Chemical modifications of the vasoconstrictor peptide angiotensin II by nitrogen oxides (NO, HNO2, HOONO)--evaluation by mass spectrometry.

Nitric oxide (NO) and angiotensin II are natural regulators of blood pressure. Under aerobic conditions, NO is transformed into its higher oxides (N2O4, NO2, NO/NO2 or N2O3) and oxoperoxonitrate (currently named peroxynitrite) by coupling with superoxide. Previous studies have shown that these reactive nitrogen species should be involved in vivo in the transformation of cysteine and tyrosine into the corresponding nitrosothiol and 3-nitrotyrosine. In the present study, attention has been focused on the relative reactivities of HNO2, peroxynitrite, and NO in the presence of dioxygen, towards the arginine and tyrosine residues of the peptide angiotensin II. Nitration of the tyrosine residue is clearly the main reaction with peroxynitrite. By contrast, besides 20% of nitration of the tyrosine residue, NO in the presence of dioxygen leads to nitrosation reactions with the arginine residue similar to those observed with HNO2 at pH 5, possibly through the intermediate N2O3 reactive species. Angiotensin II is converted for the most part to peptides having lost either a terminal amine function or the whole guanido group, leading respectively to citrulline-containing angiotensin II or to a diene derivative. Identification established mainly by tandem mass spectrometry of peptidic by-products allows us to propose a cascade of nitrosations of all the amine functions of the arginine residue. Further in vivo studies show that transformations of the arginine residue in angiotensin II do not alter its vasoconstrictive properties, whereas nitration of the tyrosine residue totally inhibits them.

Common structural features of UUCG and UACG tetraloops in very short hairpins determined by UV absorption, Raman, IR and NMR spectroscopies.

Thermodynamic and structural properties of two UNCG tetraloops in very short hairpin octamers, 5'-r(GCUUCGGC)-3' and 5'-r(GCUACGGC)-3', have been studied by means of various physical techniques. Melting profiles of both octamers, obtained from UV absorption spectra taken as a function of temperature, are consistent with a monophasic, progressive and completely reversible order-to-disorder transition and confirm their unusual structural stability (Tm > 51 degrees C). The 1H, 13C and 31P NMR chemical shifts and coupling constants of the UACG loop nucleotides are comparable with those reported previously for UUCG loops, i.e. 2'-endo/anti conformation of the second and third nucleotide of the loop as well as the syn orientation of the ultimate guanine base and the A-type double helical conformation of the hairpin stem. Simulation of quantitative NOESY volumes shows that the UACG octamer adopts a very rigid compact structure which is well represented by an average order parameter of 0.9. Three base-pairs and four additional strong hydrogen bonds are undoubtedly responsible for such limited flexibility. Raman and infrared spectra as a function of temperature reflect the order-to-disorder transition, as well. Vibrational conformational markers in low temperature spectra of both octamers indicate the hairpin structure as the major conformer in aqueous phase. These spectra further support the structural features of most of the nucleotides involved in the tetraloops and clearly demonstrate the structural similarities of the phosphodiester backbone in both hairpins. Consequently, on the basis of all present results, one can deduce that the conformational features of the UUCG and UACG tetraloops seem to be inherent to the UNCG type tetraloops, regardless of either the nature of the tetraloop second base or the stem length.

NMR analysis of carbohydrates with model-free spectral densities: the dispersion range revisited.

Over the past decade molecular mechanics and molecular dynamics studies have demonstrated considerable flexibility for carbohydrates. In order to interpret the corresponding NMR parameters, which correspond to a time-averaged or 'virtual' conformer, it is necessary to simulate the experimental data using the averaged geometrical representation obtained with molecular modelling methods. This structural information can be transformed into theoretical NMR data using empirical Karplus-type equations for the scalar coupling constants and the appropriate formalism for the relaxation parameters. In the case of relaxation data, the 'model-free' spectral densities have been widely used in order to account for the internal motions in sugars. Several studies have been conducted with truncated model-free spectral densities based on the assumption that internal motion is very fast with respect to overall tumbling. In this report we present experimental and theoretical evidence that suggests that this approach is not justified. Indeed, recent results show that even in the case of moderate-sized carbohydrates internal motions are occurring on the same timescale as molecular reorientation. Simulations of relaxation parameters (NOESY volumes, proton cross-relaxation rates, carbon T1 and nOe values) in the dispersion range (0.1 < tau(c) < 5 ns) show that rates of internal motion can be fairly precisely defined with respect to overall tumbling. Experimental data for a variety of oligosaccharides clearly indicate similar timescales for internal and overall motion.

Conformational analysis of disaccharides using molecular dynamics and NMR methods.

The internal dynamics of four disaccharides, a galacturonic acid dimer, beta-ethyl-lactoside, sucralose and arabinobiose, have been studied using molecular dynamics and nuclear magnetic resonance methods. Theoretical motion models, which include order parameters and correlation times for internal motions, were extracted from dynamics trajectories in vacuo. In parallel, theoretical NOESY volumes were calculated from averaged distance matrices using 'model-free' spectral densities. These data were least-squares fitted to the normalized experimental NOESY volumes using the order parameters and internal motion correlation times as adjustable parameters. The resulting 'experimental' motional models were in good agreement with the theoretical ones with the exception of the galacturonic acid dimer which was best described by the rigid molecule approximation.

Thermodynamic and structural properties of r(ACC) as revealed by ultraviolet electronic absorption, circular dichroism, 1H-NMR spectroscopy and Monte Carlo simulations.

UV absorption, circular dichroism (CD) and 1H NMR, associated with Monte Carlo (MC) molecular structure simulations have been applied to the study of the trinucleoside diphosphate: r(ACC). The MC study which has been conducted as a function of temperature, is based on random variations of the nucleotide conformational angles, i.e. phosphodiester chain torsional angles and sugar pucker pseudorotational angles. All of the chemical bond lengths and valence angles remained fixed during the structural simulation, except those of the sugar pucker. Six different initial structures have been selected in order to explore the molecular conformational space as completely as possible. This simulation procedure led to distinct families of equilibrium conformations at 283, 298 and 318 K. The thermodynamical parameters such as variations in entropy, enthalpy and also melting temperature (delta SX0, delta HX0 and Tm) of the stacking (X) equilibrium were obtained from UV absorption and circular dichroism (CD) spectra recorded over a 80K temperature range. Chemical shifts (delta), vicinal coupling constants (3Jk,l), and cross-relaxation rate (sigma k,l) of trimers were measured at 400.13 MHz over a range of concentrations (2-13 mM) and temperatures (283-333K). Least-squares fitting of the experimental chemical shifts to simple models of association (A) and stacking equilibria allowed separation of the variations in the delta values (delta delta X and delta delta A) due to either phenomenon. The three NMR data sets (delta delta X, 3Jk,l, and sigma k,l) were then evaluated for the minima conformers obtained with the MC stimulations. Theoretical values of delta delta X were estimated using the results of an ab initio study while the coupling constant data were simulated with Karplus-type equations. Finally, the relaxation data were simulated from the distance matrices using treatment for cases of both slow conformational exchange accompanied by rapid small-amplitude fluctuations about the minima structures. A consistent picture of the large amplitude deformations (torsional angle variation) of these trimers has emerged from the present study. Optimized conformational blends at 283,296 and 318K were obtained by least-squares fitting of the experimental data to the theoretical ones, while considering the populations as adjustable parameters. As it would be expected, the right-handed helical conformation (A-RNA type) is found to be the major stacked species, in the temperature range of 283 to 318K. Limited evidence for bulged structures has been obtained, whereas novel reverse-stacked and half-stacked conformers also presented theoretical data compatible with the NMR observables of aqueous r(ACC).