Multiple functional domains of human U2 small nuclear RNA: strengthening conserved stem I can block splicing.

We showed previously that a branch site mutation in simian virus 40 early pre-mRNA that prevented small t antigen mRNA splicing could be efficiently suppressed by a compensatory mutation in a coexpressed U2 small nuclear (sn) RNA gene. We have now generated second-site mutations in this suppressor gene to investigate regions of U2 RNA required for function. A number of mutations in a putative stem at the 5' end of the molecule inhibited splicing, indicating that bases in this region are important for activity. However, several lines of evidence suggested that formation of the entire stem is not essential for splicing. Indeed, mutations that strengthen the stem actually inhibited splicing, and evidence that this prevents a required base-pairing interaction with U6 snRNA is presented. These results suggest that the relative stabilities of competing intra- and intermolecular base-pairing interactions play an important role in the splicing reaction. Mutations in a conserved single-stranded region immediately 3' to the branch site recognition sequence all inhibited splicing, indicating that this region is required for U2 function, although its exact role remains unknown. Finally, two mutations in the loop of stem IV at the 3' end of the molecule, which destroy the binding site of U2 sn ribonucleoprotein B", prevented small t splicing; this finding contrasts with previous studies which utilized different assay systems. Analysis of the accumulation and subcellular localization of all of the mutant RNAs showed that they were similar to those of the parental suppressor U2 RNA, indicating that the effects observed indeed reflect defects in splicing.