Your search keyword '"Tetranitromethane chemistry"' showing total 5 results

1. Probing structural differences in prion protein isoforms by tyrosine nitration.

Author

Lennon CW, Cox HD, Hennelly SP, Chelmo SJ, and McGuirl MA

Subjects

Amino Acid Sequence, Animals, Circular Dichroism, Cricetinae, Hot Temperature, Mesocricetus, Peroxynitrous Acid chemistry, PrPC Proteins chemistry, Protein Denaturation, Protein Isoforms chemistry, Spectrometry, Mass, Electrospray Ionization, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Tandem Mass Spectrometry, Tetranitromethane chemistry, Prions chemistry, Tyrosine chemistry

Abstract

Two conformational isomers of recombinant hamster prion protein (residues 90-232) have been probed by reaction with two tyrosine nitration reagents, peroxynitrite and tetranitromethane. Two conserved tyrosine residues (tyrosines 149 and 150) are not labeled by either reagent in the normal cellular form of the prion protein. These residues become reactive after the protein has been converted to the beta-oligomeric isoform, which is used as a model of the fibrillar form that causes disease. After conversion, a decrease in reactivity is noted for two other conserved residues, tyrosine 225 and tyrosine 226, whereas little to no effect was observed for other tyrosines. Thus, tyrosine nitration has identified two specific regions of the normal prion protein isoform that undergo a change in chemical environment upon conversion to a structure that is enriched in beta-sheet.

Published

2007

2. Time course and site(s) of cytochrome c tyrosine nitration by peroxynitrite.

Author

Batthyány C, Souza JM, Durán R, Cassina A, Cerveñansky C, and Radi R

Subjects

Amino Acid Sequence, Animals, Electron Transport, Horses, Mitochondria, Heart enzymology, Molecular Sequence Data, Peroxidase chemistry, Peroxynitrous Acid metabolism, Potassium Cyanide chemistry, Rats, Sodium Cyanide chemistry, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Tetranitromethane chemistry, Time Factors, Cytochromes c chemistry, Cytochromes c metabolism, Peroxynitrous Acid chemistry, Tyrosine metabolism

Abstract

Cytochrome c-dependent electron transfer and apoptosome activation require protein-protein binding, which are mainly directed by conformational and specific electrostatic interactions. Cytochrome c contains four highly conserved tyrosine residues, one internal (Tyr67), one intermediate (Tyr48), and two more accessible to the solvent (Tyr74 and Tyr97). Tyrosine nitration by biologically-relevant intermediates could influence cytochrome c structure and function. Herein, we analyzed the time course and site(s) of tyrosine nitration in horse cytochrome c by fluxes of peroxynitrite. Also, a method of purifying each (nitrated) cytochrome c product by cation-exchange HPLC was developed. A flux of peroxynitrite caused the time-dependent formation of different nitrated species, all less positively charged than the native form. At low accumulated doses of peroxynitrite, the main products were two mononitrated cytochrome c species at Tyr97 and Tyr74, as shown by peptide mapping and mass spectrometry analysis. At higher doses, all tyrosine residues in cytochrome c were nitrated, including dinitrated (i.e., Tyr97 and Tyr67 or Tyr74 and Tyr67) and trinitrated (i.e., Tyr97, Tyr74, and Tyr67) forms of the protein, with Tyr67 well represented in dinitrated species and Tyr48 being the least prone to nitration. All mono-, di-, and trinitrated cytochrome c species displayed an increased peroxidase activity. Nitrated cytochrome c in Tyr74 and Tyr67, and to a lesser extent in Tyr97, was unable to restore the respiratory function of cytochrome c-depleted mitochondria. The nitration pattern of cytochrome c in the presence of tetranitromethane (TNM) was comparable to that obtained with peroxynitrite, but with an increased relative nitration yield at Tyr67. The use of purified and well-characterized mono- and dinitrated cytochrome c species allows us to study the influence of nitration of specific tyrosines in cytochrome c functions. Moreover, identification of cytochrome c nitration sites in vivo may assist in unraveling the chemical nature of proximal reactive nitrogen species.

Published

2005

3. Identification of an essential tyrosine residue in nitroalkane oxidase by modification with tetranitromethane.

Author

Gadda G, Banerjee A, and Fitzpatrick PF

Subjects

Amino Acid Sequence, Binding Sites drug effects, Enzyme Activation drug effects, Enzyme Inhibitors chemistry, Enzyme Inhibitors metabolism, Enzyme Inhibitors pharmacology, Flavin-Adenine Dinucleotide chemistry, Fusarium enzymology, Indicators and Reagents, Kinetics, Molecular Sequence Data, Oxygenases antagonists & inhibitors, Oxygenases chemistry, Tyrosine chemistry, Dioxygenases, Oxygenases metabolism, Tetranitromethane chemistry, Tetranitromethane metabolism, Tetranitromethane pharmacology, Tyrosine metabolism

Abstract

The flavoprotein nitroalkane oxidase from Fusarium oxysporum catalyzes the oxidation of nitroalkanes to the respective aldehydes or ketones with production of nitrite and hydrogen peroxide. The enzyme is irreversibly inactivated by incubation with tetranitromethane, a tyrosine-directed reagent, at pH 7.3. The inactivation is time-dependent and shows first-order kinetics for two half-lives of inactivation. Further inactivation can be achieved upon a second addition of tetranitromethane. A saturation kinetic pattern is observed when the rate of inactivation is determined versus the concentration of tetranitromethane, indicating that a reversible enzyme-inhibitor complex is formed before irreversible inactivation occurs. Values of 0.096 +/- 0.013 min(-1) and 12.9 +/- 3.8 mM were determined for the first-order rate constant for inactivation and the dissociation constant for the reversibly formed complex, respectively. The competitive inhibitor valerate protects the enzyme from inactivation by tetranitromethane, suggesting an active-site-directed inactivation. The UV-visible absorbance spectrum of the inactivated enzyme is perturbed with respect to that of the native enzyme, suggesting that treatment with tetranitromethane resulted in nitration of the enzyme. Comparison of tryptic maps of nitroalkane oxidase treated with tetranitromethane in the presence and absence of valerate shows a single peptide differentially labeled in the inactivated enzyme. The spectral properties of the modified peptide are consistent with nitration of a tyrosine residue. The amino acid sequence of the nitrated peptide is L-L-N-E-V-M-C-(NO(2)-Y)-P-L-F-D-G-G-N-I-G-L-R. The possible role of this tyrosine in substrate binding is discussed.

Published

2000

4. HlyC, the internal protein acyltransferase that activates hemolysin toxin: the role of conserved tyrosine and arginine residues in enzymatic activity as probed by chemical modification and site-directed mutagenesis.

Author

Trent MS, Worsham LM, and Ernst-Fonberg ML

Subjects

Acetyltransferases genetics, Acetyltransferases physiology, Amino Acid Sequence, Amino Acid Substitution genetics, Arginine genetics, Bacterial Proteins genetics, Bacterial Proteins physiology, Bacterial Toxins genetics, Enzyme Activation genetics, Escherichia coli, Hemolysin Proteins genetics, Hemolysin Proteins physiology, Imidazoles chemistry, Molecular Sequence Data, Phenylglyoxal chemistry, Sulfhydryl Reagents chemistry, Tetranitromethane chemistry, Tyrosine genetics, Acetyltransferases chemistry, Acyltransferases, Arginine chemistry, Bacterial Proteins chemistry, Bacterial Toxins chemistry, Escherichia coli Proteins, Hemolysin Proteins chemistry, Mutagenesis, Site-Directed, Tyrosine chemistry

Abstract

Internal fatty acylation of proteins is a recognized means of modifying biological behavior. Escherichia coli hemolysin A (HlyA), a toxic protein, is transcribed as a nontoxic protein and made toxic by internal acylation of two lysine residue epsilon-amino groups; HlyC catalyzes the acyl transfer from acyl-acyl carrier protein (ACP), the obligate acyl donor. Conserved residues among the respective homologous C proteins that activate 13 different RTX (repeats in toxin) toxins of which HlyA is the prototype likely include some residues that are important in catalysis. Possible roles of two conserved tyrosines and two conserved arginines were investigated by noting the effects of chemical modifiers and site-directed mutagenesis. TNM modification of HlyC at pH 8.0 led to extensive inhibition that was prevented by the presence of the substrate myristoyl-ACP but not by the product, ACPSH. NAI had no effect. Y70G and Y150G greatly diminished enzyme activity, whereas mutations Y70F and Y150F exhibited wild-type activity. Modification of arginine residues with PG markedly lowered acyltransferase activity with moderate protection by both myristoyl-ACP and ACPSH. Under optimum conditions, four separate mutations of the two conserved arginine residues (R24A, R24K, R87A, and R87K) had little effect on acyltransferase activity.

Published

1999

5. Chemical modification of the urokinase-type plasminogen activator and its receptor using tetranitromethane. Evidence for the involvement of specific tyrosine residues in both molecules during receptor-ligand interaction.

Author

Ploug M, Rahbek-Nielsen H, Ellis V, Roepstorff P, and Danø K

Subjects

Amino Acid Sequence, Animals, Humans, Ligands, Molecular Sequence Data, Protein Conformation, Receptors, Cell Surface chemistry, Receptors, Urokinase Plasminogen Activator, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Tetranitromethane chemistry, Tyrosine chemistry, Urokinase-Type Plasminogen Activator chemistry

Abstract

The high-affinity interaction between urokinase-type plasminogen activator (uPA) and its glycolipid anchored receptor (uPAR) is essential for the confinement of plasminogen activation to cell surfaces where it is thought to play an important role in cancer cell invasion and metastasis. The receptor binding site of uPA is retained within its isolated growth factor-like module (GFD; residues 4-43). The NH2-terminal domain of uPAR has a primary role in uPA binding, although maintenance of its multidomain structure has been shown to be necessary for the high affinity of this interaction [Ploug, M., Ellis, V., & Danø, K. (1994) Biochemistry 33, 8991-8997]. To identify residues engaged in the uPAR-uPA interaction, we have performed a "protein-protein footprinting" study on preformed uPAR-GFD complexes by chemical modification with tetranitromethane. All six tyrosine residues in uPAR and the single tyrosine residue in GFD (Tyr24) were susceptible to nitration in the native uncomplexed proteins, whereas in the receptor-ligand complexes both Tyr57 of uPAR and Tyr24 of GFD were protected from modification. Modification of uPAR alone led to a parallel reduction in the potential to bind pro-uPA and 8-anilino-1-naphthalenesulfonate, an extrinsic fluorophore reporting on the accessibility of a hydrophobic site involved in uPA binding. These data clearly demonstrate that Tyr57 in the NH2-terminal domain of uPAR and Tyr24 in uPA are intimately engaged in the receptor-ligand interaction, whereas Tyr87 positioned in the linker region between the first two domains of uPAR does not appear to be shielded by the resulting intermolecular interface.

Published

1995