DMD transcript imbalance determines dystrophin levels.

Duchenne and Becker muscular dystrophies are caused by out-of-frame and in-frame mutations, respectively, in the dystrophin encoding DMD gene. Molecular therapies targeting the precursor-mRNA are in clinical trials and show promising results. These approaches will depend on the stability and expression levels of dystrophin mRNA in skeletal muscles and heart. We report that the DMD gene is more highly expressed in heart than in skeletal muscles, in mice and humans. The transcript mutated in the mdx mouse model shows a 5' to 3' imbalance compared with that of its wild-type counterpart and reading frame restoration via antisense-mediated exon skipping does not correct this event. We also report significant transcript instability in 22 patients with Becker dystrophy, clarifying the fact that transcript imbalance is not caused by premature nonsense mutations. Finally, we demonstrate that transcript stability, rather than transcriptional rate, is an important determinant of dystrophin protein levels in patients with Becker dystrophy. We suggest that the availability of the complete transcript is a key factor to determine protein abundance and thus will influence the outcome of mRNA-targeting therapies.

Guidelines for antisense oligonucleotide design and insight into splice-modulating mechanisms.

Antisense oligonucleotides (AONs) can interfere with mRNA processing through RNase H-mediated degradation, translational arrest, or modulation of splicing. The antisense approach relies on AONs to efficiently bind to target sequences and depends on AON length, sequence content, secondary structure, thermodynamic properties, and target accessibility. We here performed a retrospective analysis of a series of 156 AONs (104 effective, 52 ineffective) previously designed and evaluated for splice modulation of the dystrophin transcript. This showed that the guanine-cytosine content and the binding energies of AON-target and AON-AON complexes were significantly higher for effective AONs. Effective AONs were also located significantly closer to the acceptor splice site (SS). All analyzed AONs are exon-internal and may act through steric hindrance of Ser-Arg-rich (SR) proteins to exonic splicing enhancer (ESE) sites. Indeed, effective AONs were significantly enriched for ESEs predicted by ESE software programs, except for predicted binding sites of SR protein Tra2beta, which were significantly enriched in ineffective AONs. These findings compile guidelines for development of AONs and provide more insight into the mechanism of antisense-mediated exon skipping. On the basis of only four parameters, we could correctly classify 79% of all AONs as effective or ineffective, suggesting these parameters can be used to more optimally design splice-modulating AONs.

Antisense-induced exon skipping for duplications in Duchenne muscular dystrophy.

BACKGROUND: Antisense-mediated exon skipping is currently one of the most promising therapeutic approaches for Duchenne muscular dystrophy (DMD). Using antisense oligonucleotides (AONs) targeting specific exons the DMD reading frame is restored and partially functional dystrophins are produced. Following proof of concept in cultured muscle cells from patients with various deletions and point mutations, we now focus on single and multiple exon duplications. These mutations are in principle ideal targets for this approach since the specific skipping of duplicated exons would generate original, full-length transcripts. METHODS: Cultured muscle cells from DMD patients carrying duplications were transfected with AONs targeting the duplicated exons, and the dystrophin RNA and protein were analyzed. RESULTS: For two brothers with an exon 44 duplication, skipping was, even at suboptimal transfection conditions, so efficient that both exons 44 were skipped, thus generating, once more, an out-of-frame transcript. In such cases, one may resort to multi-exon skipping to restore the reading frame, as is shown here by inducing skipping of exon 43 and both exons 44. By contrast, in cells from a patient with an exon 45 duplication we were able to induce single exon 45 skipping, which allowed restoration of wild type dystrophin. The correction of a larger duplication (involving exons 52 to 62), by combinations of AONs targeting the outer exons, appeared problematic due to inefficient skipping and mistargeting of original instead of duplicated exons. CONCLUSION: The correction of DMD duplications by exon skipping depends on the specific exons targeted. Its options vary from the ideal one, restoring for the first time the true, wild type dystrophin, to requiring more 'classical' skipping strategies, while the correction of multi-exon deletions may need the design of tailored approaches.

Functional analysis of 114 exon-internal AONs for targeted DMD exon skipping: indication for steric hindrance of SR protein binding sites.

As small molecule drugs for Duchenne muscular dystrophy (DMD), antisense oligonucleotides (AONs) have been shown to restore the disrupted reading frame of DMD transcripts by inducing specific exon skipping. This allows the synthesis of largely functional dystrophin proteins and potential conversion of severe DMD into milder Becker muscular dystrophy (BMD) phenotypes. We have previously described 37 exon-internal AONs that induce skipping of 14 DMD exons in human control myotube cultures. Here, we report 77 new AONs, effectively targeting an additional 21 exons. Of the 114 AONs thus far tested, 72 (67%) were effective. AON design initially was based on a partial overlap with predicted open secondary structures in the target RNA. We have analyzed various AON and target exon parameters in retrospect. Interestingly, we observed significantly higher SF2/ASF, SC35, and SRp40 values (as predicted by ESEfinder) for effective AONs when compared with ineffective AONs. In addition, the distance to the 3' splice site was significantly smaller for effective AONs. No other significant correlations were observed. Our results suggest that effective exon-internal AONs primarily act by blocking SR binding sites (which often correspond to open structures) and that ESEfinder may be used to refine AON design for DMD and other genes.

Targeted exon skipping in transgenic hDMD mice: A model for direct preclinical screening of human-specific antisense oligonucleotides.

The therapeutic potential of frame-restoring exon skipping by antisense oligonucleotides (AONs) has recently been demonstrated in cultured muscle cells from a series of Duchenne muscular dystrophy (DMD) patients. To facilitate clinical application, in vivo studies in animal models are required to develop safe and efficient AON-delivery methods. However, since exon skipping is a sequence-specific therapy, it is desirable to target the human DMD gene directly. We therefore set up human sequence-specific exon skipping in transgenic mice carrying the full-size human gene (hDMD). We initially compared the efficiency and toxicity of intramuscular AON injections using different delivery reagents in wild-type mice. At a dose of 3.6 nmol AON and using polyethylenimine, the skipping levels accumulated up to 3% in the second week postinjection and lasted for 4 weeks. We observed a correlation of this long-term effect with the intramuscular persistence of the AON. In regenerating myofibers higher efficiencies (up to 9%) could be obtained. Finally, using the optimized protocols in hDMD mice, we were able to induce the specific skipping of human DMD exons without affecting the endogenous mouse gene. These data highlight the high sequence specificity of this therapy and present the hDMD mouse as a unique model to optimize human-specific exon skipping in vivo.

Antisense-induced multiexon skipping for Duchenne muscular dystrophy makes more sense.

Dystrophin deficiency, which leads to severe and progressive muscle degeneration in patients with Duchenne muscular dystrophy (DMD), is caused by frameshifting mutations in the dystrophin gene. A relatively new therapeutic strategy is based on antisense oligonucleotides (AONs) that induce the specific skipping of a single exon, such that the reading frame is restored. This allows the synthesis of a largely functional dystrophin, associated with a milder Becker muscular dystrophy phenotype. We have previously successfully targeted 20 different DMD exons that would, theoretically, be beneficial for >75% of all patients. To further enlarge this proportion, we here studied the feasibility of double and multiexon skipping. Using a combination of AONs, double skipping of exon 43 and 44 was induced, and dystrophin synthesis was restored in myotubes from one patient affected by a nonsense mutation in exon 43. For another patient, with an exon 46-50 deletion, the therapeutic double skipping of exon 45 and 51 was achieved. Remarkably, in control myotubes, the latter combination of AONs caused the skipping of the entire stretch of exons from 45 through 51. This in-frame multiexon skipping would be therapeutic for a series of patients carrying different DMD-causing mutations. In fact, we here demonstrate its feasibility in myotubes from a patient with an exon 48-50 deletion. The application of multiexon skipping may provide a more uniform methodology for a larger group of patients with DMD.

Therapeutic antisense-induced exon skipping in cultured muscle cells from six different DMD patients.

The dystrophin deficiency leading to the severely progressing muscle degeneration in Duchenne muscular dystrophy (DMD) patients is caused by frame-shifting mutations in the DMD gene. We are developing a reading frame correction therapy aimed at the antisense-induced skipping of targeted exons from the pre-mRNA. Despite introducing a (larger) deletion, an in-frame transcript is generated that allows the synthesis of a slightly shorter, but largely functional dystrophin as found in the mostly milder Becker muscular dystrophy (BMD). We have recently demonstrated both the efficacy and high efficiency of the antisense-induced skipping of numerous exons from the DMD transcript in control muscle cells. In principle, this would restore the reading frame in over 75% of the patients reported in the Leiden DMD mutation database. In this study, we in fact demonstrate the broad therapeutic applicability of this strategy in cultured muscle cells from six DMD patients carrying different deletions and a nonsense mutation. In each case, the specific skipping of the targeted exon was induced, restoring dystrophin synthesis in over 75% of cells. The protein was detectable as soon as 16 h post-transfection, then increased to significant levels at the membrane within 2 days, and was maintained for at least a week. Finally, its proper function was further suggested by the restored membranal expression of four associated proteins from the dystrophin-glycoprotein complex. These results document important progress towards a clinically applicable, small-molecule based therapy.

Targeted exon skipping as a potential gene correction therapy for Duchenne muscular dystrophy.

Duchenne muscular dystrophy is primarily caused by frame-disrupting mutations in the Duchenne muscular dystrophy gene which abort dystrophin synthesis. We have explored a gene correction therapy aimed at restoration of the reading frame in Duchenne muscular dystrophy patients. Through the binding of antisense oligoribonucleotides to exon-internal sequences in the pre-mRNA, the splicing can be manipulated in such a manner that the targeted exon is skipped and a slightly shorter, but in-frame, transcript is generated. We recently showed that antisense oligoribonucleotide-mediated skipping of exon 46 efficiently induced dystrophin synthesis in cultured muscle cells from Duchenne muscular dystrophy patients carrying an exon 45 deletion. In this study we have identified antisense oligoribonucleotides with which the skipping of 11 other Duchenne muscular dystrophy exons could be induced in cultured human muscle cells. The targeted skipping of only one particular exon may restore the reading frame in a series of patients with different mutations. Accordingly, these antisense oligoribonucleotides would allow correction of over 50% of deletions and 22% of duplications reported in the Leiden DMD-mutation Database.