A clinical trial in The Netherlands involves intramuscular injection of 2OMeAOs (P-S) into the TA muscle of patients with mutations correctable by exon 51 skipping. Phosphorodiamidate Morpholino Oligomers (Morpholinos, PMOs) have a number of additional advantages over
other chemistries, such as high water solubility. Furthermore, morpholinos are not subject to metabolic degradation, do not activate toll-like receptors and do not activate the interferon system or the NF-(kappa)B mediated inflammation response (12). Recently, we have shown that systemic injections of PMOs Inhibitors,research,lifescience,medical can restore dystrophin production to functional levels in many muscles of the mdx mouse and ameliorate dystrophic pathology without any trace of toxicity (13). This approach is currently being tested in DMD dogs with similarly encouraging results (Yokota et al., unpublished observations). A clinical trial, planned in
the UK, proposes to locally inject a 30 mer of single morpholino, targeting the Exonic splicing enhancer (ESE) sequence of Inhibitors,research,lifescience,medical exon 51. They will inject three different concentrations (low, intermediate and high – 2 boys per concentration), into extensor digitorum Inhibitors,research,lifescience,medical brevis and analyze the biopsy one month after injection (14). Development of a new AO drug is also underway. Recently, Wilton et al. reported that peptide tagged morpholinos show much greater efficiency than untagged bare morpholinos (15). However, they also showed elevated blood urea nitrogen (BUN) after injection into mice, indicative Inhibitors,research,lifescience,medical of toxicity. Whether or not tagged PMOs are better than non-tagged AO drugs will depend on the balance between increased efficacy and increased toxicity. Attention must also be paid to the question of whether there is any immune response in the long term to the peptide tag. Animal models to test exon skipping Conventionally, the mdx mouse model has been much used for animal research on DMD. The dystrophin defect arises from a nonsense mutation in exon 23. Both 2OMeAO and morpholinos (11, 13) Inhibitors,research,lifescience,medical against exon 23 have been shown to efficiently skip the exon and restore dystrophin expression in mdx mice. However,
the same mutation is very rare in humans, there being no reports of it in the Leiden Muscular Dystrophy database (http://www.dmd.nl) (16), so exon 23 will not be a target in any early human trials. In man, most DMD mutations are deletions, with a lesser number of duplications, that compromise the open reading frame. Of deletions, whatever 80% begin and end within the rod domain of the dystrophin gene and 90% of these occur within a “hotspot” LY2835219 concentration region, from exons 42 to 57. At least two mutant mice harbor mutations in this region, mdx52, where exon 52 is lacking, and mdx-4cv with a nonsense mutation in exon 53. Both will be useful for testing the feasibility of AOs (17, 18) targeted at regions of interest for therapy in man. AOs targeting exon 51 or exon 53 can restore the mdx52 mutation, and dual targeting of exon 52 and exon 53 can restore the mdx-4cv mutation.