Levels of Exon-Skipping Are Not Artificially Overestimated Because of the Increased Affinity of Tricyclo-DNA-Modified Antisense Oligonucleotides to the Target DMD Exon.

Antisense oligonucleotides (ASO) are very promising drugs for numerous diseases including neuromuscular disorders such as Duchenne muscular dystrophy (DMD). Several ASO drugs have already been approved by the US Food and Drug Administration for DMD and global efforts are still ongoing to improve further their potency, notably by developing new delivery systems or alternative chemistries. In this context, a recent study investigated the potential of different chemically modified ASO to induce exon-skipping in mouse models of DMD. Importantly, the authors reported a strong discrepancy between exon-skipping and protein restoration levels, which was mainly owing to the high affinity of locked nucleic acid (LNA) modifications to the target RNA, thereby interfering with the amplification of the unskipped product and resulting in artificial overamplification of the exon-skipped product. These findings urged us to verify whether a similar phenomenon could occur with tricyclo-DNA (tcDNA)-ASO that also display high-affinity properties to the target RNA. We thus ran a series of control experiments and demonstrate here that exon-skipping levels are not overestimated owing to an interference of tcDNA-ASO with the unskipped product in contrast to what was observed with LNA-containing ASO.

Networking to Optimize Dmd exon 53 Skipping in the Brain of mdx52 Mouse Model.

Duchenne muscular dystrophy (DMD) is caused by mutations in the DMD gene that disrupt the open reading frame and thus prevent production of functional dystrophin proteins. Recent advances in DMD treatment, notably exon skipping and AAV gene therapy, have achieved some success aimed at alleviating the symptoms related to progressive muscle damage. However, they do not address the brain comorbidities associated with DMD, which remains a critical aspect of the disease. The mdx52 mouse model recapitulates one of the most frequent genetic pathogenic variants associated with brain involvement in DMD. Deletion of exon 52 impedes expression of two brain dystrophins, Dp427 and Dp140, expressed from distinct promoters. Interestingly, this mutation is eligible for exon skipping strategies aimed at excluding exon 51 or 53 from dystrophin mRNA. We previously showed that exon 51 skipping can restore partial expression of internally deleted yet functional Dp427 in the brain following intracerebroventricular (ICV) injection of antisense oligonucleotides (ASO). This was associated with a partial improvement of anxiety traits, unconditioned fear response, and Pavlovian fear learning and memory in the mdx52 mouse model. In the present study, we investigated in the same mouse model the skipping of exon 53 in order to restore expression of both Dp427 and Dp140. However, in contrast to exon 51, we found that exon 53 skipping was particularly difficult in mdx52 mice and a combination of multiple ASOs had to be used simultaneously to reach substantial levels of exon 53 skipping, regardless of their chemistry (tcDNA, PMO, or 2'MOE). Following ICV injection of a combination of ASO sequences, we measured up to 25% of exon 53 skipping in the hippocampus of treated mdx52 mice, but this did not elicit significant protein restoration. These findings indicate that skipping mouse dystrophin exon 53 is challenging. As such, it has not yet been possible to answer the pertinent question whether rescuing both Dp427 and Dp140 in the brain is imperative to more optimal treatment of neurological aspects of dystrophinopathy.