An experimental study of Saccharomyces cerevisiae U3 snRNA conformation in solution.

The conformation of Saccharomyces cerevisiae U3 snRNA (snR17A RNA) in solution was studied using enzymatic and chemical probes. In vitro synthesized and authentic snR17A RNAs have a similar conformation in solution. The S. cerevisiae U3 snRNA is folded in two distinct domains. The 5'-domain has a low degree of compactness; it is constituted of two stem-loop structures separated by a single-stranded segment, which has recently been proposed to basepair with the 5'-ETS of pre-ribosomal RNA. We demonstrate that, as previously proposed, the 5'-terminal region of U3 snRNA has a different structure in higher and lower eukaryotes and that this may be related to pre-rRNA 5'-ETS evolution. The S. cerevisiae U3 snRNA 3'-domain has a cruciform secondary structure and a compact conformation resulting from an higher order structure involving the single-stranded segments at the center of the cross and the bottom parts of helices. Compared to tRNA, where long range interactions take place between terminal loops, this represents another kind of tertiary folding of RNA molecules that will deserve further investigation, especially since the implicated single-strands have highly evolutionarily conserved primary structures that are involved in snRNP protein binding

Analysis of Sequence and Structural Features That Identify the B/C Motif of U3 Small Nucleolar RNA as the Recognition Site for the Snu13p-Rrp9p Protein Pair

The eukaryal Snu13p/15.5K protein binds K-turn motifs in U4 snRNA and snoRNAs. Two Snu13p/15.5K molecules bind the nucleolar U3 snoRNA required for the early steps of preribosomal processing. Binding of one molecule on the C′/D motif allows association of proteins Nop1p, Nop56p, and Nop58p, whereas binding of the second molecule on the B/C motif allows Rrp9p recruitment. To understand how the Snu13p-Rrp9p pair recognizes the B/C motif, we first improved the identification of RNA determinants required for Snu13p binding by experiments using the systematic evolution of ligands by exponential enrichment. This demonstrated the importance of a U·U pair stacked on the sheared pairs and revealed a direct link between Snu13p affinity and the stability of helices I and II. Sequence and structure requirements for efficient association of Rrp9p on the B/C motif were studied in yeast cells by expression of variant U3 snoRNAs and immunoselection assays. A G-C pair in stem II, a G residue at position 1 in the bulge, and a short stem I were found to be required. The data identify the in vivo function of most of the conserved residues of the U3 snoRNA B/C motif. They bring important information to understand how different K-turn motifs can recruit different sets of proteins after Snu13p association