Shape changes and cooperativity in the folding of the central domain of the 16S ribosomal RNA.

Both the small and large subunits of the ribosome, the molecular machine that synthesizes proteins, are complexes of ribosomal RNAs (rRNAs) and a number of proteins. In bacteria, the small subunit has a single 16S rRNA whose folding is the first step in its assembly. The central domain of the 16S rRNA folds independently, driven either by Mg ions or by interaction with ribosomal proteins. To provide a quantitative description of ion-induced folding of the ∼350-nucleotide rRNA, we carried out extensive coarse-grained molecular simulations spanning Mg concentration between 0 and 30 mM. The Mg dependence of the radius of gyration shows that globally the rRNA folds cooperatively. Surprisingly, various structural elements order at different Mg concentrations, indicative of the heterogeneous assembly even within a single domain of the rRNA. Binding of Mg ions is highly specific, with successive ion condensation resulting in nucleation of tertiary structures. We also predict the Mg-dependent protection factors, measurable in hydroxyl radical footprinting experiments, which corroborate the specificity of Mg-induced folding. The simulations, which agree quantitatively with several experiments on the folding of a three-way junction, show that its folding is preceded by formation of other tertiary contacts in the central junction. Our work provides a starting point in simulating the early events in the assembly of the small subunit of the ribosome.