Responses to peroxynitrite in yeast: glyceraldehyde-3-phosphate dehydrogenase (GAPDH) as a sensitive intracellular target for nitration and enhancement of chaperone expression and ubiquitination

Peroxynitrite (ONOO-), a potent oxidizing and nitrating species, has been linked to covalent modifications of biomolecules in a number of pathological conditions. In S. cerevisiae, a model eukaryotic cell system, ONOO- was found to be more potent than hydrogen peroxide in oxidizing thiols, inducing heat shock proteins (Hsp70) and enhancing the ubiquitination of proteins. As identified by microsequence analysis following immunoprecipitation with anti-nitrotyrosine antibodies, glyceraldehyde-3-phosphate dehydrogenase (GAPDH) was especially susceptible to nitration by ONOO- in yeast cells. The activity of this enzyme was strongly inhibited upon steady-state exposure of the cells to low doses of ONOO- in yeast and in cultured rat astrocytes. Thus, ONOO- is a potent stressor in yeast capable of inducing oxidative damage and protein nitration, with GAPDH being a preferential target protein that is efficiently inactivated.     

Peroxynitrite and protein tyrosine nitration of prostacyclin synthase

When working on the regulation of prostacyclin synthase (PGIS), we found that PGIS was selectively inhibited by peroxynitrite (ONOO-), a potent oxidant formed by the combination of superoxide anion and nitric oxide (NO) at a rate of diffusion-controlled. None of the cellular antioxidants studied (i.e. GSH, Vitamins C and E, and others) prevented the inhibition of ONOO- on PGIS. This unexpected behavior was explained by a catalytic reaction of the iron-thiolate center of PGIS with ONOO- anion. In contrast, ONOO- activated both thromboxane A2-synthase and cyclooxygenases. In addition, we demonstrated that sub-micromolar levels of ONOO- inhibited PGI2-dependent vasorelaxation and triggered a PGH2-dependent vasospasm, indicating that ONOO- increased PGH2 formation as a consequence of PGIS nitration. We have subsequently demonstrated that endogenous ONOO- caused PGIS nitration and TxA2 activation in several diseased conditions such as atherosclerotic vessels, hypoxia-reperfusion injury, cytokines-treated cells, diabetes, as well as hypertension. Since NO is produced physiologically it seems that excessive formation of superoxide not only eliminates the vasodilatory, growth-inhibiting, anti-thrombotic and anti-adhesive effects of NO and PGI2 but also allows and promotes an action of the potent vasoconstrictor, prothrombotic agent, growth promoter, and leukocyte adherer, PGH2. We conclude that the nitration of PGIS nitration might be a new pathogenic mechanism for superoxide-induced endothelium dysfunction often observed in vascular diseases such as atherosclerosis, hypertension, ischemia, endotoxic shock, and diabetes.     

Tyrosine modifications and inactivation of active site manganese superoxide dismutase mutant (Y34F) by peroxynitrite.

Recent studies from this laboratory have demonstrated that human manganese superoxide dismutase (MnSOD) is a target for tyrosine nitration in several chronic inflammatory diseases including chronic organ rejection, arthritis, and tumorigenesis. Furthermore, we demonstrated that peroxynitrite (ONOO-) is the only known biological oxidant competent to inactivate enzymatic activity, nitrate critical tyrosine residues, and induce dityrosine formation in MnSOD. To elucidate the differential contributions of tyrosine nitration and oxidation during enzymatic inactivation, we now compare ONOO- treatment of native recombinant human MnSOD (WT-MnSOD) and a mutant, Y34F-MnSOD, in which tyrosine 34 (the residue most susceptible to ONOO--mediated nitration) was mutated to phenylalanine. Both WT-MnSOD (IC50 = 65 microM, 15 microM MnSOD) and Y34F-MnSOD (IC50 = 55 microM, 15 microM Y34F) displayed similar dose-dependent sensitivity to ONOO--mediated inactivation. Compared to WT-MnSOD, the Y34F-MnSOD mutant demonstrated significantly less efficient tyrosine nitration and enhanced formation of dityrosine following treatment with ONOO-. Collectively, these results suggest that complete inactivation of MnSOD by ONOO- can occur independent of the active site tyrosine residue and includes not only nitration of critical tyrosine residues but also tyrosine oxidation and subsequent formation of dityrosine.     

Reactions of peroxynitrite in the mitochondrial matrix

Superoxide radical (O2-) and nitric oxide (NO) produced at the mitochondrial inner membrane react to form peroxynitrite (ONOO-) in the mitochondrial matrix. Intramitochondrial ONOO- effectively reacts with a few biomolecules according to reaction constants and intramitochondrial concentrations. The second-order reaction constants (in M(-1) s(-1)) of ONOO- with NADH (233 +/- 27), ubiquinol-0 (485 +/- 54) and GSH (183 +/- 12) were determined fluorometrically by a simple competition assay of product formation. The oxidation of the components of the mitochondrial matrix by ONOO- was also followed in the presence of CO2, to assess the reactivity of the nitrosoperoxocarboxylate adduct (ONOOCO2-) towards the same reductants. The ratio of product formation was about similar both in the presence of 2.5 mM CO2 and in air-equilibrated conditions. Liver submitochondrial particles supplemented with 0.25-2 microM ONOO- showed a O2- production that indicated ubisemiquinone formation and autooxidation. The nitration of mitochondrial proteins produced after addition of 200 microM ONOO- was observed by Western blot analysis. Protein nitration was prevented by the addition of 50-200 microM ubiquinol-0 or GSH. An intramitochondrial steady state concentration of about 2 nM ONOO- was calculated, taking into account the rate constants and concentrations of ONOO- coreactants.     

Peroxynitrite inhibits myofibrillar protein function in an in vitro assay of motility

We determined the effects of peroxynitrite (ONOO-) on cardiac myosin, actin, and thin filaments in order to more clearly understand the impact of this reactive compound in ischemia/reperfusion injury and heart failure. Actin filaments, native thin filaments, and alpha-cardiac myosin from rat hearts were exposed to ONOO- in the presence of 2 mM bicarbonate. Filament velocities over myosin, calcium sensitivity, and relative force generated by myosin were assessed in an in vitro motility assay in the absence of reducing agents. ONOO- concentrations > or =10 microM significantly reduced the velocities of thin filaments or bare actin filaments over alpha-cardiac myosin when any of these proteins were exposed individually. These functional deficits were linearly related to the degree of tyrosine nitration, with myosin being the most sensitive. However, at 10 microM ONOO- the calcium sensitivity of thin filaments remained unchanged. Cotreatment of myosin and thin filaments, analogous to the in vivo situation, resulted in a significantly greater functional deficit. The load supported by myosin after ONOO- exposure was estimated using mixtures experiments to be increased threefold. These data suggest that nitration of myofibrillar proteins can contribute to cardiac contractile dysfunction in pathologic states in which ONOO- is liberated.     

Reduction of insulin-stimulated glucose uptake by peroxynitrite is concurrent with tyrosine nitration of insulin receptor substrate-1

Inducible nitric oxide synthetase plays an essential role in insulin resistance induced by a high-fat diet. The reaction of nitric oxide with superoxide leads to the formation of peroxynitrite (ONOO-), which can modify several proteins. In this study, we investigated whether peroxynitrite impairs insulin-signalling pathway. Our experiments showed that 3-(4-morpholinyl)sydnonimine hydrochloride (SIN-1), a constitutive producer of peroxynitrite, dose-dependently inhibited insulin-stimulated glucose uptake. While SIN-1 did not affect the insulin receptor protein level and tyrosine phosphorylation, it reduced the insulin receptor substrate-1 (IRS-1) protein level, and IRS-1 associated phosphatidylinositol-3 kinase (PI-3 kinase) activity. Although SIN-1 did not induce Ser307 phosphorylation of IRS-1, tyrosine nitration of IRS-1 was detected in SIN-1-treated-Rat1 fibroblasts expressing human insulin receptors. Mass spectrometry showed that peroxynitrite induced at least four nitrated tyrosine residues in rat IRS-1, including Tyr939, which is critical for association of IRS-1 with the p85 subunit of PI-3 kinase. Our results suggest that peroxynitrite reduces the IRS-1 protein level and decreases phosphorylation of IRS-1 concurrent with nitration of its tyrosine residues.     

Site-specific nitration and oxidative dityrosine bridging of the tau protein by peroxynitrite: implications for Alzheimer's disease

Alzheimer's disease (AD) is a progressive amnestic disorder typified by the pathological misfolding and deposition of the microtubule-associated tau protein into neurofibrillary tangles (NFTs). While numerous post-translational modifications influence NFT formation, the molecular mechanisms responsible for tau aggregation remain enigmatic. Since nitrative and oxidative injury have previously been shown to play a mechanistic role in neurodegeneration, we examined whether these events influence tau aggregation. In this report, we characterize the effects of peroxynitrite (ONOO-)-mediated nitration and oxidation on tau polymerization in vitro. Treatment of tau with ONOO- results in 3-nitrotyrosine (3-NT) immunoreactivity and the formation of heat-stable, SDS-insoluble oligomers. Using ESI-MS and HPLC with fluorescent detection, we show that these higher-order aggregates contain 3,3'-dityrosine (3,3'-DT). Tyrosine (Tyr) residues are critical for ONOO(-)-mediated oligomerization, as tau proteins lacking all Tyr residues fail to generate oligomers upon ONOO- treatment. Further, tau nitration targets residues Y18, Y29, and to a lesser degree Y197 and Y394, and nitration at these sites inhibits in vitro polymerization. The inhibitory effect of nitration on tau polymerization is specific for the 3-NT modification, as pseudophosphorylation at these same Tyr residues does not inhibit tau assembly. Our results suggest that the nitrative and oxidative roles of ONOO- differentially affect tau polymerization and that ONOO(-)-mediated cross-linking could facilitate tau aggregation in AD.     

Reprint of "oxidative alterations of cyclooxygenase during atherogenesis" [Prostag. Oth. Lipid. M. 80 (2006) 1-14

Nitric oxide (*NO) and eicosanoids are critical mediators of physiological and pathophysiological processes. They include inflammation and atherosclerosis. *NO production and eicosanoid synthesis become disrupted during atherosclerosis and thus, it is important to understand the mechanisms that may contribute to this outcome. We, and others, have shown that nitrogen oxide (NOx) species modulate cyclooxygenase (COX; also known as prostaglandin H2 synthase) activity and alter eicosanoid production. We have determined that peroxynitrite (ONOO-) has multiple effects on COX activity. ONOO- can provide the peroxide tone necessary for COX activation, such that simultaneous exposure of COX to its arachidonic acid substrate and ONOO- results in increased eicosanoid production. Alternatively, in the absence of arachidonic acid, ONOO- can modify COX through nitration of an essential tyrosine residue (Tyr385) such that it is incapable of catalysis. In this regard, we have shown that COX nitration occurs in human atherosclerotic tissue and in aortic lesions from ApoE-/- mice kept on a high fat diet. Additionally, we have demonstrated that Tyr nitration in ApoE-/- mice is dependent on the inducible form of NO synthase (iNOS). Under conditions where ONOO- persists and arachidonic acid is not immediately available, the cell may try to correct the situation by responding to ONOO- and releasing arachidonic acid via a signaling pathway to favor COX activation. Other post-translational modifications of COX by NOx species include S-nitrosation of cysteine (Cys) residues (which may have an activating effect) and Cys oxidation. The central focus of this review will include a discussion of how NOx species alter COX activity at the molecular level and how these modifications may contribute to altered eicosanoid output during atherosclerosis and lesion development.     

Peroxynitrite inhibits enterocyte proliferation and modulates Src kinase activity in vitro

Overproduction of nitric oxide (NO) or its toxic metabolite, peroxynitrite (ONOO-), after endotoxemia promotes gut barrier failure, in part, by inducing enterocyte apoptosis. We hypothesized that ONOO- may also inhibit enterocyte proliferation by disrupting the Src tyrosine kinase signaling pathway, thereby blunting repair of the damaged mucosa. We examined the effect of ONOO- on enterocyte proliferation and Src kinase activity. Sprague-Dawley rats were challenged with LPS or saline, whereas intestinal epithelial cell line cells were treated with ONOO- or decomposed ONOO- in vitro. Enterocyte proliferation in vivo and in vitro was measured by 5-bromo-2'-deoxyuridine (BrdU) or [3H]thymidine incorporation. Src kinase activity in cell lysates was determined at various times. LPS challenge in vivo and ONOO- treatment in vitro inhibited enterocyte proliferation. ONOO- treatment blunted the activity of Src and its downstream target, focal adhesion kinase, in a time-dependent manner. ONOO- blocked mitogen (FBS, EGF)-induced enterocyte proliferation and Src phosphorylation while increasing Src nitration. Thus ONOO- may promote gut barrier failure not only by inducing enterocyte apoptosis but also by disrupting signaling pathways involved in enterocyte proliferation.     

Peroxynitrite mild nitration of albumin and LDL-albumin complex naturally present in plasma and tyrosine nitration rate-albumin impairs LDL nitration

In blood, peroxynitrite (ONOO- ) and CO2 react to form NO2* and CO3* through the short-lived adduct ONOOCO2-, leading to protein-bound tyrosine nitration. ONOO(-) -modified LDL is atherogenic. Oxidatively modified LDL generally appears in the vessel wall surrounded by antioxidants. Human serum albumin (HSA) is one of them, partly associated to LDL as a LDL-albumin complex (LAC). The purpose was to study the effect of a mild nitration on LAC and whether albumin may interfere with LDL nitration. To do so, SIN-1 was used as ONOO- generator in the presence or absence of 25 mM HCO3-. The human serum albumin (HSA)-bound tyrosine nitration rate was found to be 4.4 x 10(-3) mol/mol in the presence of HCO3-. HSA decreased the LAC-tyrosine nitration rate from 2.5 x 10(-3) to 0.6 x 10(-3) mol/mol. It was concluded that HSA impaired the apoB-bound tyrosine nitration. These findings raise the question of the patho-physiological significance of these nitrations and their interactions which may potentially prevent both atheromatous plaque formation and endothelium dysfunction in particular and appear to be beneficial in terms of atherogenic risk.     

Evidence for peroxynitrite formation during S-nitrosoglutathione photolysis in air saturated solutions

Flash photolysis of S-nitrosoglutathione (GSNO) in aerated solutions at pH 10 gave rise to an absorption with a maximum around 310-320 nm. This peak is spectrally similar to that displayed by ONOO-. The decay kinetics of this absorption was compared to that of authentic ONOO-, generated independently. An excellent correlation was obtained. Further proof of ONOO- generation was provided by HPLC studies showing the production of 3-nitrotyrosine on irradiation of GSNO in the presence of tyrosine at pH 7.4. In addition, the nitration yield was increased approximately 5-fold in the presence of bicarbonate and totally eliminated with DMPO, indicating the requirement of a radical intermediate for peroxynitrite production during S-nitrosothiol photolysis.     

Peroxynitrite inhibits T lymphocyte activation and proliferation by promoting impairment of tyrosine phosphorylation and peroxynitrite-driven apoptotic death

Peroxynitrite (ONOO-) is a potent oxidizing and nitrating agent produced by the reaction of nitric oxide with superoxide. It readily nitrates phenolic compounds such as tyrosine residues in proteins, and it has been demonstrated that nitration of tyrosine residues in proteins inhibits their phosphorylation. During immune responses, tyrosine phosphorylation of key substrates by protein tyrosine kinases is the earliest of the intracellular signaling pathways following activation through the TCR complex. This work was aimed to evaluate the effects of ONOO- on lymphocyte tyrosine phosphorylation, proliferation, and survival. Additionally, we studied the generation of nitrating species in vivo and in vitro during immune activation. Our results demonstrate that ONOO-, through nitration of tyrosine residues, is able to inhibit activation-induced protein tyrosine phosphorylation in purified lymphocytes and prime them to undergo apoptotic cell death after PHA- or CD3-mediated activation but not upon phorbol ester-mediated stimulation. We also provide evidence indicating that peroxynitrite is produced during in vitro immune activation, mainly by cells of the monocyte/macrophage lineage. Furthermore, immunohistochemical studies demonstrate the in vivo generation of nitrating species in human lymph nodes undergoing mild to strong immune activation. Our results point to a physiological role for ONOO- as a down-modulator of immune responses and also as key mediator in cellular and tissue injury associated with chronic activation of the immune system.     

Sites and mechanisms of aconitase inactivation by peroxynitrite: modulation by citrate and glutathione

Aconitases are iron-sulfur cluster-containing proteins present both in mitochondria and cytosol of cells; the cubane iron-sulfur (Fe-S) cluster in the active site is essential for catalytic activity, but it also renders aconitase highly vulnerable to reactive oxygen and nitrogen species. This study examined the sites and mechanisms of aconitase inactivation by peroxynitrite (ONOO-), a strong oxidant and nitrating agent readily formed from superoxide anion and nitric oxide generated by mitochondria. ONOO- inactivated aconitase in a dose-dependent manner (half-maximal inhibition was observed with approximately 3 microM ONOO-). Low levels of ONOO- caused the conversion of the Fe-S cluster from the [4Fe-4S]2+ form to the inactive [3Fe-4S]1+ form with the loss of labile iron, as confirmed by low-temperature EPR analysis. In the presence of the substrate, citrate, 66-fold higher concentrations of ONOO- were required for half-maximal inhibition. The protective effects of citrate corresponded to its binding to the active site. The inactivation of aconitase in the presence of citrate was due to ONOO--mediated cysteine thiol loss and tyrosine nitration in the enzyme as shown by Western blot analyses. LC/MS/MS analyses revealed that ONOO- treatment to aconitase resulted in nitration of tyrosines 151 and 472 and oxidation to sulfonic acid of cysteines 126 and 385. The latter is one of the three cysteine residues in aconitase that binds to the Fe-S cluster. All other modified tyrosine and cysteine residues were adjacent to the binding site, thus suggesting that these modifications caused conformational changes leading to active-site disruption. Aconitase cysteine thiol modifications other than oxidation to sulfonic acid, such as S-glutathionylation, also decreased aconitase activity, thus indicating that glutathionylation may be an important means of modulating aconitase activity under oxidative and nitrative stress. Taken together, these results demonstrate that the Fe-S cluster in the active site, cysteine 385 bound to the Fe-S cluster, and tyrosine and cysteine residues in the vicinity of the active site are important targets of oxidative and/or nitrative attack, which is selectively controlled by the mitochondrial matrix citrate levels. The mechanisms inherent in aconitase inactivation by ONOO- are discussed in terms of the mitochondrial matrix metabolic and thiol redox state.     

Protective effects of resveratrol against oxidative/nitrative modifications of plasma proteins and lipids exposed to peroxynitrite

The protective effects of resveratrol (3, 4', 5-trihydroxystilbene; present naturally in different plants) against the oxidative/nitrative damage of human plasma proteins induced by peroxynitrite (ONOO-) were studied and compared with those of deferoxamine (DFO; a natural siderophore isolated from Streptomyces pilosus), which is a typical and well-known antioxidant. We also studied the effect of ONOO- on plasma lipid peroxidation and the role of tested antioxidants in this process. ONOO- at the used concentrations (0.01-1 mM) showed toxicity to human plasma components. Exposure of plasma to ONOO- (0.1 mM) resulted in an increase of the level of carbonyl groups and nitrotyrosine residues in plasma proteins (approximately 4-fold and 76-fold, respectively) and in a distinct augmentation of lipid peroxidation (approximately 2-fold). In the presence of 0.1-mM resveratrol, a distinct decrease of carbonyl group formation and tyrosine nitration in plasma proteins caused by 0.1-mM ONOO- was observed (by approximately 70% and 65%, respectively). Addition of 0.1-mM DFO to plasma also distinctly reduced the level of carbonyl groups and nitrotyrosines caused by 0.1-mM ONOO- (by approximately 50% and 60%, respectively). Moreover, these antioxidants also inhibited plasma lipid peroxidation induced by ONOO- (0.1 mM). The obtained results indicate that in vitro resveratrol, like well-known antioxidant DFO, has inhibitory effects on ONOO- -mediated oxidation of proteins and lipids in human plasma.     

Peroxynitrite-mediated tau modifications stabilize preformed filaments and destabilize microtubules through distinct mechanisms

Alzheimer's disease (AD) is a progressive amnestic dementia typified by abnormal modifications of the microtubule (MT)-associated tau protein that promote its pathological self-assembly and displacement from the MT lattice. Previously, we showed that peroxynitrite (ONOO-) induces the oxidative 3,3'-dityrosine (3,3'-DT) cross-linking and site-selective nitration of tau monomers [Reynolds et al. (2005) Biochemistry 44, 1690-1700]. In the present study, we examined the effects of ONOO(-)-mediated modifications on two key elements of tau pathobiology: (1) the stability of preformed tau filaments and (2) the ability of monomeric tau to promote tubulin assembly. Here, we report that treatment of synthetic tau filaments with ONOO- generates heat-stable, SDS-insoluble aggregates with a significantly reduced mobility by SDS-PAGE compared to that of nontreated filaments. Ultrastructurally, these aggregates appear to be cross-linked via interfilament bridges. Using LC-MS/MS and HPLC with fluorescent detection, we demonstrate that covalent 3,3'-DT linkages are present within these higher-order aggregates. Similar to monomeric tau, filamentous tau exhibits a hierarchical pattern of nitration following ONOO- treatment with site selectivity toward the amino-terminal residues Tyr18 and Tyr29. Further, select nitration of residues Tyr18, Tyr29, Tyr197, and Tyr394, events known to stabilize the pathological Alz-50 conformation [Reynolds et al. (2005) Biochemistry 44, 13997-14009], inhibits the ability of monomeric tau to promote tubulin assembly. This effect is specific for the 3-NT modification, as mutant tau proteins pseudophosphorylated at each Tyr residue are fully competent to stabilize MTs. Collectively, our results suggest that ONOO(-)-mediated modifications stabilize tau filaments via 3,3'-DT bonding and destabilize MTs by site-selective nitration of tau monomers. Moreover, assumption of the Alz-50 conformation may be the mechanism through which tau nitration modulates MT stability.     

Site-specific nitration differentially influences tau assembly in vitro

Previously, we reported that the microtubule-associated tau protein, the major constituent of neurofibrillary tangles (NFTs) in Alzheimer's brain, undergoes site-selective nitration by peroxynitrite (ONOO-) and that this event inhibits tau polymerization in vitro [Reynolds et al. (2005) Biochemistry 44, 1690-1700]. In the present study, we extend our analysis of tau nitration to include mutant tau proteins singly nitrated at each residue targeted by ONOO- in vitro (Tyr18, Tyr29, Tyr197, and Tyr394). Using our polymerization paradigm, we demonstrate that site-specific Tyr nitration differentially alters the rate and/or extent of tau assembly and generates robust changes in filament morphology. As determined by quantitative electron microscopy, select nitration of residues Tyr29 and Tyr197 increases the average length of synthetic tau filaments but does not alter the steady-state polymer mass. In contrast, site-specific nitration of residues Tyr18 and Tyr394 decreases the average length and/or number of synthetic filaments, resulting in a significant reduction in filamentous mass and an increase in tau critical concentration. Intriguingly, affinity measurements demonstrate that nitrative modifications do not preclude formation of the Alz-50 epitope, a pathological tau conformation detectable in authentic paired helical filaments (PHFtau). In fact, the Alz-50 antibody binds filaments assembled from nitrated mutant tau with higher avidity than wild-type filaments, even in instances where the overall filamentous mass is reduced. Taken together, our results suggest that site-specific nitration modulates the nucleation and/or elongation capacity of assembly-competent tau and that assumption of the Alz-50 conformation may be necessary, but not sufficient, to induce filament formation.     

Peroxynitrite reductase activity of selenoprotein glutathione peroxidase: a computational study

The peroxynitrite reductase activity of selenoprotein glutathione peroxidase (GPx) has been investigated using density functional theory calculations for peroxynitrite/peroxynitrous acid (ONOO-/ONOOH) substrates through two different "oxidation" and "nitration" pathways. In the oxidation pathway for ONOO-, the oxidation of GPx and the subsequent formation of the selenenic acid (E-Se-OH) occur through a concerted mechanism with an energy barrier of 4.7 (3.7) kcal/mol, which is in good agreement with the computed value of 7.1 kcal/mol for the drug ebselen and the experimentally measured barrier of 8.8 kcal/mol for both ebselen and GPx. For ONOOH, the formation of the E-Se-OH prefers a stepwise mechanism with an overall barrier of 6.9 (11.3) kcal/mol, which is 10.2 (11.2) kcal/mol lower than that for hydrogen peroxide (H2O2), indicating that ONOOH is a more efficient substrate for GPx oxidation. It has been demonstrated that the active site Gln83 residue plays a critical role during the oxidation process, which is consistent with the experimental suggestions. The nitration of GPx by ONOOH produces a nitro (E-Se-NO2) product via either of two different mechanisms, isomerization and direct, having almost the same barrier heights. A comparison between the rate-determining barriers of the oxidation and nitration pathways suggests that the oxidation of GPx by ONOOH is more preferable than its nitration. It was also shown that the rate-determining barriers remain the same, 21.5 (25.5) kcal/mol, in the peroxynitrite reductase and peroxidase activities of GPx.     

Peroxynitrite and fibrinolytic system: The effect of peroxynitrite on plasmin activity

We have shown that peroxynitrite (ONOO-) inhibits streptokinase-induced conversion of plasminogen to plasmin in a concentration-dependent manner and reduces both amidolytic (IC5o approximately 280 microM at 10 microM concentration of enzyme) and proteolytic activity of plasmin. Spectrophotometric and immunoblot analysis of peroxynitrite-treated plasminogen demonstrates a concentration-dependent increase in its nitrotyrosine residues that correlates with a decreased generation of active plasmin. Peroxynitrite (1 mM) causes the nitration of 2.9 tyrosines per plasminogen molecule. Glutathione, like deferoxamine, partially protects plasminogen from peroxynitrite-induced inactivation and reduces the extent of tyrosine nitration. These data suggest that nitration of plasminogen tyrosine residues by peroxynitrite might play an important role in the inhibition of plasmin catalytic activity.     

Kinetics of superoxide dismutase- and iron-catalyzed nitration of phenolics by peroxynitrite.

Superoxide dismutase and Fe3+EDTA catalyzed the nitration by peroxynitrite (ONOO-) of a wide range of phenolics including tyrosine in proteins. Nitration was not mediated by a free radical mechanism because hydroxyl radical scavengers did not reduce either superoxide dismutase or Fe3+EDTA-catalyzed nitration and nitrogen dioxide was not a significant product from either catalyst. Rather, metal ions appear to catalyze the heterolytic cleavage of peroxynitrite to form a nitronium-like species (NO2+). The calculated energy for separating peroxynitrous acid into hydroxide ion and nitronium ion is 13 kcal.mol-1 at pH 7.0. Fe3+EDTA catalyzed nitration with an activation energy of 12 kcal.mol-1 at a rate of 5700 M-1.s-1 at 37 degrees C and pH 7.5. The reaction rate of peroxynitrite with bovine Cu,Zn superoxide dismutase was 10(5) M-1.s-1 at low superoxide dismutase concentrations, but the rate of nitration became independent of superoxide dismutase concentration above 10 microM with only 9% of added peroxynitrite yielding nitrophenol. We propose that peroxynitrite anion is more stable in the cis conformation, whereas only a higher energy species in the trans conformation can fit in the active site of Cu,Zn superoxide dismutase. At high superoxide dismutase concentrations, phenolic nitration may be limited by the rate of isomerization from the cis to trans conformations of peroxynitrite as well as by competing pathways for peroxynitrite decomposition. In contrast, Fe3+EDTA appears to react directly with the cis anion, resulting in greater nitration yields.     

Identification of the nitration site of insulin by peroxynitrite.

Our previous investigation indicated that insulin can be nitrated by peroxynitrite in vitro. In this study, the preferential nitration site of the four tyrosine residues in insulin molecule was confirmed. Mononitrated and dinitrated insulins were purified by RP-HPLC. Following reduction of insulin disulfide bridges, Native-PAGE indicated that A-chain was preferentially nitrated. Combination of enzymatic digestion of mononitrated insulin with endoproteinase Glu-C, mass spectrometry confirmed that Tyr-A14 was the preferential nitration site when insulin was treated with peroxynitrite. Tyr-A19, maybe, was the next preferential nitration site. According to the crystal structure, Tyr-B26 between the two tyrosine residues in insulin B-chain was likely easier to be nitrated by peroxynitrite.