H oxidation could be partially inhibited by cyanide, superoxide dismutase and catalase. Superoxide and peroxide ions (generated by enzymic xanthine oxidation) only oxidized NAD(P)H in the presence of heme nonapeptide. Oxidation of NAD(P)H was more rapid with O2- than O2-2. We suggest that a ferroheme-O2 and various heme-oxy radical complexes (mainly ferroheme-O-2 complex) play a crucial role in NAD(P)H oxidation.     

Isoporphyrin intermediate in heme oxygenase catalysis. Oxidation of alpha-meso-phenylheme

Human heme oxygenase-1 (hHO-1) catalyzes the O2- and NADPH-dependent oxidation of heme to biliverdin, CO, and free iron. The first step involves regiospecific insertion of an oxygen atom at the alpha-meso carbon by a ferric hydroperoxide and is predicted to proceed via an isoporphyrin pi-cation intermediate. Here we report spectroscopic detection of a transient intermediate during oxidation by hHO-1 of alpha-meso-phenylheme-IX, alpha-meso-(p-methylphenyl)-mesoheme-III, and alpha-meso-(p-trifluoromethylphenyl)-mesoheme-III. In agreement with previous experiments (Wang, J., Niemevz, F., Lad, L., Huang, L., Alvarez, D. E., Buldain, G., Poulos, T. L., and Ortiz de Montellano, P. R. (2004) J. Biol. Chem. 279, 42593-42604), only the alpha-biliverdin isomer is produced with concomitant formation of the corresponding benzoic acid. The transient intermediate observed in the NADPH-P450 reductase-catalyzed reaction accumulated when the reaction was supported by H2O2 and exhibited the absorption maxima at 435 and 930 nm characteristic of an isoporphyrin. Product analysis by reversed phase high performance liquid chromatography and liquid chromatography electrospray ionization mass spectrometry of the product generated with H2O2 identified it as an isoporphyrin that, on quenching, decayed to benzoylbiliverdin. In the presence of H218O2, one labeled oxygen atom was incorporated into these products. The hHO-1-isoporphyrin complexes were found to have half-lives of 1.7 and 2.4 h for the p-trifluoromethyl- and p-methyl-substituted phenylhemes, respectively. The addition of NADPH-P450 reductase to the H2O2-generated hHO-1-isoporphyrin complex produced alpha-biliverdin, confirming its role as a reaction intermediate. Identification of an isoporphyrin intermediate in the catalytic sequence of hHO-1, the first such intermediate observed in hemoprotein catalysis, completes our understanding of the critical first step of heme oxidation.     

A proximal tryptophan in NO synthase controls activity by a novel mechanism

The heme of neuronal nitric oxide synthase (nNOS) participates in O2 activation but also binds self-generated NO, resulting in reversible feedback inhibition. We utilized mutagenesis to investigate if a conserved tryptophan residue (Trp409), which engages in pi-stacking with the heme and hydrogen bonds to its axial cysteine ligand, helps control catalysis and regulation by NO. Mutants W409F and W409Y were hyperactive regarding NO synthesis without affecting cytochrome c reduction, reductase-independent N-hydroxyarginine oxidation, or Arg and tetrahydrobiopterin binding. In the absence of Arg electron flux through the heme was slower in the W409 mutants than in wild-type. However, less NO complex accumulated during NO synthesis by the mutants. To understand the mechanism, we compared the kinetics of heme-NO complex formation, rate of heme reduction, kcat prior to and after NO complex formation, NO binding affinity, NO complex stability, and its reaction with O2. During the initial phase of NO synthesis, heme-NO complex formation was three and five times slower in W409F and W409Y, which corresponded to a slower heme reduction. NO complex formation inhibited wild-type turnover 7-fold but reduced mutant turnover less than 2-fold, giving mutants higher steady-state activities. NO binding kinetics were similar among mutants and wild type, although mutants also formed a 417 nm ferrous-NO complex. Oxidation of ferrous-NO complex was seven times faster in mutants than in wild type. We conclude that mutant hyperactivity primarily derives from slower heme reduction and faster oxidation of the heme-NO complex by O2. In this way Trp409 mutations minimize NO feedback inhibition by limiting buildup of the ferrous-NO complex during the steady state. Conservation of W409 among NOS suggests that this proximal Trp may regulate NO feedback inhibition and is important for enzyme physiologic function.     

Differential effects of alkyl- and arylguanidines on the stability and reactivity of inducible NOS heme-dioxygen complexes

NO-Synthases are heme proteins that catalyze the oxidation of L-arginine into NO and L-citrulline. Some non-amino acid alkylguanidines may serve as substrates of inducible NOS (iNOS), while no NO* production is obtained from arylguanidines. All studied guanidines induce uncoupling between electrons transferred from the reductase domain and those required for NO formation. This uncoupling becomes critical with arylguanidines, leading to the exclusive formation of superoxide anion O2*- as well as hydrogen peroxide H2O2. To understand these different behaviors, we have conducted rapid scanning stopped-flow experiments with dihydrobiopterin (BH2) and tetrahydrobiopterin (BH4) to study, respectively, the (i) autoxidation and (ii) activation processes of heme ferrous-O2 complexes (Fe(II)O2) in the presence of eight alkyl- and arylguanidines. The Fe(II)O2 complex is more easily autooxidized by alkylguanidines (10-fold) and arylguanidines (100-fold) compared to L-arginine. In the presence of alkylguanidines and BH4, the oxygen-activation kinetics are very similar to those observed with L-arginine. Conversely, in the presence of arylguanidines, no Fe(II)O2 intermediate is detected. To understand such variations in reactivity and stability of Fe(II)O2 complex, we have characterized the effects of alkyl- and arylguanidines on Fe(II)O2 structure using the Fe(II)CO complex as a mimic. Resonance Raman and FTIR spectroscopies show that the two classes of guanidine derivatives induce different polar effects on Fe(II)CO environment. Our data suggest that the structure of the substituted guanidine can modulate the stability and the reactivity of heme-dioxygen complexes. We thus propose differential mechanisms for the electron- and proton-transfer steps in the NOS-dependent, oxygen-activation process, contingent upon whether alkyl- or arylguanidines are bound.     

Differential effects of mutations in human endothelial nitric oxide synthase at residues Tyr-357 and Arg-365 on L-arginine hydroxylation and GN-hydroxy-L-arginine oxidation

Biosynthesis of nitric oxide (NO) is catalyzed by NO synthase (NOS) through a two-step oxidation of L-arginine (Arg) with formation of an intermediate, GN-hydroxy-L-Arg (NHA). In this study we have employed mutagenesis to investigate how residues Y357 and R365 which interact primarily with the substrate Arg and (6R)-5,6,7,8-tetrahydro-L-biopterin (H(4)B) modulate these two steps of the NOS reaction. Mutant Y357F preserved most wild-type heme characteristics and NADPH oxidation ability. However, mutation of this residue markedly increased the dissociation constants for both Arg and NHA by 20-fold and decreased the NO synthesis from Arg by 85% compared to that of wild type. Mutation of Y357 had less effect on the rate of NO generated from NHA. Mutant R365L purified in the presence of Arg had a normal heme environment and retained 9 and 55% of the wild-type NO formation rate from Arg and NHA, respectively. When Arg was removed from buffer, R365L instantly became a low-spin state (Soret peak at 418 nm) with the resultant loss of H(4)B and instability of the heme-CO complex. The low-spin R365L exhibited an NADPH oxidation rate higher than that of wild type. Its Arg-driven NO formation was decreased to near the limit of detection, whereas the rate of NHA-driven NO synthesis was one third that of wild type. This NHA-driven NO formation completely relied on H(4)B and was not sensitive to superoxide dismutase or catalase but was inhibited by imidazole. The wild-type eNOS required 14 microM NHA and 0.39 microM H(4)B to reach the half-maximal NHA-driven NO formation rate (EC(50)), while R365L needed 59 microM NHA and 0.73 microM H(4)B to achieve EC(50). The differential effect of mutation on Arg and NHA oxidation suggests that distinct heme-based active oxidants are responsible for each step of NO synthesis.