Rapid reactions of peroxynitrite with heme-thiolate proteins as the basis for protection of prostacyclin synthase from inactivation by nitration

Prostacyclin (PGI(2)) synthase is a heme-thiolate (P450) protein which reacts with low levels of peroxynitrite (PN) under tyrosine nitration and inactivation. Studying heme proteins as models, we have found the heme-thiolate protein NADH-NO reductase (P450(NOR)) to be highly efficient in decomposing PN under concomitant nitration of phenol. The present study investigates two other P450 proteins, P450(BM-3) and chloroperoxidase, in order to test for the specific role of the thiolate ligand in the reaction with PN. A comparison with horseradish peroxidase and microperoxidase gives evidence of kinetic differences that classify heme-thiolate proteins, but not other heme proteins, as effective inhibitors of PGI(2) synthase nitration and inactivation. P450(BM-3) with PN catalyzes phenol nitration and nitration of its own tyrosine below 10 microM PN, whereas chloroperoxidase and P450(NOR) at such concentrations also nitrate phenol but not enzyme-bound tyrosine residues. We conclude that heme-thiolate proteins in general exhibit high reactivity with PN and turnover, probably due to the special electronic structure of the presumed thiolate-ferryl intermediate.     

Nitration and inactivation of cytochrome P450BM-3 by peroxynitrite. Stopped-flow measurements prove ferryl intermediates.

Peroxynitrite (PN) is likely to be generated in vivo from nitric oxide and superoxide. We have previously shown that prostacyclin synthase, a heme-thiolate enzyme essential for regulation of vascular tone, is nitrated and inactivated by submicromolar concentrations of PN [Zou, M.-H. & Ullrich, V. (1996) FEBS Lett. 382, 101-104] and we have studied the effect of heme proteins on the PN-mediated nitration of phenolic compounds in model systems [Mehl, M., Daiber, A. & Ullrich, V. (1999) Nitric Oxide: Biol. Chem. 2, 259-269]. In the present work we show that bolus additions of PN or PN-generating systems, such as SIN-1, can induce the nitration of P450BM-3 (wild-type and F87Y variant), for which we suggest an autocatalytic mechanism. HPLC and MS-analysis revealed that the wild-type protein is selectively nitrated at Y334, which was found at the entrance of a water channel connected to the active site iron center. In the F87Y variant, Y87, which is directly located at the active site, was nitrated in addition to Y334. According to Western blots stained with a nitrotyrosine antibody, this nitration started at 0.5 microM of PN and was half-maximal between 100 and 150 microM of PN. Furthermore, PN caused inactivation of the P450BM-3 monooxygenase as well as the reductase activity with an IC50 value of 2-3 microM. As two thiol residues/protein molecule were oxidized by PN and the inactivation was prevented by GSH or dithiothreitol, but not by uric acid (a powerful inhibitor of the nitration), our data strongly indicate that the inactivation is due to thiol oxidation at the reductase domain rather then to nitration of Y residues. Stopped-flow data presented here support our previous hypothesis that ferryl-species are involved as intermediates during the reactions of P450 enzymes with PN.     

Peroxynitrite reaction with heme proteins.

We have reported that low levels of peroxynitrite (PN) can cause inactivation of the heme-thiolate protein prostacyclin (PGI2)-synthase by nitration of a tyrosine residue. To prove that iron catalysis is involved we studied the interaction of PN with microperoxidase and P450nor, a heme-thiolate protein of known structure. Spectral and kinetic analyses allow to conclude on a ferryl nitrogen dioxide complex as an intermediate which decomposes in the presence of an excess of PN under formation of dioxygen, nitrite, and nitrate. This occurs in a catalytic cycle which was more efficient with P450nor than with microperoxidase. If phenol was added to the reaction mixtures of PN and the ferric complexes the ratio of hydroxylated to nitrated phenols decreased compared to the metal-free system. Phenol competed with the formation of dioxygen indicating that the ferryl intermediate was involved in both pathways. One therefore can postulate that the ferryl complex reacts with phenol to give the phenoxyradical which is nitrated in the presence of nitrogen dioxide but does not give hydroxylated products as with metal-free PN. Alternately, the ferryl nitrogen dioxide complex can oxidize a second PN molecule to the radical, *OONO, which can decompose to dioxygen and NO. The latter forms N2O3, with the remaining *NO2 radical. A third pathway consists in the isomerization to nitrate which also is catalyzed by the heme proteins since the ratio of nitrite/nitrate does not change significantly during the catalytic reaction with excess of PN. Our data explain the mechanism of nitration of PGI2-synthase, suggest a role of P450nor as a PN scavenger, and favor heme-thiolate complexes for trapping PN.     

The impact of metal catalysis on protein tyrosine nitration by peroxynitrite

In a series of heme and non-heme proteins the nitration of tyrosine residues was assessed by complete pronase digestion and subsequent HPLC-based separation of 3-nitrotyrosine. Bolus addition of peroxynitrite caused comparable nitration levels in all tested proteins. Nitration mainly depended on the total amount of tyrosine residues as well as on surface exposition. In contrast, when superoxide and nitrogen monoxide (NO) were generated at equal rates to yield low steady-state concentrations of peroxynitrite, metal catalysis seemed to play a dominant role in determining the sensitivity and selectivity of peroxynitrite-mediated tyrosine nitration in proteins. Especially, the heme-thiolate containing proteins cytochrome P450(BM-3) (wild type and F87Y variant) and prostacyclin synthase were nitrated with high efficacy. Nitration by co-generated NO/O(2)(-) was inhibited in the presence of superoxide dismutase. The NO source alone only yielded background nitration levels. Upon changing the NO/O(2)(-) ratio to an excess of NO, a decrease in nitration in agreement with trapping of peroxynitrite and derived radicals by NO was observed. These results clearly identify peroxynitrite as the nitrating species even at low steady-state concentrations and demonstrate that metal catalysis plays an important role in nitration of protein-bound tyrosine.     

Redox regulation of vascular prostanoid synthesis by the nitric oxide-superoxide system

Oxygen is involved in cell signaling through oxygenases and oxidases and this applies especially for the vascular system. Nitric oxide (*NO) and epoxyarachidonic acids are P450-dependent monooxygenase products and prostacyclin is formed via cyclooxygenase and a heme-thiolate isomerase. The corresponding vasorelaxant mechanisms are counteracted by superoxide which not only traps *NO but through the resulting peroxynitrite blocks prostacyclin synthase by nitration of an active site tyrosine residue. In a model of septic shock, this leads to vessel constriction by activation of the thromboxane A2-prostaglandin endoperoxide H2 receptor. This sequence of events is part of endothelial dysfunction in which the activated vascular smooth muscle counteracts and regenerates vessel tone by cyclooxygenase-2-dependent prostacyclin synthesis. Peroxynitrite was found to activate cyclooxygenases by providing the peroxide tone at nanomolar concentrations. Such new insights into the control of vascular function have allowed us to postulate a concept of redox regulation in which a progressive increase of superoxide production by NADPH-oxidase, mitochondria, xanthine oxidase, and even uncoupled NO-synthase triggers a network of signals originating from an interaction of *NO with superoxide.     

Thoughts on thiolate tethering. Tribute and thanks to a teacher

A unique feature of P450 enzymes is in the presence of a thiolate ligand heme but its exact function in catalysis is a matter of debate. For P450 dependent monooxygenases the "active oxygen" complex seems to exist only as a transition state in which the thiolate ligand provides electron density in order to prevent pi-backbonding of the oxygen to the iron (-S-Fe-O(z.rad;)). The corresponding ground state (Compound I) would be a ferryl species (Fe(IV)z.dbnd6;O) with an electron hole either at the porphyrin or at the sulfur. Apart from this role we postulate that a second function is related to the electronic structure of Compound II as an electron acceptor and this property is shared among monooxygenases, thromboxane synthase, prostacyclin synthase, allene oxide synthase, P450(NOR(-)) and chloroperoxidase. As a common step in all P450 enzymes an extremely rapid electron uptake by Compound II allows that the primary substrate radicals are oxidized to cations which immediately combine with a neighbouring nucleophile. Thus "electron transfer" may substitute for "oxygen rebound" as the final step leading to product formation. The same principle also applies methane monooxygenases in which the role of the thiyl sulfur is replaced by a ferryl-oxyl entity.     

Heme-thiolate proteins

Cytochrome P450 was the first hemoprotein found to have a thiolate anion as the axial ligand of the heme. Several other heme-thiolate proteins, including nitric oxide synthase, were later found in animals, plants, and microorganisms. Both cytochrome P450 and nitric oxide synthase, two major members of the heme-thiolate protein family, catalyze monooxygenase reactions, but the physiological functions of other heme-thiolate proteins are apparently highly diverse. Chloroperoxidase of a mold, Caldaryomyces fumago, catalyzes a haloperoxidase reaction. CooA of a bacterium, Rhodospirillum rubrum, and heme-regulated eIF2α kinase of animals function as the sensors for carbon monoxide and nitric oxide, respectively, to elicit biological responses to these gases. The role of heme in the enzymatic activity of cystathionine β-synthase is still unknown. It is likely that more heme-thiolate proteins with diversified functions will be found in various organisms in the future.     

Phorbol ester mediated activation of inducible nitric oxide synthase results in platelet profilin nitration.

Nitric oxide is an important precursor for peroxynitrite production under in vivo conditions leading to cell injury and cell death. In platelets, a number of cytosolic and actin binding proteins were shown to be nitrated [K.M. Naseem, S.Y. Low, M. Sabetkar, N.J. Bradley, J. Khan, M. Jacobs, K.R. Bruckdorfer, The nitration of platelet cytosolic proteins during agonist-induced activation of platelets. FEBS Lett. 473 (1) (2000) 199-122 and M. Sabetkar, S.Y. Low, K.M. Naseem, K.R. Bruckdorfer, The nitration of proteins in platelets: significance in platelet function, Free Radic. Biol. Med. 33 (6) (2002) 728-736]. We investigated the possible mechanism that regulates profilin (an actin binding protein) nitration in platelets. Activation of bovine platelets with arachidonic acid, thrombin, and phorbol 12,13-dibutyrate resulted in nitration of profilin on tyrosine residue. In vivo profilin nitration showed a four- and eight-fold increase in the presence of thrombin and phorbol 12,13-dibutyrate, respectively. Analysis of nitroprofilin levels in the presence of NOS inhibitors (1400W and EGTA), indicated that profilin nitration in phorbol 12,13-dibutyrate treated platelets is mediated by inducible nitric oxide synthase. Phorbol ester treated platelets exhibited higher levels by inducible nitric oxide synthase (491% over control), while total nitric oxide synthase activity increased by 5% over control. Higher levels of peroxynitrite in platelets treated with phorbol 12,13-dibutyrate indicated that profilin nitration is mediated by peroxynitrite. Increase in phosphatidylinositol 3-kinase (PI 3-kinase) activity in platelets treated with thrombin and phorbol 12,13-dibutyrate indicates that nitration of platelet profilin could be mediated by PI 3-kinase. A decrease in the level of nitroprofilin in PDBu treated platelets in the presence of inducible nitric oxide synthase inhibitor, 1400W, was observed suggesting that profilin nitration is mediated by PI 3-kinase dependent activation of inducible nitric oxide synthase.     

Specific nitration at tyrosine 430 revealed by high resolution mass spectrometry as basis for redox regulation of bovine prostacyclin synthase

Treatment of bovine aortic microsomes containing active prostacyclin synthase (PGI(2) synthase) with increasing concentrations of peroxynitrite (PN) up to 250 microm of PN yielded specific staining of this enzyme on Western blots with antibodies against 3-nitrotyrosine (3-NT), whereas above 500 microm PN staining of additional proteins was also observed. Following treatment of aortic microsomes with 25 microm PN, PGI(2) synthase was about half-maximally nitrated and about half-inhibited. It was then isolated by gel electrophoresis and subjected to proteolytic digestion with several proteases. Digestion with thermolysin for 24 h provided a single specific peptide that was isolated by high performance liquid chromatography and identified as a tetrapeptide Leu-Lys-Asn-Tyr(3-nitro)-COOH corresponding to positions 427-430 of PGI(2) synthase. Its structure was established by precise mass determination using Fourier transform-ion cyclotron resonance-nanoelectrospray mass spectrometry and Edman microsequencing and ascertained by synthesis and mass spectrometric characterization of the authentic Tyr-nitrated peptide. Complete digestion by Pronase to 3-nitrotyrosine was obtained only after 72 h, suggesting that the nitrated Tyr-430 residue may be embedded in a tight fold around the heme binding site. These results provide evidence for the specific inhibition of PGI(2) synthase by nitration at Tyr-430 that may occur already at low levels of PN as a consequence of endothelial co-generation of nitric oxide and superoxide.     

Nitric oxide reductase (P450nor) from Fusarium oxysporum

In the present review we wanted to highlight the characteristic features of cytochtome P450 NADH-NO reductase (P450nor) from Fusarium oxysporum which belongs to the heme-thiolate protein family. This enzyme catalyzes the reduction of two NO molecules to N2O. The discovery, isolation, identification and crystallography are described in detail. Special emphasis was focused on the mechanism of NO reduction and possible electronic configurations of the 444 nm intermediate were discussed. Among heme-thiolate proteins nitric oxide reductase (P450nor) is unique since it catalyzes the conversion to dinitrogen oxide as a reductive process. However, it joins the typical physical characteristics of other P450 proteins including the ferric NO complex which can be considered as the enzyme-substrate complex of the enzyme. At a closer look some of its properties like a tilted structure and a shorter Fe-N distance indicate properties for a facilitated hydride transfer from NADH. The resulting intermediate forms the product in a subsequent reaction with the NO radical. For this rate-limiting step at physiological NO levels electron transfer is postulated as a common feature with other heme-thiolate mechanisms. P450nor seems to have an important role in protecting the fungus from NO inhibition of mitochondria especially when dioxygen becomes limiting.     

Nitration of cytoskeletal proteins in the chicken embryo chorioallantoic membrane

Protein tyrosine nitration is one of the post-translational modifications that alter the biological function of proteins. Two important mechanisms are involved: peroxynitrite formation and myeloperoxidase or eosinophil peroxidase (EPO) activity. In the present work we studied the nitration of proteins in the in vivo system of chicken embryo chorioallantoic membrane (CAM). 3-Nitrotyrosine was detected only in the insoluble fraction of the CAM homogenate. By immunoprecipitation, Western blot analysis, and double immunofluorescence, we identified two major polypeptides that were nitrated: actin and alpha-tubulin. Quantification of actin and alpha-tubulin nitration revealed that they are differentially nitrated during normal development of the chicken embryo CAM. After irradiation, although they were both increased, they required different time periods to return to the physiological levels of nitration. It seems that both peroxynitrite formation and EPO activity are involved in the in vivo tyrosine nitration of cytoskeletal proteins. These data suggest that tyrosine nitration of cytoskeletal proteins has a physiological role in vivo, which depends on the protein involved and is differentially regulated.     

Factors determining the selectivity of protein tyrosine nitration.

Tyrosine nitration is a covalent posttranslational protein modification derived from the reaction of proteins with nitrating agents. Protein nitration appears to be a selective process since not all tyrosine residues in proteins or all proteins are nitrated in vivo. To investigate factors that may determine the biological selectivity of protein tyrosine nitration, we developed an in vitro model consisting of three proteins with similar size but different three-dimensional structure and tyrosine content. Exposure of ribonuclease A to putative in vivo nitrating agents revealed preferential nitration of tyrosine residue Y(115). Tyrosine residue Y(23) and to a lesser extent residue Y(20) were preferentially nitrated in lysozyme, whereas tyrosine Y(102) was the only residue modified by nitration in phospholipase A(2). Tyrosine Y(115) was the residue modified by nitration after exposure of ribonuclease A to different nitrating agents: chemically synthesized peroxynitrite, nitric oxide, and superoxide generated by SIN-1 or myeloperoxidase (MPO)/H(2)O(2) plus nitrite (NO(-2)) in the presence of bicarbonate/CO(2). The nature of the nitrating agent determined in part the protein that would be predominantly modified by nitration in a mixture of all three proteins. Ribonuclease A was preferentially nitrated upon exposure to MPO/H(2)O(2)/NO(-2), whereas phospholipase A(2) was the primary target for nitration upon exposure to peroxynitrite. The data also suggest that the exposure of the aromatic ring to the surface of the protein, the location of the tyrosine on a loop structure, and its association with a neighboring negative charge are some of the factors determining the selectivity of tyrosine nitration in proteins.     

Epitope motif of an anti‐nitrotyrosine antibody specific for tyrosine‐nitrated peptides revealed by a combination of affinity approaches and mass spectrometry

Nitration of tyrosine residues has been shown to be an important oxidative modification in proteins and has been suggested to play a role in several diseases such as atherosclerosis, asthma, lung and neurodegenerative diseases. Detection of nitrated proteins has been mainly based on the use of nitrotyrosine‐specific antibodies. In contrast, only a small number of nitration sites in proteins have been unequivocally identified by MS. We have used a monoclonal 3‐NT‐specific antibody, and have synthesized a series of tyrosine‐nitrated peptides of prostacyclin synthase (PCS) in which a single specific nitration site at Tyr‐430 had been previously identified upon reaction with peroxynitrite 17 . The determination of antibody‐binding affinity and specificity of PCS peptides nitrated at different tyrosine residues (Tyr‐430, Tyr‐421, Tyr‐83) and sequence mutations around the nitration sites provided the identification of an epitope motif containing positively charged amino acids (Lys and/or Arg) N‐terminal to the nitration site. The highest affinity to the anti‐3NT‐antibody was found for the PCS peptide comprising the Tyr‐430 nitration site with a K_D of 60 nM determined for the peptide, PCS(424‐436‐Tyr‐430NO₂); in contrast, PCS peptides nitrated at Tyr‐421 and Tyr‐83 had substantially lower affinity. ELISA, SAW bioaffinity, proteolytic digestion of antibody‐bound peptides and affinity‐MS analysis revealed highest affinity to the antibody for tyrosine‐nitrated peptides that contained positively charged amino acids in the N‐terminal sequence to the nitration site. Remarkably, similar N‐terminal sequences of tyrosine‐nitration sites have been recently identified in nitrated physiological proteins, such as eosinophil peroxidase and eosinophil‐cationic protein. Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.     

Rapid kinetics investigations of peracid oxidation of ferric cytochrome P450cam: nature and possible function of compound ES

Previously, we reported spectroscopic properties of cytochrome P450cam compound I, (ferryl iron plus a porphyrin π-cation radical (Fe^IV = O/Por⁺)), as well as compound ES (Fe^IV = O/Tyr) in reactions of substrate-free ferric enzyme with m-chloroperbenzoic acid [T. Spolitak, J.H. Dawson, D.P. Ballou, J. Biol. Chem. 280 (2005) 20300-9]. Compound ES arises by intramolecular electron transfer from nearby tyrosines to the porphyrin π-cation radical of Compound I, and has been characterized by rapid-freeze-quench-Mössbauer/EPR spectroscopy; the tyrosyl radical was assigned to Tyr96 for wild type or to Tyr75 for the Tyr96Phe variant [V. Schünemann, F. Lendzian, C. Jung, J. Contzen, A.L. Barra, S.G. Sligar, A.X. Trautwein, J. Biol. Chem. 279 (2004) 10919–10930]. Here we report rapid-scanning stopped-flow studies of the reactions of peracids with substrate-free ferric Y75F, Y96F, and Y96F/Y75F P450cam variants, showing how these active site changes influence electron transfer from nearby tyrosines and affect formation of intermediates. Curiously, rates of generation of Compounds I and ES for both single mutants were not very different from wild type. Contrasting with the earlier EPR results, the Y96F/Y75F variant was also shown to form an ES-like species, but more slowly. When substrate is not present, or is improperly bound, compound I rapidly converts to compound ES, which can be reduced to form H₂O and ferric P450, thus avoiding the modification of nearby protein groups or release of reactive oxygen species.     

In vivo protein tyrosine nitration in Arabidopsis thaliana

Nitration of tyrosine (Y) residues of proteins is a low abundant post-translational modification that modulates protein function or fate in animal systems. However, very little is known about the in vivo prevalence of this modification and its corresponding targets in plants. Immunoprecipitation, based on an anti-3-nitroY antibody, was performed to pull-down potential in vivo targets of Y nitration in the Arabidopsis thaliana proteome. Further shotgun liquid chromatography-mass spectrometry (LC-MS/MS) proteomic analysis of the immunoprecipitated proteins allowed the identification of 127 proteins. Around 35% of them corresponded to homologues of proteins that have been previously reported to be Y nitrated in other non-plant organisms. Some of the putative in vivo Y-nitrated proteins were further confirmed by western blot with specific antibodies. Furthermore, MALDI-TOF (matrix-assisted laser desorption ionization-time of flight) analysis of protein spots, separated by two-dimensional electrophoresis from immunoprecipitated proteins, led to the identification of seven nitrated peptides corresponding to six different proteins. However, in vivo nitration sites among putative targets could not be identified by MS/MS. Nevertheless, an MS/MS spectrum with 3-aminoY318 instead of the expected 3-nitroY was found for cytosolic glyceraldehyde-3-phosphate dehydrogenase. Reduction of nitroY to aminoY during MS-based proteomic analysis together with the in vivo low abundance of these modifications made the identification of nitration sites difficult. In turn, in vitro nitration of methionine synthase, which was also found in the shotgun proteomic screening, allowed unequivocal identification of a nitration site at Y287.     

Nitric-oxide synthase: a cytochrome P450 family foster child

Nitric-oxide synthase (NOS), the enzyme responsible for mammalian NO generation, is no cytochrome P450, but there are striking similarities between both enzymes. First and foremost, both are heme-thiolate proteins, employing the same prosthetic group to perform similar chemistry. Moreover, they share the same redox partner, a diflavoprotein reductase, which in the case of NOS is incorporated with the oxygenase in one polypeptide chain. There are, however, also conspicuous differences, such as the presence in NOS of the additional cofactor tetrahydrobiopterin, which is applied as an auxiliary electron donor to prevent decay of the oxyferrous complex to ferric heme and superoxide. In this review similarities and differences between NOS and cytochrome P450 are analyzed in an attempt to explain why NOS requires BH4 and why NO synthesis is not catalyzed by a member of the cytochrome P450 family.     

Engineering cytochrome c peroxidase into cytochrome P450: a proximal effect on heme-thiolate ligation.

In an effort to investigate factors required to stabilize heme-thiolate ligation, key structural components necessary to convert cytochrome c peroxidase (CcP) into a thiolate-ligated cytochrome P450-like enzyme have been evaluated and the H175C/D235L CcP double mutant has been engineered. The UV-visible absorption, magnetic circular dichroism (MCD) and electron paramagnetic resonance (EPR) spectra for the double mutant at pH 8.0 are reported herein. The close similarity between the spectra of ferric substrate-bound cytochrome P450cam and those of the exogenous ligand-free ferric state of the double mutant with all three techniques support the conclusion that the latter has a pentacoordinate, high-spin heme with thiolate ligation. Previous efforts to prepare a thiolate-ligated mutant of CcP with the H175C single mutant led to Cys oxidation to cysteic acid [Choudhury et al. (1994) J. Biol. Chem. 267, 25656-25659]. Therefore it is concluded that changing the proximal Asp235 residue to Leu is critical in forming a stable heme-thiolate ligation in the resting state of the enzyme. To further probe the versatility of the CcP double mutant as a ferric P450 model, hexacoordinate low-spin complexes have also been prepared. Addition of the neutral ligand imidazole or of the anionic ligand cyanide results in formation of hexacoordinate adducts that retain thiolate ligation as determined by spectral comparison to the analogous derivatives of ferric P450cam. The stability of these complexes and their similarity to the analogous forms of P450cam illustrates the potential of the H175C/D235L CcP double mutant as a model for ferric P450 enzymes. This study marks the first time a stable cyanoferric complex of a model P450 has been made and demonstrates the importance of the environment around the primary coordination ligands in stabilizing metal-ligand ligation.     

Peroxynitrite-induced nitration of tyrosine hydroxylase: identification of tyrosines 423, 428, and 432 as sites of modification by matrix-assisted laser desorption ionization time-of-flight mass spectrometry and tyrosine-scanning mutagenesis

Tyrosine hydroxylase (TH), the initial and rate-limiting enzyme in the biosynthesis of the neurotransmitter dopamine, is inactivated by peroxynitrite. The sites of peroxynitrite-induced tyrosine nitration in TH have been identified by matrix-assisted laser desorption time-of-flight mass spectrometry and tyrosine-scanning mutagenesis. V8 proteolytic fragments of nitrated TH were analyzed by matrix-assisted laser desorption time-of-flight mass spectrometry. A peptide of 3135.4 daltons, corresponding to residues V410-E436 of TH, showed peroxynitrite-induced mass shifts of +45, +90, and +135 daltons, reflecting nitration of one, two, or three tyrosines, respectively. These modifications were not evident in untreated TH. The tyrosine residues (positions 423, 428, and 432) within this peptide were mutated to phenylalanine to confirm the site(s) of nitration and assess the effects of mutation on TH activity. Single mutants expressed wild-type levels of TH catalytic activity and were inactivated by peroxynitrite while showing reduced (30-60%) levels of nitration. The double mutants Y423F,Y428F, Y423F,Y432F, and Y428F,Y432F showed trace amounts of tyrosine nitration (7-30% of control) after exposure to peroxynitrite, and the triple mutant Y423F,Y428F,Y432F was not a substrate for nitration, yet peroxynitrite significantly reduced the activity of each. When all tyrosine mutants were probed with PEO-maleimide activated biotin, a thiol-reactive reagent that specifically labels reduced cysteine residues in proteins, it was evident that peroxynitrite resulted in cysteine oxidation. These studies identify residues Tyr(423), Tyr(428), and Tyr(432) as the sites of peroxynitrite-induced nitration in TH. No single tyrosine residue appears to be critical for TH catalytic function, and tyrosine nitration is neither necessary nor sufficient for peroxynitrite-induced inactivation. The loss of TH catalytic activity caused by peroxynitrite is associated instead with oxidation of cysteine residues.     

Eosinophils are a major source of nitric oxide-derived oxidants in severe asthma: characterization of pathways available to eosinophils for generating reactive nitrogen species

Eosinophil recruitment and enhanced production of NO are characteristic features of asthma. However, neither the ability of eosinophils to generate NO-derived oxidants nor their role in nitration of targets during asthma is established. Using gas chromatography-mass spectrometry we demonstrate a 10-fold increase in 3-nitrotyrosine (NO(2)Y) content, a global marker of protein modification by reactive nitrogen species, in proteins recovered from bronchoalveolar lavage of severe asthmatic patients (480 +/- 198 micromol/mol tyrosine; n = 11) compared with nonasthmatic subjects (52.5 +/- 40.7 micromol/mol tyrosine; n = 12). Parallel gas chromatography-mass spectrometry analyses of bronchoalveolar lavage proteins for 3-bromotyrosine (BrY) and 3-chlorotyrosine (ClY), selective markers of eosinophil peroxidase (EPO)- and myeloperoxidase-catalyzed oxidation, respectively, demonstrated a dramatic preferential formation of BrY in asthmatic (1093 +/- 457 micromol BrY/mol tyrosine; 161 +/- 88 micromol ClY/mol tyrosine; n = 11 each) compared with nonasthmatic subjects (13 +/- 14.5 micromol BrY/mol tyrosine; 65 +/- 69 micromol ClY/mol tyrosine; n = 12 each). Bronchial tissue from individuals who died of asthma demonstrated the most intense anti-NO(2)Y immunostaining in epitopes that colocalized with eosinophils. Although eosinophils from normal subjects failed to generate detectable levels of NO, NO(2-), NO(3-), or NO(2)Y, tyrosine nitration was promoted by eosinophils activated either in the presence of physiological levels of NO(2-) or an exogenous NO source. At low, but not high (e.g., >2 microM/min), rates of NO flux, EPO inhibitors and catalase markedly attenuated aromatic nitration. These results identify eosinophils as a major source of oxidants during asthma. They also demonstrate that eosinophils use distinct mechanisms for generating NO-derived oxidants and identify EPO as an enzymatic source of nitrating intermediates in eosinophils.     

Formation of transient oxygen complexes of cytochrome p450 BM3 and nitric oxide synthase under high pressure

The kinetics of formation and transformation of oxygen complexes of two heme-thiolate proteins (the F393H mutant of cytochrome P450 BM3 and the oxygenase domain of endothelial nitric oxide synthase, eNOS) were studied under high pressure. For BM3, oxygen-binding characteristics (rate and activation volume) matched those measured for CO-binding. In contrast, pressure revealed a different CO- and oxygen-binding mechanism for eNOS, suggesting that it is hazardous to take CO-binding as a model for oxygen-binding. With eNOS, a ferric NO complex is formed as an intermediate in the second reaction cycle. Here we report the pressure stability of this compound. Furthermore, in the presence of 4-amino-tetrahydrobiopterin (ABH(4)), an analog to the natural second electron donor tetrahydrobiopterin (BH(4)), biphasic pressure profiles of the oxygen-binding rates were observed, both in the first and the second reaction cycles, indicative of the formation of an additional reaction intermediate. This was confirmed by experiments where ABH(4) was replaced by ABH(2), a cofactor which cannot deliver an electron. Altogether, high pressure appears to be a useful tool to characterize elementary steps in the reaction cycle of heme-thiolate proteins.