Abstract

It has long been known that canonical 5 splice site (5SS) GT>GC mutations may be compatible with normal splicing. However, to date, the true scale of canonical 5SS GT>GC mutations generating wild-type transcripts, both in the context of the frequency of such mutations and the level of wild-type transcripts generated from the mutation alleles, remain unknown. Herein, combining data derived from a meta-analysis of 45 informative disease-causing 5SS GT>GC mutations (from 42 genes) and a cell culture-based full-length gene splicing assay of 103 5SS GT>GC mutations (from 30 genes), we estimate that [~]15-18% of the canonical GT 5SSs are capable of generating between 1 and 84% normal transcripts as a consequence of the substitution of GT by GC. We further demonstrate that the canonical 5SSs whose substitutions of GT by GC generated normal transcripts show stronger complementarity to the 5 end of U1 snRNA than those sites whose substitutions of GT by GC did not lead to the generation of normal transcripts. We also observed a correlation between the generation of wild-type transcripts and a milder than expected clinical phenotype but found that none of the available splicing prediction tools were able to accurately predict the functional impact of 5SS GT>GC mutations. Our findings imply that 5SS GT>GC mutations may not invariably cause human disease but should also help to improve our understanding of the evolutionary processes that accompanied GT>GC subtype switching of U2-type introns in mammals.