Deuterium and nitrogen pure quadrupole resonance in amino acids. II

Probing amide bond nitrogens in solids using 14N NMR spectroscopy

A novel two-dimensional nuclear magnetic resonance (NMR) experiment is proposed for indirect observation of 14N nuclei in various types of nitrogen-containing solids. In a method somewhat similar to the heteronuclear single-quantum correlation (HSQC) experiment widely used for protein structure determination in solutions, this technique correlates spin S=1/2 nuclei, e.g., 1H, 13C, with the 14N spin I=1 nucleus in solids. The present experiment, however, transfers coherence from neighboring 1H or 13C nuclei to 14N via a combination of J-couplings and residual dipolar splittings (RDS). Projections of the two-dimensional NMR spectra onto the 14N dimension yield powder patterns that reflect the 14N quadrupolar interaction, which can be used to study molecular structure and dynamics. Indirect detection of amide nitrogen-14 via 1H and 13C is shown experimentally on a model compound of N-acetyl-glycine.

Nuclear magnetic resonance structural investigations of ammonia-doped fullerides

The dynamic and structural properties of the ammonia-doped superconducting fulleride (NH3)xNaK2C60 (0.5< or =x< or =1), well known for its anomalous decrease of transition temperature with doping, have been investigated using sodium and deuterium solid-state NMR techniques. The independence of 23Na quadrupole splitting from the ammonia content x, which, at the same time, substantially affects Tc, suggests a marginal role of the cation position in the superconducting mechanism. On the other hand, a strong reduction of the deuterium quadrupole coupling with respect to the free ammonia value denotes the presence of weak hydrogen bonds between the deuterium atoms and fullerene pi orbitals. Despite the bond weakness, as evinced by the lively ammonia rotational dynamics even at very low temperatures, the resulting electron localization could explain the observed Tc anomaly. The motion of the ND3-Na group (located in the compound's octahedral voids), as well as the evolution of the ammonia dynamics as a function of temperature, were determined from deuterium NMR line shape analysis and from detailed numerical simulations. While at the lowest measured temperatures only the ammonia rotation around its own C3 axis takes place, above approximately 25 and 70 K, respectively, also the wobbling of the C3 axis and the ND3 relocation become active, successfully modeled by a strongly correlated motion involving two different time scales.

Identification of a putative histidine base and of a non-protein nitrogen ligand in the active site of Fe-hydrogenases by one-dimensional and two-dimensional electron spin-echo envelope-modulation spectroscopy

The active H-cluster of the Fe-hydrogenases from Megasphaera elsdenii and Desulfovibrio vulgaris (strain Hildenborough) has been investigated with one- and two-dimensional pulsed EPR spectroscopy. In both complexes the coordination of a nitrogen-containing ligand was found. The unusual quadrupole interaction parameters (D. vulgaris: quadrupole coupling constant, K = 1.20 MHz, asymmetry parameter eta = 0.32, M. elsdenii: K = 1.23 MHz, eta = 0.25) indicate a non-protein type of nitrogen and are consistent with cyanide as ligand to the H-cluster. The additional interactions measured on the EPR signal of the inactivated H-cluster in D. vulgaris hydrogenase are consistent with an imidazole interaction similar to that found in Rieske-type iron-sulfur clusters. Since a His residue near the putative H-cluster binding motif of Cys residues, His371, is the only conserved His in Fe-hydrogenases, it is a likely candidate for the base that accepts the proton in the heterolytic cleavage of molecular hydrogen. The inactivation of the enzyme is accompanied by direct binding of the imidazole ring to the H-cluster.