Mutations at the lariat acceptor site allow self‐splicing of a group II intron without lariat formation.

The fifth intron in the gene for cytochrome c oxidase subunit I in yeast mitochondrial DNA is of the group II type and is capable of self‐splicing in vitro. The reaction results in lariat formation, concomitant with exon‐exon ligation and does not require a guanosine nucleotide for its initiation. It is generally assumed, but not formally proven, that the first step in splicing is a nucleophilic attack of the 2′‐hydroxyl of the branchpoint nucleotide (A) on the 5′‐exon‐intron junction. To investigate the role of intron sequences in recognition of the 5′‐splice junction and the ensuing event of cleavage and lariat formation, mutations have been introduced at and around the branchsite. Results obtained show that although branchpoint attack and subsequent lariat formation are strongly preferred events under conditions normally used for self‐splicing, addition of a single T residue at intron position 856, a mutation which brings the branchpoint adenosine into a basepair, leads to a conditionally active intron, which at high ionic strength catalyses exon‐exon ligation in the absence of lariat formation. Comparable behaviour is also observed with the branchpoint A deletion mutant. The implications of these findings for the mechanism of self‐splicing of group II introns are discussed.