Multiple roles for U6 snRNA in the splicing pathway
- PMID: 2149118
- DOI: 10.1101/gad.4.12b.2264
Multiple roles for U6 snRNA in the splicing pathway
Abstract
U6 is the most highly conserved of the five spliceosomal RNAs. It is associated with U4 by an extensive base-pairing interaction, which is disrupted immediately prior to the first nucleolytic step of splicing. It has been proposed that this event activates catalysis by unmasking U6. Using a combination of doped synthesis and site-directed mutagenesis to generate point mutations in U6, we have now identified 12 positions, in three domains, at which single nucleotide substitutions or deletions result in lethal or temperature-sensitive phenotypes. Biochemical analysis demonstrates that most of these mutants retain the ability to assemble into U4/U6 and U4/U5/U6 snRNPs. Notably, although mutations at three positions in U6 that base-pair with U4 are lethal, mutations in the complementary residues in U4 are fully viable. Furthermore, compensatory mutations in U4 that restore base-pairing fail to suppress the phenotypes of the U6 mutations. This demonstrates a function for U6 independent of its role in base-pairing. Remarkably, two of the three essential regions in U6 identified genetically correspond to intron insertion points in two yeast species. A temperature-sensitive mutation at one of these sites is defective in the second step of splicing in vitro.
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