Stabilized isoporphyrin intermediates in the inactivation of horseradish peroxidase by alkylhydrazines

The reaction of horseradish peroxidase with alkylhydrazines results in delta-meso-alkylation of the prosthetic heme group and enzyme inactivation (Ator, M. A., David, S. K., and Ortiz de Montellano, P. R. (1987) J. Biol. Chem. 262, 14954-14960). As reported here, enzyme inactivation is associated with the accumulation of intermediates that absorb at approximately 835 nm. The properties of these intermediates, including their collapse to give meso-alkylhemes, identify them as isoporphyrins. The t1/2 values for inactivation and formation of the isoporphyrin intermediate at 25 degrees C are, respectively, 11.6 and 12.5 min for methylhydrazine (2.0 mM), 8.7 and 7.2 min for ethylhydrazine (1.0 mM), and 30 and 25 s for phenylethylhydrazine (50 microM). The isoporphyrin intermediates are surprisingly long-lived, with half-lives (35 degrees C, pH 7.0) of 9, 28, 96, and 450 min for, respectively, the phenylethyl, methyl, n-butyl, and ethyl analogues. pH studies show that protonation of a group with pKa = 5.0-6.5 accelerates isoporphyrin decay and decreases steady state isoporphyrin accumulation. Horseradish peroxidase reconstituted with delta-meso-methylheme, unlike horseradish peroxidase with a heme that has a larger meso-substituent, is catalytically active but is more sensitive to H2O2-mediated degradation of the prosthetic group than is the native enzyme. The delta-meso-methylheme prosthetic group is converted in the reaction with H2O2 to a biliverdin-like product. The results implicate highly stabilized isoporphyrin intermediates in the inactivation of horseradish peroxidase by alkylhydrazines and indicate that inactivation by the meso-alkyl groups is due to steric interference with electron delivery to the heme edge rather than to intrinsic electronic consequences of meso-alkylation. The structural features that stabilize the cationic isoporphyrins may also be involved in stabilization of the Compound I porphyrin radical cation.     

Regioselective peroxo-dependent heme alkylation in P450(BM3)-F87G by aromatic aldehydes: effects of alkylation on cataysis

Cytochrome P450(BM3)-F87G reacts with aromatic aldehydes and hydrogen peroxide to generate covalent heme adducts in a reaction that may involve the formation of a stable isoporphyrin intermediate [Raner, G. M., Hatchell, A. J., Morton, P. E., Ballou, D. P., and Coon, M. J. (2000) J. Inorg. Biochem. 81, 153-160]. Electron paramagnetic resonance spectra for the proposed isoporphyrin intermediates generated using two different aromatic aldehydes suggest that, in each case, the heme remained coordinated to the apoenzyme via the cysteine thiolate, the metal center remained ferric low spin, and a slight distortion in the geometry of the pyrrole nitrogens occurred. Characterization of the resulting heme adducts via 1D and 2D NMR showed conclusively that the heme was modified at the gamma-meso position alone, and mass spectral analysis indicated loss of formate from the aldehyde prior to alkylation. The enzyme derivatives in which the hemes were covalently altered retained the characteristic UV/vis and EPR spectral properties of a P450, indicating that the heme was properly ligated in the active site. The modified enzymes were able to accept electrons from NADPH in the presence of lauric acid at a rate comparable to that of the unmodified forms, although oxidation of the lauric acid was not observed with either modified enzyme. Oxidation of 4-nitrophenol and 4-nitrocatechol was observed for both derivatives. However, 4-nitrocatechol oxidation was completely quenched in the presence of superoxide dismutase. The results are consistent with heme modification occurring through a peroxo-dependent pathway and also suggest that modification results in altered catalytic activity, rather than complete inactivation of the P450.     

Diversity in mechanisms of substrate oxidation by cytochrome P450 2D6. Lack of an allosteric role of NADPH-cytochrome P450 reductase in catalytic regioselectivity

Cytochrome P450 (P450) 2D6 was first identified as the polymorphic human debrisoquine hydroxylase and subsequently shown to catalyze the oxidation of a variety of drugs containing a basic nitrogen. Differences in the regioselectivity of oxidation products formed in systems containing NADPH-P450 reductase/NADPH and the model oxidant cumene hydroperoxide have been proposed by others to be due to an allosteric influence of the reductase on P450 2D6 (Modi, S., Gilham, D. E., Sutcliffe, M. J., Lian, L.-Y., Primrose, W. U., Wolf, C. R., and Roberts, G. C. K. (1997) Biochemistry 36, 4461-4470). We examined the differences in the formation of oxidation products of N-methyl-4-phenyl-1,2,5,6-tetrahydropyridine, metoprolol, and bufuralol between reductase-, cumene hydroperoxide-, and iodosylbenzene-supported systems. Catalytic regioselectivity was not influenced by the presence of the reductase in any of the systems supported by model oxidants, ruling out allosteric influences. The presence of the reductase had little effect on the affinity of P450 2D6 for any of these three substrates. The addition of the reaction remnants of the model oxidants (cumyl alcohol and iodobenzene) to the reductase-supported system did not affect reaction patterns, arguing against steric influences of these products on catalytic regioselectivity. Label from H(2)18O was quantitatively incorporated into 1'-hydroxybufuralol in the iodosylbenzene- but not in the reductase- or cumene hydroperoxide-supported reactions. We conclude that the P450 systems utilizing NADPH-P450 reductase, cumene hydroperoxide, and iodosylbenzene use similar but distinct chemical mechanisms. These differences are the basis for the variable product distributions, not an allosteric influence of the reductase.     

The binding sites on human heme oxygenase-1 for cytochrome p450 reductase and biliverdin reductase

Human heme oxygenase-1 (hHO-1) catalyzes the NADPH-cytochrome P450 reductase-dependent oxidation of heme to biliverdin, CO, and free iron. The biliverdin is subsequently reduced to bilirubin by biliverdin reductase. Earlier kinetic studies suggested that biliverdin reductase facilitates the release of biliverdin from hHO-1 (Liu, Y., and Ortiz de Montellano, P. R. (2000) J. Biol. Chem. 275, 5297-5307). We have investigated the binding of P450 reductase and biliverdin reductase to truncated, soluble hHO-1 by fluorescence resonance energy transfer and site-specific mutagenesis. P450 reductase and biliverdin reductase bind to truncated hHO-1 with Kd = 0.4 +/- 0.1 and 0.2 +/- 0.1 microm, respectively. FRET experiments indicate that biliverdin reductase and P450 reductase compete for binding to truncated hHO-1. Mutation of surface ionic residues shows that hHO-1 residues Lys18, Lys22, Lys179, Arg183, Arg198, Glu19, Glu127, and Glu190 contribute to the binding of cytochrome P450 reductase. The mutagenesis results and a computational analysis of the protein surfaces partially define the binding site for P450 reductase. An overlapping binding site including Lys18, Lys22, Lys179, Arg183, and Arg185 is similarly defined for biliverdin reductase. These results confirm the binding of biliverdin reductase to hHO-1 and define binding sites of the two reductases.     

Monooxygenation of an aromatic ring by F43W/H64D/V68I myoglobin mutant and hydrogen peroxide. Myoglobin mutants as a model for P450 hydroxylation chemistry

Myoglobin (Mb) is used as a model system for other heme proteins and the reactions they catalyze. The latest novel function to be proposed for myoglobin is a P450 type hydroxylation activity of aromatic carbons (Watanabe, Y., and Ueno, T. (2003) Bull. Chem. Soc. Jpn. 76, 1309-1322). Because Mb does not contain a specific substrate binding site for aromatic compounds near the heme, an engineered tryptophan in the heme pocket was used to model P450 hydroxylation of aromatic compounds. The monooxygenation product was not previously isolated because of rapid subsequent oxidation steps (Hara, I., Ueno, T., Ozaki, S., Itoh, S., Lee, K., Ueyama, N., and Watanabe, Y. (2001) J. Biol. Chem. 276, 36067-36070). In this work, a Mb variant (F43W/H64D/V68I) is used to characterize the monooxygenated intermediate. A modified (+16 Da) species forms upon the addition of 1 eq of H2O2. This product was digested with chymotrypsin, and the modified peptide fragments were isolated and characterized as 6-hydroxytryptophan using matrix-assisted laser desorption ionization time-of-flight tandem mass spectroscopy and 1H NMR. This engineered Mb variant represents the first enzyme to preferentially hydroxylate the indole side chain of Trp at the C6 position. Finally, heme extraction was used to demonstrate that both the formation of the 6-hydroxytryptophan intermediate (+16 Da) and subsequent oxidation to form the +30 Da final product are catalyzed by the heme cofactor, most probably via the compound I intermediate. These results provide insight into the mechanism of hydroxylation of aromatic carbons by heme proteins, demonstrating that non-thiolate-ligated heme enzymes can perform this function. This establishes Mb compound I as a model for P450 type aromatic hydroxylation chemistry.     

Structure and catalytic mechanism of horseradish peroxidase. Regiospecific meso alkylation of the prosthetic heme group by alkylhydrazines

Horseradish peroxidase is inactivated in a time-, H2O2-, and concentration-dependent manner by phenylethyl-, ethyl-, and methylhydrazine. The pseudo- first order kinetic constants for these inactivation reactions at pH 7 are: phenylethyl (KI = 115 microM, kinact = 1.5 min-1, partition ratio = 11), ethyl (KI = 145 microM, kinact = 0.08 min-1, partition ratio = 32), and methyl (KI = 3000 microM, kinact = 0.12 min-1, partition ratio = 80). At pH 5, the constants for the phenylethyl reaction change to KI = 1540 microM and kinact = 0.86 min-1. A transient absorbance at approximately 830 nm, suggestive of an isoporphyrin intermediate, is seen during these reactions. The prosthetic heme is converted by each of the three alkylhydrazines into the corresponding delta-meso-alkylated heme. Complete inactivation of the enzymes by methyl-, ethyl-, and phenylethylhydrazine is associated with alkylation of 60-70, 70, and 90%, respectively, of the prosthetic heme groups. The absence of N-alkylation and the high specificity for the delta-meso position, even with agents as small as methylhydrazine, strengthen the proposal that electron abstraction is mediated by the heme edge rather than the ferryl oxygen of horseradish peroxidase.     

Human heme oxygenase oxidation of 5- and 15-phenylhemes

Human heme oxygenase-1 (hHO-1) catalyzes the O2-dependent oxidation of heme to biliverdin, CO, and free iron. Previous work indicated that electrophilic addition of the terminal oxygen of the ferric hydroperoxo complex to the alpha-meso-carbon gives 5-hydroxyheme. Earlier efforts to block this reaction with a 5-methyl substituent failed, as the reaction still gave biliverdin IXalpha. Surprisingly, a 15-methyl substituent caused exclusive cleavage at the gamma-meso-rather than at the normal, unsubstituted alpha-meso-carbon. No CO was formed in these reactions, but the fragment cleaved from the porphyrin eluded identification. We report here that hHO-1 cleaves 5-phenylheme to biliverdin IXalpha and oxidizes 15-phenylheme at the alpha-meso position to give 10-phenylbiliverdin IXalpha. The fragment extruded in the oxidation of 5-phenylheme is benzoic acid, one oxygen of which comes from O2 and the other from water. The 2.29- and 2.11-A crystal structures of the hHO-1 complexes with 1- and 15-phenylheme, respectively, show clear electron density for both the 5- and 15-phenyl rings in both molecules of the asymmetric unit. The overall structure of 15-phenylheme-hHO-1 is similar to that of heme-hHO-1 except for small changes in distal residues 141-150 and in the proximal Lys18 and Lys22. In the 5-phenylheme-hHO-1 structure, the phenyl-substituted heme occupies the same position as heme in the heme-HO-1 complex but the 5-phenyl substituent disrupts the rigid hydrophobic wall of residues Met34, Phe214, and residues 26-42 near the alpha-meso carbon. The results provide independent support for an electrophilic oxidation mechanism and support a role for stereochemical control of the reaction regiospecificity.     

Chlorination of NADH: similarities of the HOCl-supported and chloroperoxidase-catalyzed reactions

The chloroperoxidase-catalyzed reactions of NAD(P)H with H2O2 in the presence of Cl- or Br- have been characterized. With 1 mol H2O2 per mol of NADH, one atom of 36Cl was incorporated into the 264-nm-absorbing intermediate product. This species was oxidized enzymatically by a second mole of H2O2 to a species distinct from NAD+, which retained one Cl atom. Spectroscopically identical species were also produced by reaction of NADH with one and two molar ratios of HOCl, respectively. These data indicate that, with respect to halogenation activities, chloroperoxidase functions similarly to myeloperoxidase, i.e., produces HOCl as the first product of Cl- oxidation by H2O2. Moreover, rapid chlorination of NAD(P)H followed by oxidation may be an important and highly lethal microbicidal effect of HOCl produced by myeloperoxidase in activated neutrophils.     

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.     

Stopped-flow spectrophotometric analysis of intermediates in the peroxo-dependent inactivation of cytochrome P450 by aldehydes

The reaction of hydrogen peroxide and certain aromatic aldehydes with cytochrome P450BM3-F87G results in the covalent modification of the heme cofactor of this monooxygenase. Analysis of the resulting heme by electronic absorption spectrophotometry indicates that the reaction in the BM3 isoform is analogous to that in P450(2B4), which apparently occurs via a peroxyhemiacetal intermediate [Kuo et al., Biochemistry, 38 (1999) 10511]. It was observed that replacement of the Phe-87 in the P450BM3 by the smaller glycyl residue was essential for the modification to proceed, as the wild-type enzyme showed no spectral changes under identical conditions. The kinetics of this reaction were examined by stopped-flow spectrophotometry with 3-phenylpropionaldehyde and 3-phenylbutyraldehyde as reactants. In each case, the process of heme modification was biphasic, with initial bleaching of the Soret absorbance, followed by an increase in absorbance centered at 430 nm, consistent with meso-heme adduct formation. The intermediate formed during phase I also showed an increased absorbance between 700 and 900 nm, relative to the native heme and the final product. Phase I showed a linear dependence on peroxide concentration, whereas saturation kinetics were observed for phase II. All of these observations are consistent with a mechanism involving radical attack at the gamma-meso position of the heme cofactor, resulting in the intermediate formation of an isoporphyrin, the deprotonation of which produces the gamma-meso-alkyl heme derivative.     

Chemical and transient state kinetic studies on the formation and decomposition of horseradish peroxidase compounds XI and XII

Previous studies on the chlorination reaction catalyzed by horseradish peroxidase using chlorite as the source of chlorine detected the formation of a chlorinating intermediate that was termed Compound X (Shahangian, S., and Hager, L.P. (1982) J. Biol. Chem. 257, 11529-11533). These studies indicated that at pH 10.7, the optical absorption spectrum of Compound X was similar to the spectrum of horseradish peroxidase Compound II. Compound X was shown to be quite stable at alkaline pH values. This study was undertaken to examine the relationship between the oxidation state of the iron protoporphyrin IX heme prosthetic group in Compound X and the chemistry of the halogenating intermediate. The experimental results show that the optical absorption properties and the oxidation state of the heme prosthetic group in horseradish peroxidase are not directly related to the presence of the activated chlorine atom in the intermediate. The oxyferryl porphyrin heme group in alkaline Compound X can be reduced to a ferric heme species that still retains the activated chlorine atom. Furthermore, the reaction of chlorite with horseradish peroxidase at acidic pH leads to the secondary formation of a green intermediate that has the spectral properties of horseradish peroxidase Compound I (Theorell, H. (1941) Enzymologia 10, 250-252). The green intermediate also retains the activated chlorine atom. By analogy to peroxidase Compound I chemistry, the heme prosthetic group in the green chlorinating intermediate must be an oxyferryl porphyrin pi-cation radical species (Roberts, J. E., Hoffman, B. M., Rutter, R. J., and Hager, L. P. (1981) J. Am. Chem. Soc. 103, 7654-7656). To be consistent with traditional peroxidase nomenclature, the red alkaline form of Compound X has been renamed Compound XII, and the green acidic form has been named Compound XI. The transfer of chlorine from the chlorinating intermediate to an acceptor molecule follows an electrophilic (rather than a free radical) path. A mechanism for the reaction is proposed in which the activated chlorine atom is bonded to a heteroatom on an active-site amino acid side chain. Transient state kinetic studies show that the initial intermediate, Compound XII, is formed in a very fast reaction. The second-order rate constant for the formation of Compound XII is approximately 1.1 x 10(7) M-1 s-1. The rate of formation of Compound XII is strongly pH-dependent. At pH 9, the second-order rate constant for the formation of Compound XII drops to 1.5 M-1 s-1. At acidic pH values, Compound XII undergoes a spontaneous first-order decay to yield Compound XI.(ABSTRACT TRUNCATED AT 400 WORDS)     

Characterization of the enzymatic and nonenzymatic peroxidative degradation of iron porphyrins and cytochrome P-450 heme

Both purified cytochrome P-450 (P-450) and free ferriprotoporphyrin IX are destroyed by NADPH-P-450 reductase in the presence of NADPH and O2. The process appears to be mediated by H2O2 generated by reduction of O2. Six major products were identified from the reaction of H2O2 with ferri-protoporphyrin IX-hematinic acid, methylvinylmaleimide, and four dipyrrolic propentdyopents. The structures of the propentdyopents were elucidated by mass spectrometry and 1H NMR methods. Both free ferriprotoporphyrin IX and P-450 yielded these same products in similar relative ratios. P-450 heme in rat liver microsomes was degraded in the presence of O2 and NADPH and either NaN3 (a catalase inhibitor) or Fe-ADP (which promotes lipid peroxidation); the products were primarily hematinic acid, methylvinylmaleimide, and small quantities of one propentdyopent. Only the two maleimides were detected in the destruction of microsomal P-450 heme by cumene hydroperoxide and iodosylbenzene. On the basis of the reaction of H2O2 with several metal-octaethylethylporphyrin complexes and free octaethylporphyrin, the iron chelated in ferriprotoporphyrin IX is required for degradation by H2O2. Biliverdin is not an intermediate in the formation of maleimides and propentdyopents from heme. Experiments using the tetraethylpropentdyopent produced from ferrioctaethylporphyrin suggest that propentdyopents are not further cleaved to form the maleimides. A mechanism for oxidative heme destruction consistent with these observations is proposed.     

Heterologous expression of cytochrome P450 2D6 mutants, electron transfer, and catalysis of bufuralol hydroxylation: the role of aspartate 301 in structural integrity

Cytochrome P450 (P450) 2D6 is a polymorphic human enzyme involved in the oxidation of >50 drugs, most of which contain a basic nitrogen. In confirmation of previous work by others, substitutions at Asp301 decreased rates of substrate oxidation by P450 2D6. An anionic residue (Asp, Glu) at this position was found to be important in proper protein folding and heme incorporation, and positively charged residues were particularly disruptive in bacterial and also in baculovirus expression systems. Truncation of 20 N-terminal amino acids had no significant effect on catalytic activity except to attenuate P450 2D6 interaction with membranes and NADPH-P450 reductase. The truncation of the N-terminus increased the level of bacterial expression of wild-type P450 2D6 (Asp301) but markedly reduced expression of all codon 301 mutants, including Glu301. Reduction of ferric P450 2D6 by NADPH-P450 reductase was enhanced in the presence of the prototypic substrate bufuralol. Bacterial flavodoxin, an NADPH-P450 reductase homolog, binds tightly to P450 2D6 but is inefficient in electron transfer to the heme. These results collectively indicate that the acidic residue at position 301 in P450 2D6 has a structural role in addition to any in substrate binding and that the N-terminus of P450 2D6 is relatively unimportant to catalytic activity beyond a role in facilitating binding to NADPH-P450 reductase.     

Destruction of cytochrome P-450 by vinyl fluoride, fluroxene, and acetylene. Evidence for a radical intermediate in olefin oxidation

Vinyl fluoride, vinyl bromide, fluroxene (2,2,2-trifluoroethyl vinyl ether), and acetylene alkylate the prosthetic heme group of cytochrome P-450 enzymes which catalyze their metabolism. The alkylated heme moiety has been identified in all four cases, after carboxyl group methylation and demetalation, as the dimethyl easier of N-(2-oxoethyl)protoporphyrin IX. The dimethyl acetal derivative of the aldehyde group in this structure is also isolated. The formation of the same prosthetic heme adduct with the four substrates requires introduction of an oxygen at the trifluoroethoxy or halide-substituted terminus of the pi bond and reaction of the unsubstituted terminus with a heme nitrogen atom. This reaction orientation is consistent with a radical intermediate, possibly formed by way of an initial pi-bond radical cation, but is difficult to reconcile with a cationic intermediate. The occurrence of a radical intermediate in the oxidation of olefins by cytochrome P-450 is thus suggested.     

Observation of a novel transient ferryl complex with reduced CuB in cytochrome c oxidase

The reaction between mixed-valence (MV) cytochrome c oxidase from beef heart with H2O2 was investigated using the flow-flash technique with a high concentration of H2O2 (1 M) to ensure a fast bimolecular interaction with the enzyme. Under anaerobic conditions the reaction exhibits 3 apparent phases. The first phase (tau congruent with 25 micros) results from the binding of one molecule of H2O2 to reduced heme a3 and the formation of an intermediate which is heme a3 oxoferryl (Fe4+=O2-) with reduced CuB (plus water). During the second phase (tau congruent with 90 micros), the electron transfer from CuB+ to the heme oxoferryl takes place, yielding the oxidized form of cytochrome oxidase (heme a3 Fe3+ and CuB2+, plus hydroxide). During the third phase (tau congruent with 4 ms), an additional molecule of H2O2 binds to the oxidized form of the enzyme and forms compound P, similar to the product observed upon the reaction of the mixed-valence (i.e., two-electron reduced) form of the enzyme with dioxygen. Thus, within about 30 ms the reaction of the mixed-valence form of the enzyme with H2O2 yields the same compound P as does the reaction with dioxygen, as indicated by the final absorbance at 436 nm, which is the same in both cases. This experimental approach allows the investigation of the form of cytochrome c oxidase which has the heme a3 oxoferryl intermediate but with reduced CuB. This state of the enzyme cannot be obtained from the reaction with dioxygen and is potentially useful to address questions concerning the role of the redox state in CuB in the proton pumping mechanism.     

A conserved tryptophan 457 modulates the kinetics and extent of N-hydroxy-L-arginine oxidation by inducible nitric-oxide synthase

In the oxygenase domain of mouse inducible nitric-oxide synthase (iNOSoxy), a conserved tryptophan residue, Trp-457, regulates the kinetics and extent of l-Arg oxidation to N(omega)-hydroxy-l-arginine (NOHA) by controlling electron transfer between bound (6R)-tetrahydrobiopterin (H(4)B) cofactor and the enzyme heme Fe(II)O(2) intermediate (Wang, Z. Q., Wei, C. C., Ghosh, S., Meade, A. L., Hemann, C., Hille, R., and Stuehr, D. J. (2001) Biochemistry 40, 12819-12825). To investigate whether NOHA oxidation to citrulline and nitric oxide (NO) is regulated by a similar mechanism, we performed single turnover reactions with wild type iNOSoxy and mutants W457F and W457A. Ferrous proteins containing NOHA plus H(4)B or NOHA plus 7,8-dihydrobiopterin (H(2)B), were mixed with O(2)-containing buffer, and then heme spectral transitions and product formation were followed versus time. All three proteins formed a Fe(II)O(2) intermediate with identical spectral characteristics. In wild type, H(4)B increased the disappearance rate of the Fe(II)O(2) intermediate relative to H(2)B, and its disappearance was coupled to the formation of a Fe(III)NO immediate product prior to formation of ferric enzyme. In W457F and W457A, the disappearance rate of the Fe(II)O(2) intermediate was slower than in wild type and took place without detectable build-up of the heme Fe(III)NO immediate product. Rates of Fe(II)O(2) disappearance correlated with rates of citrulline formation in all three proteins, and reactions containing H(4)B formed 1.0, 0.54, and 0.38 citrulline/heme in wild type, W457F, and W457A iNOSoxy, respectively. Thus, Trp-457 modulates the kinetics of NOHA oxidation by iNOSoxy, and this is important for determining the extent of citrulline and NO formation. Our findings support a redox role for H(4)B during NOHA oxidation to NO by iNOSoxy.     

Regiospecificity determinants of human heme oxygenase: differential NADPH- and ascorbate-dependent heme cleavage by the R183E mutant

The ability of the human heme oxygenase-1 (hHO-1) R183E mutant to oxidize heme in reactions supported by either NADPH-cytochrome P450 reductase or ascorbic acid has been compared. The NADPH-dependent reaction, like that of wild-type hHO-1, yields exclusively biliverdin IXalpha. In contrast, the R183E mutant with ascorbic acid as the reductant produces biliverdin IXalpha (79 +/- 4%), IXdelta (19 +/- 3%), and a trace of IXbeta. In the presence of superoxide dismutase and catalase, the yield of biliverdin IXdelta is decreased to 8 +/- 1% with a corresponding increase in biliverdin IXalpha. Spectroscopic analysis of the NADPH-dependent reaction shows that the R183E ferric biliverdin complex accumulates, because reduction of the iron, which is required for sequential iron and biliverdin release, is impaired. Reversal of the charge at position 183 makes reduction of the iron more difficult. The crystal structure of the R183E mutant, determined in the ferric and ferrous-NO bound forms, shows that the heme primarily adopts the same orientation as in wild-type hHO-1. The structure of the Fe(II).NO complex suggests that an altered active site hydrogen bonding network supports catalysis in the R183E mutant. Furthermore, Arg-183 contributes to the regiospecificity of the wild-type enzyme, but its contribution is not critical. The results indicate that the ascorbate-dependent reaction is subject to a lower degree of regiochemical control than the NADPH-dependent reaction. Ascorbate may be able to reduce the R183E ferric and ferrous dioxygen complexes in active site conformations that cannot be reduced by NADPH-cytochrome P450 reductase.     

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.     

Resonance Raman spectra for catalytic intermediates of cytochrome c oxidase detected with a mixed flow transient apparatus

A novel technique was employed to collect resonance Raman spectra of an oxygenated intermediate of cytochrome c oxidase. Instead of laser pulses of high peak power, which may cause photodissociation, a continuous wave laser and a mixed flow apparatus were used. An intermediate formed within 450 microseconds after the reaction of cytochrome c oxidase with molecular oxygen could be detected. From the spectra it could be deduced that the most likely candidate for the intermediate would be a transient oxygenated species having the Fe2+ - O2 or Fe4+ = O heme in cytochrome a3 and the Fe2+ heme in cytochrome a.     

Inter- and intramolecular deuterium isotope effects on the cytochrome P-450-catalyzed oxidative dehalogenation of 1,1,2,2-tetrachloroethane

The oxidation of 1,1,2,2-tetrachloroethane to dichloroacetic acid was investigated with rat liver microsomes and purified cytochrome P-450. Deuterium substitution had no effect on Km values, but both the inter- and intramolecular isotope effects (kH/kD) on Vmax were in the range 5.7-6.1. The equivalence of the inter- and intramolecular values indicates that 6.0 may be a good estimate of the intrinsic isotope effect. The intermolecular kH/kD value for the conversion of 1,1,2,2-trichloroethane and its 1-2H analog to chloroacetic acid was 5.5. These data, and the finding that 1 atom of 18O was incorporated into the product when TCEA was oxidized in an 18O2 atmosphere, support an oxidative dechlorination mechanism that involves hydrogen atom abstraction by the P-450 intermediate oxo complex.