Engineered U1 snRNAs to modulate alternatively spliced exons

Alternative splicing accounts for a considerable portion of transcriptomic diversity, as most protein-coding genes are spliced into multiple mRNA isoforms. However, errors in splicing patterns can give rise to mis-splicing with pathological consequences, such as the congenital diseases familial dysautonomia, Duchenne muscular dystro-phy, and spinal muscular atrophy. Small nuclear RNA (snRNA) components of the U snRNP family have been proposed as a therapeutic modality for the treatment of mis-splicing. U1 snRNAs offer great promise, with prior studies demonstrating in vivo efficacy, suggesting additional preclinical development is merited. Improvements in enabling technologies, including screening methodologies, gene delivery vectors, and relevant considerations from gene editing approaches justify further advancement of U1 snRNA as a therapeutic and research tool. With the goal of providing a user-friendly protocol, we compile and demonstrate a methodological toolkit for sequence-specific targeted perturbation of alternatively spliced pre-mRNA with engineered U1 snRNAs. We observe robust modulation of endogenous pre-mRNA transcripts targeted in two contrasting splicing contexts, SMN2 exon 7 and FAS exon 6, exhibiting the utility and applicability of engineered U1 snRNA to both inclusion and exclusion of targeted exons. We anticipate that these demonstrations will contribute to the usability of U1 snRNA in investigating splicing modulation in eukaryotic cells, increasing accessibility to the broader research community.

Automated summary

Alternative splicing is an important aspect of transcriptomic diversity, but errors in splicing patterns can have pathological consequences. U1 snRNA has been proposed as a therapeutic and research tool for correcting splicing errors. This study demonstrates a methodological toolkit for perturbing alternative splicing using engineered U1 snRNAs, showing their effectiveness in controlling targeted exons. These findings contribute to the usability and accessibility of U1 snRNA for investigating splicing modulation in eukaryotic cells.