Selective nitration of histone tyrosine residues in vivo in mutatect tumors.

Nitric oxide-derived reactive species have been implicated in many disorders. Protein nitrotyrosine is often used as a stable marker of these reactive species. Using immunohistochemistry, we have previously detected nitrotyrosine in murine Mutatect tumors, where neutrophils are the principal source of nitric oxide. We now report on the identification of several prominent nitrotyrosine-containing proteins. Using Western blot analysis, nitrotyrosine in higher molecular mass proteins (>20 kDa) was detected in tumors containing a high number of neutrophils but not in tumors with fewer neutrophils. Staining for nitrotyrosine was consistently seen in low molecular mass proteins (< or =15 kDa), regardless of the level of neutrophils. Protein nitrotyrosine was not seen in Mutatect cells growing in vitro. Treatment with nitric oxide donors produced nitration of < or =15-kDa proteins, but only after extended periods. These small proteins, both from tumors and cultured cells, were identified by mass spectrometry to be histones. Only a subset of tyrosine residues was nitrated. Selective nitration may reflect differential accessibility of different tyrosine residues and the influence of neighboring residues within the nucleosome. The prominence of histone nitration may reflect its relative stability, making this post-translational modification a potentially useful marker of extended exposure of cells or tissues to nitric oxide-derived reactive species.     

Tyrosine nitration of c-SRC tyrosine kinase in human pancreatic ductal adenocarcinoma

During pancreatic tumorigenesis, the equilibrium between cell survival and cell death is altered, allowing aggressive neoplasia and resistance to radiation and chemotherapy. Local oxidative stress is one mechanism regulating programmed cell death and growth and may contribute to both tumor progression and suppression. Our recent in situ immunohistochemical studies demonstrated that levels of total nitrotyrosine, a footprint of the reactive nitrogen species peroxynitrite, are elevated in human pancreatic ductal adenocarcinomas. In this study, quantitative HPLC-EC techniques demonstrated a 21- to 97-fold increase in the overall levels of nitrotyrosine of human pancreatic tumor extracts compared to normal pancreatic extracts. Western blot analysis of human pancreatic tumor extracts showed that tyrosine nitration was restricted to a few specific proteins. Immunoprecipitation coupled with Western analysis identified c-Src tyrosine kinase as a target of both tyrosine nitration and tyrosine phosphorylation. Peroxynitrite treatment of human pancreatic carcinoma cells in vitro resulted in increased tyrosine nitration and tyrosine phosphorylation of c-Src kinase, increased (>2-fold) c-Src kinase activity, and increased association between c-Src kinase and its downstream substrate cortactin. Collectively, these observations suggest that peroxynitrite-mediated tyrosine nitration and tyrosine phosphorylation of c-Src kinase may lead to enhanced tyrosine kinase signaling observed during pancreatic ductal adenocarcinoma growth and metastasis.     

Peroxynitrite treatment in vitro disables catalytic activity of recombinant p38 MAPK

Protein tyrosine nitration is a post-translational modification occurring under conditions of oxidative stress in a number of diseases. The causative agent of tyrosine nitration is the potent prooxidant peroxynitrite that results from the interaction of nitric oxide and superoxide. We have previously demonstrated existence of nitrotyrosine in placenta from pregnancies complicated by preeclampsia, which suggested the possibility of the existence of nitrated proteins. Nitration of various proteins has been demonstrated to more commonly result in loss of protein function. Potential nitration of p38 MAPK, a critical signaling molecule has been suggested and also tentatively identified in certain in vivo systems. In this study we demonstrate for the first time nitration of recombinant p38 MAPK in vitro and an associated loss of its catalytic activity. LC-MS data identified tyrosine residues Y132, Y245 and Y258 to be nitrated. Nitration of these specific residues was deduced from the 45.0-Da change in mass that these residues exhibited that was consistent with the loss of a proton and addition of the nitro group.     

Endogenously nitrated proteins in mouse brain: links to neurodegenerative disease

Increased abundance of nitrotyrosine modifications of proteins have been documented in multiple pathologies in a variety of tissue types and play a role in the redox regulation of normal metabolism. To identify proteins sensitive to nitrating conditions in vivo, a comprehensive proteomic data set identifying 7792 proteins from a whole mouse brain, generated by LC/LC-MS/MS analyses, was used to identify nitrated proteins. This analysis resulted in the identification of 31 unique nitrotyrosine sites within 29 different proteins. More than half of the nitrated proteins that have been identified are involved in Parkinson's disease, Alzheimer's disease, or other neurodegenerative disorders. Similarly, nitrotyrosine immunoblots of whole brain homogenates show that treatment of mice with 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), an experimental model of Parkinson's disease, induces an increased level of nitration of the same protein bands observed to be nitrated in brains of untreated animals. Comparing sequences and available high-resolution structures around nitrated tyrosines with those of unmodified sites indicates a preference of nitration in vivo for surface accessible tyrosines in loops, a characteristic consistent with peroxynitrite-induced tyrosine modification. In addition, most sequences contain cysteines or methionines proximal to nitrotyrosines, contrary to suggestions that these amino acid side chains prevent tyrosine nitration. More striking is the presence of a positively charged moiety near the sites of nitration, which is not observed for non-nitrated tyrosines. Together, these observations suggest a predictive tool of functionally important sites of nitration and that cellular nitrating conditions play a role in neurodegenerative changes in the brain.     

Evidence that light modulates protein nitration in rat retina

As part of ongoing efforts to better understand the role of protein oxidative modifications in retinal pathology, protein nitration in retina has been compared between rats exposed to damaging light or maintained in the dark. In the course of the research, Western methodology for detecting nitrotyrosine-containing proteins has been improved by incorporating chemical reduction of nitrotyrosine to aminotyrosine, allowing specific and nonspecific nitrotyrosine immunoreactivity to be distinguished. A liquid chromatography MS/MS detection strategy was used that selects all possible nitrotyrosine peptides for MS/MS based on knowing the protein identity. Quantitative liquid chromatography MS/MS analyses with tetranitromethane-modified albumin demonstrated the approach capable of identifying sites of tyrosine nitration with detection limits of 4-33 fmol. Using two-dimensional gel electrophoresis, Western detection, and mass spectrometric analyses, several different nitrotyrosine-immunoreactive proteins were identified in light-exposed rat retina compared with those maintained in the dark. Immunocytochemical analyses of retina revealed that rats reared in darkness exhibited more nitrotyrosine immunoreactivity in the photoreceptor outer segments. After intense light exposure, immunoreactivity decreased in the outer segments and increased in the photoreceptor inner segments and retinal pigment epithelium. These results suggest that light modulates retinal protein nitration in vivo and that nitration may participate in the biochemical sequela leading to light-induced photoreceptor cell death. Furthermore, the identification of nitrotyrosine-containing proteins from rats maintained in the dark, under non-pathological conditions, provides the first evidence of a possible role for protein nitration in normal retinal physiology.     

Hemoglobin can nitrate itself and other proteins.

Incubation of human hemoglobin with nitrite and hydrogen peroxide was found to induce autonitration and nitration of another protein (bovine serum albumin), as demonstrated by detection of nitrotyrosine residues in Western blots of separated membrane proteins. Inhibition of nitration by conversion of hemoglobin into the cyanmet form demonstrates that nitration is due to the pseudoperoxidase activity of hemoglobin. Incubation of whole erythrocytes with nitrite and hydrogen peroxide induces nitration of erythrocyte membrane proteins, much stronger when cellular catalase was inhibited with azide. These results suggest that hemoglobin and other hemoproteins may contribute to the tyrosine nitration in vivo.     

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.     

Peroxynitrite-mediated tyrosine nitration catalyzed by superoxide dismutase.

Peroxynitrite (ONOO-), the reaction product of superoxide (O2-) and nitric oxide (NO), may be a major cytotoxic agent produced during inflammation, sepsis, and ischemia/reperfusion. Bovine Cu,Zn superoxide dismutase reacted with peroxynitrite to form a stable yellow protein-bound adduct identified as nitrotyrosine. The uv-visible spectrum of the peroxynitrite-modified superoxide dismutase was highly pH dependent, exhibiting a peak at 438 nm at alkaline pH that shifts to 356 nm at acidic pH. An equivalent uv-visible spectrum was obtained by Cu,Zn superoxide dismutase treated with tetranitromethane. The Raman spectrum of authentic nitrotyrosine was contained in the spectrum of peroxynitrite-modified Cu,Zn superoxide dismutase. The reaction was specific for peroxynitrite because no significant amounts of nitrotyrosine were formed with nitric oxide (NO), nitrogen dioxide (NO2), nitrite (NO2-), or nitrate (NO3-). Removal of the copper from the Cu,Zn superoxide dismutase prevented formation of nitrotyrosine by peroxynitrite. The mechanism appears to involve peroxynitrite initially reacting with the active site copper to form an intermediate with the reactivity of nitronium ion (NO2+), which then nitrates tyrosine on a second molecule of superoxide dismutase. In the absence of exogenous phenolics, the rate of nitration of tyrosine followed second-order kinetics with respect to Cu,Zn superoxide dismutase concentration, proceeding at a rate of 1.0 +/- 0.1 M-1.s-1. Peroxynitrite-mediated nitration of tyrosine was also observed with the Mn and Fe superoxide dismutases as well as other copper-containing proteins.     

pH profile of cytochrome c-catalyzed tyrosine nitration

In the present study, we investigated how cytochrome c catalyzed the nitration of tyrosine at various pHs. The cytochrome c-catalyzed nitration of tyrosine occurred in proportion to the concentration of hydrogen peroxide, nitrite or cytochrome c. The cytochromec-catalyzed nitration of tyrosine was inhibited by catalase, sodium azide, cystein, and uric acid. These results show that the cytochrome c-catalyzed nitrotyrosine formation was due to peroxidase activity. The rate constant between cytochrome c and hydrogen peroxide within the pH range of 3-8 was the largest at pH 6 (37 degrees C). The amount of nitrotyrosine formed was the greatest at pH 5. At pH 3, only cytochromec-independent nitration of tyrosine occurred in the presence of nitrite. At this pH, the UV as well as visible spectrum of cytochrome c was changed by nitrite, even in the presence of hydrogen peroxide, probably via the formation of a heme iron-nitric oxide complex. Due to this change, the peroxidase activity of cytochrome c was lost.     

Inflammatory cytokines induce protein tyrosine nitration in rat astrocytes

Protein tyrosine nitration may be relevant for the pathogenesis of hepatic encephalopathy (HE). Infections, sepsis, and trauma precipitate HE episodes. Recently, serum levels of tumor necrosis factor (TNF)-alpha were shown to correlate with severity of HE in chronic liver failure. Here the effects of inflammatory cytokines on protein tyrosine nitration in cultured rat astrocytes and rat brain in vivo were studied. In cultured rat astrocytes TNF-alpha (50 pg/ml-10 ng/ml) within 6h increased protein tyrosine nitration. TNF-alpha-induced tyrosine nitration was related to an increased formation of reactive oxygen and nitrogen intermediates, which was downstream from a NMDA-receptor-dependent increase of intracellular [Ca(2+)](i) and nNOS-catalyzed NO production. Astroglial tyrosine nitration was also elevated in brains of rats receiving a non-lethal injection of lipopolysaccharide, as indicated by colocalization of nitrotyrosine immunoreactivity with glial fibrillary acidic protein and glutamine synthetase, and by identification of the glutamine synthetase among the tyrosine-nitrated proteins. It is concluded that reactive oxygen and nitrogen intermediates as well as protein tyrosine nitration by inflammatory cytokines may alter astrocyte function in an NMDA-receptor-, Ca(2+)-, and NOS-dependent fashion. This may be relevant for the pathogenesis of HE and other conditions involving cytokine exposure the brain.     

Protein tyrosine nitration in the mitochondria from diabetic mouse heart. Implications to dysfunctional mitochondria in diabetes

Oxidative stress has been implicated in dysfunctional mitochondria in diabetes. Tyrosine nitration of mitochondrial proteins was observed under conditions of oxidative stress. We hypothesize that nitration of mitochondrial proteins is a common mechanism by which oxidative stress causes dysfunctional mitochondria. The putative mechanism of nitration in a diabetic model of oxidative stress and functional changes of nitrated proteins were studied in this work. As a source of mitochondria, alloxan-susceptible and alloxan-resistant mice were used. These inbred strains are distinguished by the differential ability to detoxify free radicals. A proteomic approach revealed significant similarity between patterns of tyrosine-nitrated proteins generated in the heart mitochondria under different in vitro and in vivo conditions of oxidative stress. This observation points to a common nitrating species, which may derive from different nitrating pathways in vivo and may be responsible for the majority of nitrotyrosine formed. Functional studies show that protein nitration has an adverse effect on protein function and that protection against nitration protects functional properties of proteins. Because proteins that undergo nitration are involved in major mitochondrial functions, such as energy production, antioxidant defense, and apoptosis, we concluded that tyrosine nitration of mitochondrial proteins may lead to dysfunctional mitochondria in diabetes.     

Proteomic analysis of protein nitration in aging skeletal muscle and identification of nitrotyrosine-containing sequences in vivo by nanoelectrospray ionization tandem mass spectrometry

The nitration of protein tyrosine residues represents an important post-translational modification during development, oxidative stress, and biological aging. To rationalize any physiological changes with such modifications, the actual protein targets of nitration must be identified by proteomic methods. While several studies have used proteomics to screen for 3-nitrotyrosine-containing proteins in vivo, most of these studies have failed to prove nitration unambiguously through the actual localization of 3-nitrotyrosine to specific sequences by mass spectrometry. In this paper we have applied sequential solution isoelectric focusing and SDS-PAGE for the proteomic characterization of specific 3-nitrotyrosine-containing sequences of nitrated target proteins in vivo using nanoelectrospray ionization-tandem mass spectrometry. Specifically, we analyzed proteins from the skeletal muscle of 34-month-old Fisher 344/Brown Norway F1 hybrid rats, a well accepted animal model for biological aging. We identified the 3-nitrotyrosine-containing sequences of 11 proteins, including cytosolic creatine kinase, tropomyosin 1, glyceraldehyde-3-phosphate dehydrogenase, myosin light chain, aldolase A, pyruvate kinase, glycogen phosphorylase, actinin, gamma-actin, ryanodine receptor 3, and neurogenic locus notch homolog. For creatine kinase and neurogenic locus notch homolog, two 3-nitrotyrosine-containing sequences were identified, i.e. at positions 14 and 20 for creatine kinase and at positions 1175 and 1205 for the neurogenic locus notch homolog. The selectivity of the in vivo nitration of creatine kinase at Tyr14 and Tyr20 does not correspond to the product selectivity in vitro, where exclusively Tyr82 was nitrated when creatine kinase was exposed to peroxynitrite. The latter experiments demonstrate that the in vitro exposure of an isolated protein to peroxynitrite may not always be a good model to mimic protein nitration in vivo.     

Nitration and oxidation of a hydrophobic tyrosine probe by peroxynitrite in membranes: comparison with nitration and oxidation of tyrosine by peroxynitrite in aqueous solution.

It has been reported that peroxynitrite will initiate both oxidation and nitration of tyrosine, forming dityrosine and nitrotyrosine, respectively. We compared peroxynitrite-dependent oxidation and nitration of a hydrophobic tyrosine analogue in membranes and tyrosine in aqueous solution. Reactions were carried out in the presence of either bolus addition or slow infusion of peroxynitrite, and also using the simultaneous generation of superoxide and nitric oxide. Results indicate that the level of nitration of the hydrophobic tyrosyl probe located in a lipid bilayer was significantly greater than its level of oxidation to the corresponding dimer. During slow infusion of peroxynitrite, the level of nitration of the membrane-incorporated tyrosyl probe was greater than that of tyrosine in aqueous solution. Evidence for hydroxyl radical formation from decomposition of peroxynitrite in a dimethylformamide/water mixture was obtained by electron spin resonance spin trapping. Mechanisms for nitration of the tyrosyl probe in the membrane are discussed. We conclude that nitration but not oxidation of a tyrosyl probe by peroxynitrite is a predominant reaction in the membrane. Thus, the local environment of target tyrosine residues is an important factor governing its propensity to undergo nitration in the presence of peroxynitrite. This work provides a new perspective on selective nitration of membrane-incorporated tyrosine analogues.     

Tyrosine nitration impairs mammalian aldolase A activity

Protein tyrosine nitration increases in vivo as a result of oxidative stress and is elevated in numerous inflammatory-associated diseases. Mammalian fructose-1,6-bisphosphate aldolases are tyrosine nitrated in lung epithelial cells and liver, as well as in retina under different inflammatory conditions. Using two-dimensional gel electrophoresis and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry, we now show that aldolase A is nitrated in human skin fibroblasts. To reveal the consequences of tyrosine nitration, we studied the impact of peroxynitrite on the glycolytic functions of aldolase A. A peroxynitrite concentration-dependent decrease in fructose-1,6-bisphosphate cleavage activity was observed with a concomitant increase in nitrotyrosine immunoreactivity. Both V(max) and the K(m) for fructose-1,6-bisphosphate decreased after incubation with peroxynitrite. Aldolase nitrotyrosine immunoreactivity diminished following carboxypeptidase Y digestion, demonstrating that tyrosine residues in the carboxyl-terminal region of aldolase are major targets of nitration. Aldolase A contains a carboxyl-terminal tyrosine residue, Tyr(363), that is critical for its catalytic activity. Indeed, tandem mass spectrometric analysis of trypsin-digested aldolase showed that Tyr(363) is the most susceptible to nitration, with a modification of Tyr(342) occurring only after nitration of Tyr(363). These tyrosine nitrations likely result in altered interactions between the carboxyl-terminal region and enzyme substrate or reaction intermediates causing the decline in activity. The results suggest that tyrosine nitration of aldolase A can contribute to an impaired cellular glycolytic activity.     

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.     

Neuronal NOS-mediated nitration and inactivation of manganese superoxide dismutase in brain after experimental and human brain injury

Manganese superoxide dismutase (MnSOD) provides the first line of defense against superoxide generated in mitochondria. SOD competes with nitric oxide for reaction with superoxide and prevents generation of peroxynitrite, a potent oxidant that can modify proteins to form 3-nitrotyrosine. Thus, sufficient amounts of catalytically competent MnSOD are required to prevent mitochondrial damage. Increased nitrotyrosine immunoreactivity has been reported after traumatic brain injury (TBI); however, the specific protein targets containing modified tyrosine residues and functional consequence of this modification have not been identified. In this study, we show that MnSOD is a target of tyrosine nitration that is associated with a decrease in its enzymatic activity after TBI in mice. Similar findings were obtained in temporal lobe cortical samples obtained from TBI cases versus control patients who died of causes not related to CNS trauma. Increased nitrotyrosine immunoreactivity was detected at 2 h and 24 h versus 72 h after experimental TBI and co-localized with the neuronal marker NeuN. Inhibition and/or genetic deficiency of neuronal nitric oxide synthase (nNOS) but not endothelial nitric oxide synthase (eNOS) attenuated MnSOD nitration after TBI. At 24 h after TBI, there was predominantly polymorphonuclear leukocytes accumulation in mouse brain whereas macrophages were the predominant inflammatory cell type at 72 h after injury. However, a selective inhibitor or genetic deficiency of inducible nitric oxide synthase (iNOS) failed to affect MnSOD nitration. Nitration of MnSOD is a likely consequence of peroxynitrite within the intracellular milieu of neurons after TBI. Nitration and inactivation of MnSOD could lead to self-amplification of oxidative stress in the brain progressively enhancing peroxynitrite production and secondary damage.     

Dynamics of protein nitration in cells and mitochondria

Nitric oxide is a precursor of reactive nitrating species such as peroxynitrite and nitrogen dioxide that modify proteins to generate 3-nitrotyrosine. Many diseases are associated with increased levels of protein-bound nitrotyrosine, and this is used as a marker for oxidative damage. However, the regulation of protein nitration and its role in cell function are unclear. We demonstrate that biological protein nitration can be a specific and dynamic process. Proteins were nitrated in distinct temporal patterns in cells undergoing inflammatory activation, and protein denitration and renitration occurred rapidly in respiring mitochondria. The targets of protein nitration varied over time, which may reflect their sensitivity to nitration, expression pattern, or turnover. The dynamic nature of the nitration process was revealed by denitration and renitration of proteins occurring within minutes in mitochondria that were subject to hypoxiaanoxia and reoxygenation. Our results have implications that are particularly important for ischemia-reperfusion injury.     

Nitric oxide nitrates tyrosine residues of tumor-suppressor p53 protein in MCF-7 cells

It has been reported that mammalian cells incubated with excess nitric oxide (NO) accumulate p53 protein but concomitantly this p53 loses its capacity for binding to its DNA consensus sequence. As nitration of tyrosine residues in various proteins has been shown to inhibit their functions, we examined whether NO nitrates tyrosine residues in p53 protein. MCF-7 cells expressing wild-type p53 were incubated with S-nitrosoglutathione for 4 h and cellular extracts were immunoprecipitated with an anti-p53 antibody. Western blot analyses of immunoprecipitates for p53 or for nitrotyrosine revealed low levels of nitrotyrosine in p53 from untreated cells. Incubation with 2 mM S-nitrosoglutathione induced a significant increase in the nitrotyrosine level in p53 protein compared to nontreated cells. These results suggest that excess NO produced in inflamed tissues could nitrate p53 protein, playing a role in carcinogenesis by impairing functions of this tumor-suppressor protein.     

Tyrosine modification of glucose dehydrogenase from Bacillus megaterium. Effect of tetranitromethane on the enzyme in the tetrameric and monomeric state

The active tetrameric glucose dehydrogenase from Bacillus megaterium is rapidly inactivated upon reaction with tetranitromethane. The inactivation is correlated with the nitration of a single tyrosine residue/subunit. The nitration does not influence the dissociation-reassociation process of the enzyme. The inactivation is prevented by the presence of NAD, AMP, ATP. The sequence around the nitrated tyrosine residue was determined and the residue was identified as Tyr-254 in the covalent structure of the enzyme. After dissociation of the enzyme into its monomers two tyrosine residues become susceptible to nitration. The nitrated subunits are unable to reassociate to the tetramer. Isolation and sequence analysis of the peptides containing nitrotyrosine indicated that two different tyrosine residues are predominantly modified. One residue is Tyr-254 which is essential for the catalytic activity and the other one is Tyr-160 which seems to be located in the subunit binding area.     

Tyrosine nitration by peroxynitrite formed from nitric oxide and superoxide generated by xanthine oxidase

Peroxynitrite (ONOO(-)) is a potent nitrating and oxidizing agent that is formed by a rapid reaction of nitric oxide (NO) with superoxide anion (O(2)). It appears to be involved in the pathophysiology of many inflammatory and neurodegenerative diseases. It has recently been reported (Pfeiffer, S., and Mayer, B. (1998) J. Biol. Chem. 273, 27280-27285) that ONOO(-) generated at neutral pH from NO and O(2) (NO/O(2)) was substantially less efficient than preformed ONOO(-) at nitrating tyrosine. Here we re-evaluated tyrosine nitration by NO/O(2) with a shorter incubation period and a more sensitive electrochemical detection system. Appreciable amounts of nitrotyrosine were produced by ONOO(-) formed in situ (2.9 micrometer for 5 min; 10 nm/s) by NO/O(2) flux obtained from propylamine NONOate (CH(3)N[N(O)NO](-) (CH(2))(3)NH(2)(+)CH(3)) and xanthine oxidase using pterin as a substrate in phosphate buffer (pH 7.0) containing 0.1 mm l-tyrosine. The yield of nitrotyrosine by this NO/O(2) flux was approximately 70% of that produced by the same flux of preformed ONOO(-) (2.9 micrometer/5 min). When hypoxanthine was used as a substrate, tyrosine nitration by NO/O(2) was largely eliminated because of the inhibitory effect of uric acid produced during the oxidation of hypoxanthine. Tyrosine nitration caused by NO/O(2) was inhibited by the ONOO(-) scavenger ebselen and was enhanced 2-fold by NaHCO(3), as would be expected, because CO(2) promotes tyrosine nitration. The profile of nitrotyrosine and dityrosine formation produced by NO/O(2) flux (2.9 micrometer/5 min) was consistent with that produced by preformed ONOO(-). Tyrosine nitration predominated compared with dityrosine formation caused by a low nanomolar flux of ONOO(-) at physiological concentrations of free tyrosine (<0.5 mm). In conclusion, our results show that NO generated with O(2) nitrates tyrosine with a reactivity and efficacy similar to those of chemically synthesized ONOO(-), indicating that ONOO(-) can be a significant source of tyrosine nitration in physiological and pathological events in vivo.