Dynamics of backbone conformational heterogeneity in Bacillus subtilis ribonuclease P protein.

Interconversion of protein conformations is imperative to function, as evidenced by conformational changes associated with enzyme catalytic cycles, ligand binding and post-translational modifications. In this study, we used 15N NMR relaxation experiments to probe the fast (i.e.

Differential helix stabilities and sites pre-organized for tertiary interactions revealed by monitoring local nucleotide flexibility in the bI5 group I intron RNA.

The local environment at adenosine residues in the bI5 group I intron RNA was monitored as a function of Mg(2+) using both the traditional method of dimethyl sulfate (DMS) N1 methylation and a new approach, selective acylation of 2'-amine substituted nucleotides. These probes yield complementary structural information because N1 methylation reports accessibility at the base pairing face, whereas 2'-amine acylation scores overall residue flexibility. 2'-Amine acylation robustly detects RNA secondary structure and is sensitive to higher order interactions not monitored by DMS.

Catalysis of amide synthesis by RNA phosphodiester and hydroxyl groups.

The functional groups found among the RNA bases and in the phosphoribose backbone represent a limited repertoire from which to construct a ribozyme active site. This work investigates the possibility that simple RNA phosphodiester and hydroxyl functional groups could catalyze amide bond synthesis. Reaction of amine groups with activated esters would be catalyzed by a group that stabilizes the partial positive charge on the amine nucleophile in the transition state.