Splice-switching antisense oligonucleotides correct cryptic exon inclusion and restore SDCCAG8 protein in Bardet-Biedl Syndrome

Bardet-Biedl Syndrome (BBS) is a ciliopathy often associated with progressive blindness and obesity. A patient presenting with BBS was discovered to have two mutations within 55bp of each other in intron 7 of SDCCAG8 ( BBS16 ). One of the biallelic mutations, c.740+356C>T, causes inclusion of cryptic exon(s) containing premature termination codons, while c.740+301G>A has not been characterized. We hypothesized that antisense oligonucleotides (ASOs) complementary to the patient’s mutations or to the cryptic exon splice sites would correct the splicing of SDCCAG8 between exons 7 and 8 to prevent cryptic exon inclusion and restore SDCCAG8 expression. We systematically screened 20nt-long ASOs tiled across each mutation and ASOs targeting the 3′ splice sites of the cryptic exons in patient-derived fibroblasts, using RT-PCR assays to assess exon 7 and 8 splicing. We identified one ASO for each mutation and a cryptic exon-targeting ASO that restored the splicing pattern to that observed in an unaffected cell line. Lead ASOs were further investigated through RT-PCR, RNA sequencing, and western blotting to confirm ASO-mediated restoration of wild-type transcript and protein. Notably, ASO 20, which targets the cryptic exon 7a/7a′ splice site rather than patient-specific mutations, achieved the greatest rescue effect, increasing exon 7-8 splicing from 0% to an average of 26% and restoring SDCCAG8 protein from undetectable levels to approximately 40% of wild-type expression. This mutation-agnostic approach could benefit multiple patients with cryptic exon inclusion in this region of SDCCAG8 , expanding therapeutic impact beyond traditional N-of-1 ASO strategies. These findings establish a molecular foundation for clinical development of ASO therapy for BBS caused by SDCCAG8 splicing defects.