The phosphoenolpyruvate-dependent phosphotransferase system of Staphylococcus aureus. Complete tyrosine assignments in the 1H nuclear-magnetic-resonance spectrum of the phosphocarrier protein HPr.

Upon nitration of the phosphocarrier protein HPr three nitrated derivatives of the protein were isolated: mononitrated HPr, dinitrated HPr and trinitrated HPr. Tryptic digestion of the derivatives leads to nitrotyrosine-containing peptides which were isolated and characterized by amino acid analysis. This resulted in the determination of the positions of the nitrated tyrosyl residues in the amino acid sequence. In mononitrated HPr only Tyr-56 was modified, in dinitrated HPr both Tyr-56 and Tyr-37 had reacted with the nitrating agent; modification of all three tyrosyl residues in trinitrated HPr required more drastic reaction conditions. The nuclear magnetic resonance spectra of the three derivatives allowed the assignments of the tyrosine resonances as follows: Tyr-A and Tyr-B with pK values of 10.5 and 11.5 were designated Tyr-56 and Tyr-37 whereas Tyr-C, whose protons are not titratable before denaturation of the protein, was assigned to Tyr-6 in the amino acid sequence. The nitration studies, together with the titration behaviour of the three tyrosines, indicate the topology of the tyrosyl residues to be as follows: Tyr-56 is located at the surface, Tyr-37 is slightly buried, Tyr-6 is deeply buried. The nitrotyrosyl derivatives retain their biological activity.     

Chemical modification of neutral protease from Bacillus subtilis var. amylosacchariticus with tetranitromethane: assignment of tyrosyl residues nitrated

A neutral protease from Bacillus subtilis var. amylosacchariticus was modified with tetranitromethane (TNM) at pH 8.0 for 1 h at 25 degrees C, by which treatment the proteolytic activity toward casein was markedly reduced, whereas activity changes toward N-blocked peptide substrates were variable depending upon the substrate used. The modified enzyme was digested with a Staphylococcus aureus V8 protease at pH 7.9 and the resultant peptides were separated by HPLC. Two peptides which contain nitrotyrosyl residue(s) were purified. One of the peptides was found to have an amino acid sequence of Thr-Ala-Asn-Leu-Ile-Tyr-Glu, which corresponds to residue Nos. 153-159 of the neutral protease, and Tyr-158 was identified as PTH-nitrotyrosine. The other one was the amino-terminal peptide of residue Nos. 1-22, and Tyr-21 was shown to be nitrated. From a comparison with the active site structure of thermolysin, which is a zinc metalloprotease with a high sequence homology to B. subtilis neutral proteases, nitration of Tyr-158 was inferred to be closely related to the activity changes of the neutral protease from B. subtilis var. amylosacchariticus.     

Differences between the conformations of nitrotyrosyl-248 carboxypeptidase A in the crystalline state and in solution

In solution, nitrocarboxypeptidase A, modified at tyrosyl-248, exhibits a nitrotyrosyl pK apparent of 6.3. In the crystalline state, the pK apparent is about 8.2. This change in ionization is consistent with the hypothesis that crystallization of the enzyme causes a displacement of tyrosine-248 away from the active site zinc ion.     

Chemical modification of human alpha 1-proteinase inhibitor by tetranitromethane. Structure-function relationship.

Nitration of tyrosine residues of alpha 1-proteinase inhibitor (alpha 1-PI) by tetranitromethane yielded a product that maintained its inhibitory activity against trypsin but lost most of its inhibitory activity against elastase. Chemical analysis of the product showed that four out of the six tyrosine residues in alpha 1-PI had been nitrated to various degrees: Tyr-38 and Tyr-297 were not nitrated, whereas Tyr-138, Tyr-160, Tyr-187 and Tyr-244 were nitrated to extents in the range 40-80%. We interpreted these data to mean that modification of these tyrosine residues decreased the association constant between alpha 1-PI and the proteinases and that the decrease differs from one proteinase to the other. When either alpha 1-PI-trypsin or alpha 1-PI-elastase complex was nitrated, nitration took place only to a very slight extent at these latter four tyrosine residues. On the other hand, Tyr-38 and Tyr-297 underwent nitration to about 20%. We concluded that Tyr-138, Tyr-160, Tyr-187 and Tyr-244 were located on the surface of alpha 1-PI that interacts with either trypsin or elastase in the formation of complexes, and were therefore protected from nitration.     

The reaction of tetranitromethane with human chorionic gonadotropin.

The reaction of tetranitromethane with human chorionic gonadotropin and its subunits has been investigated. The hormone consists of two subunits, α and β, containing four and three tyrosyl residues, respectively. Introduction of 1 nitrated tyrosine residue into the native hormone was accompanied by a 20% loss in immunological reactivity and a 50% loss in biological activity. This initial reaction occurred at α Tyr-88 and/or α Tyr-89. Exhaustive nitration of the hormone modified α tyrosines 65, 88, and 89 and resulted in 75% inactivation biologically and 50% immunologically. Either nitrated α subunit obtained by dissociation of the nitrated hormone recombined with the native β subunit to give a hormone whose activity was in reasonable agreement with that of the corresponding nitrated monomer. These results indicate involvement of α Tyr-88 and/or α Tyr 89 in binding of the hormone to its receptor. These residues are not required for binding to the β subunit, however. Tyr-65 of the α subunit is probably not involved in binding to either the β subunit or the hormone receptor. The β subunit obtained from the exhaustively nitrated hormone was unmodified and recombined with native α to give fully active hormone. About 25% of the protein was recovered as polymeric material following nitration; lesser amounts of crosslinked monomer were formed. Both were biologically inactive. The polymer products retained about 30% of the native immunological competence.Nitration of the isolated α subunit fully converted the remaining tyrosine (Tyr-37) to 3-nitrotyrosine in a two-step reaction. The fully nitrated α subunit did not recombine well with the native β subunit and the recombinant hormone has 10% or less of the native activity. Involvement of α Tyr-37 in binding to the β subunit is suggested by these data. However, exposure of this residue by a conformational change in the α subunit after dissociation of the native hormone, while it seems unlikely in view of the high disulfide content, is also consistent with the data. Reaction of the free β subunit with tetranitromethane resulted in complete nitration of Tyr-37, 85% nitration of Tyr-59, and 25% nitration of Tyr-82. The nitrated β subunit did not recombine well with native α but the isolated recombinant had two-thirds of the native activity. From these data we conclude that β Tyr-37 and/or β Tyr-59 are possibly involved in binding to the α subunit but do not have a role in the biological activity. Tyr-82 of β is apparently not involved in either subunit interactions or hormone-receptor binding.     

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.     

Nitration of the tyrosine residues of porcine pancreatic colipase with tetranitromethane, and properties of the nitrated derivatives

The nitration of the long form (N-terminal valine) of porcine pancreatic colipase with tetranitromethane was investigated under a variety of conditions. Fractionation of the nitrated monomers on DE-cellulose led to well-defined derivatives containing one, two and three nitrotyrosines per mol. Automated Edman degradation of the nitrated peptides, especially that of the staphylococcal proteinase peptide (49-64) showed that Tyr-54 was nitrated very fast under all conditions. This residue was the only one to be nitrated in water. Partial nitration of Tyr-59 was induced by bile salt micelles, while both Tyr-59 and Tyr-58 reacted extensively in the presence of lysophosphatidylcholine micelles (in which tetranitromethane is concentrated 150-fold compared to water) or of a liquid tetranitromethane-water interface. The strong negative Cotton effect at 410 nm which has already been observed using unfractionated preparations of nitrated colipase (Behnke W.D. (1982) Biochim. Biophys. Acta 708, 118-123) is linked with the nitration of Tyr-59 and it is markedly reduced by taurodeoxycholate micelles, suggesting a conformational change induced by the micelles in the tyrosine region. Moreover, the pKa of the nitrotyrosine residues in nitrated colipase is the same as that of free nitrotyrosine (pKa = 6.8) and it is shifted to 7.6 in the presence of taurodeoxycholate micelles. Micelles protected colipase against polymerization during nitration. These data suggest that Tyr-58 and Tyr-59 are part of the interface recognition site of colipase. The participation of Tyr-55 in binding is not excluded. The upwards nitrotyrosine pKa shift in the colipase micelle complex may explain why nitrated colipase can reactivate lipase in a triacylglycerol-taurodeoxycholate system at pH 7.5.     

Chemical modification of cytochrome P-450 LM4. Identification of functionally linked tyrosine residues

Cytochrome P-450 LM4 (RH, reduced flavoprotein:oxygen oxidoreductase (RH-hydroxylating), EC 1.14.14.1) from rabbit liver microsomes was chemically modified with tetranitromethane. Nitration of two tyrosine residues inhibits the p-nitrophenetole O-deethylase activity of the enzyme by about 80%. Sequencing the 3-nitrotyrosine-containing peptides after HPLC tryptic peptide mapping reveals that mainly Tyr-243 and Tyr-271 are nitrated, whereas Tyr-71, Tyr-188 and Tyr-365 are modified to a lower extent. Nitration of tyrosine residues affects the complex formation with p-nitrophenetole, alpha-naphthoflavone and metyrapone as indicated by an increased affinity towards p-nitrophenetole and by a decreased affinity for the latter compounds. Furthermore, nitration interferes with the electron transfer from NADPH-cytochrome P-450-reductase to cytochrome P-450 LM4 resulting in a slowed down reduction reaction. The results suggest that Tyr-243 and Tyr-271 of cytochrome P-450 LM4 are functionally involved in the interaction with NADPH-cytochrome P-450 reductase.     

Functional tyrosyl residues of carboxypeptidase A. The effect of protein structure on the reactivity of tyrosine-198

Coupling of bovine carboxypeptidase A with diazotized 5-amino-1H-tetrazole increases esterase activity, decreases peptidase activity slightly, and modifies one tyrosyl residue. Subsequent nitration of the azoenzyme has no further effect on esterase activity, decreases peptidase activity markedly, and modifies a second tyrosyl residue. Analysis of the azopeptides isolated from a chymotrypsin digest of the doubly modified enzyme by affinity, ion exchange, and high pressure liquid chromatography indicates that the principal residue modified by diazo-1H-tetrazole is Tyr-248. Analysis of the nitropeptides isolated by similar procedures indicates that nitration occurs mainly at Tyr-198. This residue becomes susceptible to modification only as a consequence of a conformational change that accompanies azo coupling of Tyr-248. These results describe a unique example of the influence of protein structure on the reactivity of functional amino acid residues and illustrate an important aspect of chemical modification of enzymes.     

Nitration of solvent-exposed tyrosine 74 on cytochrome c triggers heme iron-methionine 80 bond disruption. Nuclear magnetic resonance and optical spectroscopy studies

Cytochrome c, a mitochondrial electron transfer protein containing a hexacoordinated heme, is involved in other physiologically relevant events, such as the triggering of apoptosis, and the activation of a peroxidatic activity. The latter occurs secondary to interactions with cardiolipin and/or post-translational modifications, including tyrosine nitration by peroxynitrite and other nitric oxide-derived oxidants. The gain of peroxidatic activity in nitrated cytochrome c has been related to a heme site transition in the physiological pH region, which normally occurs at alkaline pH in the native protein. Herein, we report a spectroscopic characterization of two nitrated variants of horse heart cytochrome c by using optical spectroscopy studies and NMR. Highly pure nitrated cytochrome c species modified at solvent-exposed Tyr-74 or Tyr-97 were generated after treatment with a flux of peroxynitrite, separated, purified by preparative high pressure liquid chromatography, and characterized by mass spectrometry-based peptide mapping. It is shown that nitration of Tyr-74 elicits an early alkaline transition with a pKa = 7.2, resulting in the displacement of the sixth and axial iron ligand Met-80 and replacement by a weaker Lys ligand to yield an alternative low spin conformation. Based on the study of site-specific Tyr to Phe mutants in the four conserved Tyr residues, we also show that this transition is not due to deprotonation of nitro-Tyr-74, but instead we propose a destabilizing steric effect of the nitro group in the mobile Omega-loop of cytochrome c, which is transmitted to the iron center via the nearby Tyr-67. The key role of Tyr-67 in promoting the transition through interactions with Met-80 was further substantiated in the Y67F mutant. These results therefore provide new insights into how a remote post-translational modification in cytochrome c such as tyrosine nitration triggers profound structural changes in the heme ligation and microenvironment and impacts in protein function.     

Environment and conformation dependent sensitivity of the arsanilazotyrosine-248 carboxypeptidase A chromophore.

Reaction of carboxypeptidase A crystals with diazotized arsanilic acid uniquely modifies Tyr-248 to form a monazo derivative, which-in solution-forms an intramolecular inner-sphere coordination complex in the active site zinc atom. tarsanilazocarboxypeptidase exhibits spectral properties that are closely similar to those of the model complex, tetrazolylazo-N-carbobenzoxytyrosine Zn2+, with a distinctive maximum at 510 nm. In addition, its circular dichroic spectrum reveals a negative extremum at this wavelength, also characteristic of this complex. Both spectra are exquisitely responsive to pth changes and serve to monitor formation and dissociation of the metal-azophenol complex. Two pKapp at 7.7 and 9.5 delineate the pH range over which the probe characteristics most effectively gauge conformational features of the active center of arsanilazcarboxypeptidase. Other environmental parameters, e.g., substrates and inhibitors, as well as crystallization of the enzyme also critically influence the formation and dissociation of the complex; the response of the probe suggests that they induce conformational movement of the azoTyr-248 residue away from the zinc atom. tthe now available chemical, functional, structural data bearing on the spatial relationships of Tyr-248 and Zn, both thought critical to catalysis, are evaluated, based on spectra of arsanilazo- and nitrocarboxypeptidase crystals and solutions as well as on detailed kinetic analyses of the native enzyme in both physical states and based on the X-ray structure analysis of the native enzyme and its Gly-L-Tyr complex. Collectively all of the data show that the conformation of carboxypeptidase in crystals differs from that in solution. Moreover, reexamination of the original X-ray maps reported in 1968 and thought to preclude a Tyr-248-Zn interaction now leads to the conclusion that in up to 25 per cent of the molecules in the crystals ttyr-248 interacts with the active site zinc atom (W.D. Lipscomb (1973), Proc. Nat. Acad. Sci U.S. 70, 3797). Thus, even in the crystals the enzyme exists in at least two different conformations. In one of these Tyr-248 is near while in the other it is far from the zinc atom. The spectral effects of Gly-L-Tyr and beta-phenylpropionate on solutions of arsanilazo- and of nitrocarboxypeptidase demonstrate that during the catalytic process Tyr-248 moves away from the zinc atom. This implies a mechanistic role for Tyr-248 different from that postulated on the basis of X-ray crystallographic analysis. Indeed, the proximity of ttyr-248 to the zinc atom, when altered by substrates and inhibitor, may reflect certain of the properties characteristic of the entatic, active site.     

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.     

Transition of environmental polarity of tyrosine-76 of Trimeresurus flavoviridis phospholipase A2 upon active site ligand binding

Modification of Trimeresurus flavoviridis phospholipase A2 with a 5-fold molar excess of tetranitromethane produced 40% active mononitrotyrosyl phospholipase A2 in which Tyr-76 was specifically nitrated. This is in contrast to the case of mammalian pancreatic phospholipases A2 where Tyr-70 but not Tyr-76 was nitrated. When Ca2+ was bound to T. flavoviridis mononitrotyrosyl phospholipase A2, nitrated tyrosine (Tyr(NO2))-76 moved from a less polar site to a polar site with the decrease of the pKa value of its hydroxyl group. Nitration of Tyr-76 did not influence the binding affinity to Ca2+. Addition of laurylphosphorylcholine to mononitrotyrosyl phospholipase A2 in the presence of Ca2+ caused the movement of Tyr(NO2)-76 from a polar environment to a less polar environment with the rise in the pKa value. Tyrosine-76 is located in the site whose environmental polarity is affected by the binding of the ligands to the active site. As Tyr-76 is located in the site not proximal to the active site, it could be assumed that the conformational change induced by the binding of the ligands extends to the region remote from the active site in T. flavoviridis phospholipase A2. This might provide evidence of long-range diffusional coupling between remote sites in the noncooperative globular protein.     

Fluorescence studies of native and modified neurophysins. Effects of peptides and pH.

The effect of neurophysin-hormone interaction on the environment of the single tyrosine of bovine neurophysin (Tyr-49) and on that of the tyrosine of oxytocin and vasopressin was studied by fluorescence; tyrosine-free peptides were used to determine effects on Tyr-49, and acetylated neurophysin was used to determine effects on the hormone tyrosine. Binding increases the fluorescence intensity of Tyr-49 by 130% while the fluorescence of the hormone tyrosine is almost completely quenched. Correlation of these results with those obtained on binding oxytocin or vasopressin to native neurophysin indicates that in the hormone complexes less than half of the fluorescence of Tyr-49 is lost by F?rster energy transfer to the quenched hormone tyrosine. These results support spin-label studies in indicating that the distance between Tyr-49 and the tyrosine of hormone bound to the strong hormone binding site is greater than 5 A. In the absence of peptides, the fluorescence of Tyr-49 increases by 40% on lowering the pH from 6.2 to 2. Titration of the acid fluorescence transition in bovine neurophysins-I and -II, and in bovine neurophysin-II treated with carboxypeptidase B to remove the Arg-Arg-Val sequence at the carboxyl terminus, indicates that this transition is due to titration of a side-chain carboxyl with an intrinsic pK of 4.6. The effects of guanidine, glycerol, and disulfide cleavage on the magnitude of the acid transition indicate that the conformational information necessary for the transition resides within the amino acid sequence adjacent to Tyr-49. Accordingly, the fluorescence acid transition is attributed to decreased quenching by Glu-46 or Glu-47 upon protonation. Glycerol is shown to perturb the glutamate-tyrosine interaction in the absence of general conformational effects. Comparison of the fluorescence low-pH transition with that of the low-pH circular dichroism transition of nitrated neurophysins suggests that the fluorescence and CD transitions reflect related, but not necessarily identical, phenomena. In an appendix, evidence is presented which suggests that the products of carboxy-peptidase digestion of bovine neurophysin-II are the same as two minor bovine neurophysin components, one of which is neurophysin-C.     

Tyrosine 385 of prostaglandin endoperoxide synthase is required for cyclooxygenase catalysis

There are spectral and biochemical data suggesting that a tyrosine group(s) is involved in the cyclooxygenase reaction catalyzed by prostaglandin endoperoxide (PGH) synthase. Treatment with tetranitromethane, a reagent which nitrates tyrosine residues, abolishes cyclooxygenase activity, but this inactivation can be largely prevented by competitive cyclooxygenase inhibitors such as ibuprofen and indomethacin. To identify sites of nitration, native PGH synthase and indomethacin-pretreated PGH synthase were incubated with tetranitromethane, and the sequences of peptides containing nitrotyrosine were determined. Three unique tyrosines (Tyr-355, Tyr-385, and Tyr-417) were nitrated in the native enzyme but not in the indomethacin-treated PGH synthase. Using site-directed mutagenesis of sheep PGH synthase, each of these tyrosines, as well as two other tyrosine residues selected as controls (Tyr-254 and Tyr-262), were replaced with phenylalanine; cos-1 cells were transfected with constructs containing cDNAs coding for the native PGH synthase and each of the five phenylalanine mutants, and microsomes from these cells were assayed for cyclooxygenase and hydroperoxidase activities. The Phe-385 mutant of PGH synthase lacked cyclooxygenase activity but retained peroxidase activity; all other mutants expressed both enzyme activities. Our results establish that Tyr-385 is essential for the cyclooxygenase activity of PGH synthase and that nitration of this residue can be prevented by indomethacin. We conclude that Tyr-385 is at or near the cyclooxygenase active site of PGH synthase and could be the tyrosine residue proposed to be involved in the first step of the cyclooxygenase reaction, abstraction of the 13-proS hydrogen from arachidonate.     

[Nitrotyrosyl]cytochrome c. Studies of the effect of iron binding, protein denaturants and oxidation-reduction potentials.

Static measurements of the reaction of ligand binding were done by conventional spectrophotometry. The ligand-binding reactions with nitrated cytochrome c were performed with imidazole, iminazole, CO and NO. The stoicheiometry was found to be 1:1, and the stability constants for the complexes formed between the nitrated cytochrome c and the ligands are: 2.58 X 10(4) M-1 (imidazole); 1.01 X 10(2) M-1 (iminazole); 3.6 X 10(4) M-1 (CO); 2.74 X 10(4) M-1 (NO). It was found that the electrometric potentials at pH 7.0 and 25degreesC of [aminotyrosyl]cytochrome c are E'o form II = 0.115 V and E'o form I = 0.260 V, where forms I and II are two species of protein co-existing in the protein solution. The isoelectric point for the oxidized form of [nitrotyrosyl]cytochrome c was 10.05, at 4degreesC.     

Localization of nitration and chlorination sites on apolipoprotein A-I catalyzed by myeloperoxidase in human atheroma and associated oxidative impairment in ABCA1-dependent cholesterol efflux from macrophages

We recently reported that apolipoprotein A-I (apoA-I), the major protein component of high density lipoprotein, is a selective target for myeloperoxidase (MPO)-catalyzed nitration and chlorination in both and serum of subjects with cardiovascular disease. We further showed that the extent of both apoA-I nitration and chlorination correlated with functional impairment in reverse cholesterol transport activity of the isolated lipoprotein. Herein we used tandem mass spectrometry to map the sites of MPO-mediated apoA-I nitration and chlorination in vitro and in vivo and to relate the degree of site-specific modifications to loss of apoA-I lipid binding and cholesterol efflux functions. Of the seven tyrosine residues in apoA-I, Tyr-192, Tyr-166, Tyr-236, and Tyr-29 were nitrated and chlorinated in MPO-mediated reactions. Site-specific liquid chromatography-mass spectrometry quantitative analyses demonstrated that the favored modification site following exposure to MPO-generated oxidants is Tyr-192. MPO-dependent nitration and chlorination both proceed with Tyr-166 as a secondary site and with Tyr-236 and Tyr-29 modified only minimally. Parallel functional studies demonstrated dose-dependent losses of ABCA1-dependent cholesterol acceptor and lipid binding activities with apoA-I modification by MPO. Finally tandem mass spectrometry analyses showed that apoA-I in human atherosclerotic tissue is nitrated at the MPO-preferred sites, Tyr-192 and Tyr-166. The present studies suggest that site-specific modifications of apoA-I by MPO are associated with impaired lipid binding and ABCA1-dependent cholesterol acceptor functions, providing a molecular mechanism that likely contributes to the clinical link between MPO levels and cardiovascular disease risk.     

Evidence for an essential glutamyl residue in yeast hexokinase.

Yeast hexokinase is rapidly inactivated by 1-cyclohexyl-3-(2-morpholinoethyl)carbodiimide metho-p-toluenesulfonate and nitrotyrosyl ethyl ester. Sugar substrates afford a partial protection, which is increased by the addition of ADP. Inactivation of the enzyme takes place concomitantly with the incorporation of 1 mol of nitrotyrosine per mol of 50 000-dalton subunit. Exhaustive proteolytic digestion of the modified protein and isolation of the nitrotyrosyl peptide by affinity chromatography, followed by electrophoresis, lead to the identification of the modified residue as a glutamyl residue. This modification of hexokinase occurs without gross conformational changes. The enzyme still binds its substrates, though binding of the nucleotides is perturbed. While the substrates afford a partial protection, they increase the incorporation of nitrotyrosine ethyl ester into the enzyme. This may be attributed to local conformational changes which their binding induces. It is concluded that a glutamyl residue is essential for yeast hexokinase activity and its catalytic function is discussed.     

F0 portion of Escherichia coli ATP synthase: orientation of subunit c in the membrane

Incubation of right-side-out oriented membrane vesicles of Escherichia coli with tetranitromethane resulted in the nitration of tyrosine residues (Tyr-10 and Tyr-73) of subunit c from the ATP synthase. Cleavage of the protein with cyanogen bromide and separation of the resulting fragments, especially of the tyrosine-containing peptides, clearly demonstrated that the distribution of the nitro groups is similar at any time and at any pH value chosen for the analysis. Furthermore, the percentage of 3-nitrotyrosine present in the two peptide fragments was in good agreement with that obtained for the intact polypeptide chain. While the modification of the tyrosine residues in subunit c with the lipophilic tetranitromethane is independent of the orientation of the membrane vesicles, the subsequent partial conversion of the 3-nitrotyrosine to the amino form only occurred when membrane vesicles with right-side-out orientation were treated with the ionic, water-soluble sodium dithionite, which at certain concentrations cannot penetrate biological membranes. Cleavage of subunit c isolated from nitrated and subsequently reduced membrane vesicles and separation of the resulting fragments by high-pressure liquid chromatography showed that the 3-nitrotyrosine in the Tyr-73-containing peptides has been completely reduced, while the nitro group in peptides containing Tyr-10 remained nearly unaffected.     

Inhibition of peroxisomal hydroxypyruvate reductase (HPR1) by tyrosine nitration

Background

Protein tyrosine nitration is a post-translational modification (PTM) mediated by nitric oxide-derived molecules. Peroxisomes are oxidative organelles in which the presence of nitric oxide (NO) has been reported.

Methods

We studied peroxisomal nitroproteome of pea leaves by high-performance liquid chromatography with tandem mass spectrometry (LC–MS/MS) and proteomic approaches.

Results

Proteomic analysis of peroxisomes from pea leaves detected a total of four nitro-tyrosine immunopositive proteins by using an antibody against nitrotyrosine. One of these proteins was found to be the NADH-dependent hydroxypyruvate reductase (HPR). The in vitro nitration of peroxisomal samples caused a 65% inhibition of HPR activity. Analysis of recombinant peroxisomal NADH-dependent HPR1 activity from Arabidopsis in the presence of H₂O₂, NO, GSH and peroxynitrite showed that the ONOO⁻ molecule caused the highest inhibition of activity (51% at 5 mM SIN-1), with 5 mM H₂O₂ having no inhibitory effect. Mass spectrometric analysis of the nitrated recombinant HPR1 enabled us to determine that, among the eleven tyrosine present in this enzyme, only Tyr-97, Tyr-108 and Tyr-198 were exclusively nitrated to 3-nitrotyrosine by peroxynitrite. Site-directed mutagenesis confirmed Tyr198 as the primary site of nitration responsible for the inhibition on the enzymatic activity by peroxynitrite.

Conclusion

These findings suggest that peroxisomal HPR is a target of peroxynitrite which provokes a loss of function.

General significance

This is the first report demonstrating the peroxisomal NADH-dependent HPR activity involved in the photorespiration pathway is regulated by tyrosine nitration, indicating that peroxisomal NO metabolism may contribute to the regulation of physiological processes under no-stress conditions.