Over 95% of human genes undergo pre-mRNA splicing, and alternative splicing of mRNA precursors represents a prevalent mode of gene regulation. Errors in this process are often the origin of disorders. Mutations affecting directly splicing factors, including core spliceosomal components, have been linked to various pathologies. Particularly intriguing are variants of the key spliceosomal subcomplex U4/5/6 tri-snRNP, associated with Retinitis Pigmentosa, one of the most common hereditary diseases affecting 1 in 3,000 individuals, leading to retinal degeneration and progressive blindness. Why these mutations lead to highly tissue-specific phenotypes, rather than general toxicity cause by a global block in splicing, remain unexplained.
The proposed research aims to increase our understanding of the molecular mechanisms underlying the effects of these mutations and shed light on the basis of the disease. To functionally dissect these variants, I combined spliceosomal network approaches (I) with genome-wide transcriptome analysis (II). Mechanistic insights derived from these analyses will helped to identify transcripts that are predominantly sensitive to these mutations and that could be behind their pathogenic effects. This work l allowed us to better understand the function of key splicing factorsand their contributions to Retinitis Pigmentosa.