Felecia Gumienny

Low-level dystrophin expression attenuating the dystrophinopathy phenotype

The reading frame rule suggests that Duchenne muscular dystrophy (DMD) results from DMD mutations causing an out-of-frame transcript, whereas the milder Becker muscular dystrophy results from mutations causing an in-frame transcript. However, predicted nonsense mutations may instead result in altered splicing and an in-frame transcript. Here we report a 10-year-old boy with a predicted nonsense mutation in exon 42 who had a 6-minute walk time of 157% of that of age matched DMD controls, characterized as intermediate muscular dystrophy. RNA sequencing analysis from a muscle biopsy revealed only 6.0-9.8% of DMD transcripts were in-frame, excluding exon 42, and immunoblot demonstrated only 3.2% dystrophin protein expression. Another potential genetic modifier noted was homozygosity for the protective IAAM LTBP4 haplotype. This case suggests that very low levels of DMD exon skipping and dystrophin protein expression may result in amelioration of skeletal muscle weakness, a finding relevant to current dystrophin-restoring therapies.

Low-level expression of EPG5 leads to an attenuated Vici syndrome phenotype

Vici syndrome is a multisystem disorder characterized by agenesis of the corpus callosum, oculocutaneous hypopigmentation, cataracts, cardiomyopathy, combined immunodeficiency, failure to thrive, profound developmental delay, and acquired microcephaly. Most individuals are severely affected and have a markedly reduced life span. Here we describe an 8‐year‐old boy with a history of developmental delay, agenesis of the corpus callosum, failure to thrive, myopathy, and well‐controlled epilepsy. He was initially diagnosed with a mitochondrial disorder, based in part upon nonspecific muscle biopsy findings, but mitochondrial DNA mutation analysis revealed no mutations. Whole exome sequencing revealed compound heterozygosity for two EPG5 variants, inherited in trans. One was a known pathogenic mutation in exon 13 (c.2461C > T, p.Arg821X). The second was reported as a variant of unknown significance found within intron 16, six nucleotides before the exon 17 splice acceptor site (c.3099‐6C > G). Reverse transcription‐polymerase chain reaction of the EPG5 mRNA showed skipping of exon 17—which maintains an open reading frame—in 77% of the transcript, along with 23% expression of wild‐type mRNA suggesting that intronic mutations may affect splicing of the EPG5 gene and result in symptoms. However, the expression of 23% wild‐type mRNA may result in a significantly attenuated Vici syndrome phenotype.

624. A Single Neonatal Delivery of an Exon 2 Directed AAV9.U7snRNA Vector Results in Long-Term Dystrophin Expression That Prevents Pathologic Features in the Dup2 Mouse

We recently identified an internal ribosome entry site (IRES) within exon 5 of the DMD gene. Mutations that truncate the reading frame 5’ of this exon can result in use of the IRES for alternate translational initiation beginning within exon 6 that results in expression of an N-truncated isoform. Despite lacking the calponin homology domain 1 (CH1) of the actin binding domain 1 (ABD1), this isoform is highly functional, as demonstrated by the minimal symptoms in patients who express it. Consistent with genotype-phenotype correlations in DMD patients, the IRES is not active in the presence of exon 2 duplication but is active when exon 2 is deleted. We developed an AAV9.U7snRNA vector to that truncates DMD reading frame by skipping of exon 2, and have shown that in a Duchenne muscular dystrophy (DMD) mouse model carrying a duplication of exon 2 (the Dup2 mouse), postnatal intramuscular (IM) or intravascular (IV) treatment results in functional and pathologic improvement in skeletal muscle. Relevant to efforts to identify and treat DMD patients at an earlier age, we sought here to determine whether earlier gene transfer might slow down or even prevent the development of pathology. Dup2 mice were injected via facial vein at postnatal day 1 (P1) with 1E12 total vector genomes of the AAV9.U7snRNA vector and sacrificed at either 1, 3, 6, or 12 months post-injection for evaluation of exon 2 skipping by RT-PCR, quantification of dystrophin expression, and characterization of histopathology. To model the applicability of this approach beyond exon 2 duplication patients, the same vector was used to treat 6 human patient fibroblast-derived transdifferentiated myoblasts (FibroMyoD cells) harboring various mutations within exons 1 to 4. In the Dup2 mouse, efficient skipping and abundant dystrophin expression were present up to one year following the single AAV injection. Dystrophic pathology was absent at all-time points; at one year, less than 1% of fibers showed central nucleation, in comparison to ~70% in untreated Dup2 mice. Two tests on the ex vivo diaphragm preparations: isometric force (providing assessment of strength), and eccentric contractions (evaluating sarcolemma stability) were performed at 3 and 6 months following P1 injection. Both tests demonstrated little to no difference between treated animals and wild type mice. In all FibroMyoD cultures, abundant exon 2 skipping and dystrophin expression were detected in myotubes at 14 days of culture after treatment. These results suggest that this exon-skipping vector offers a therapeutic approach not only to patients with exon 2 duplications but with all mutations within the first four DMD exons (~6% of patients), an area of the gene largely ignored by the current therapeutic approaches. This work strongly supports the idea that early treatment of these patients will have longstanding and significant benefit resulting in a better outcome.

328. Proof-of-Principle Study Shows Efficient Skipping of Exon 2 Using Antisense Morpholino Oligomers

Currently, exon skipping therapies for Duchenne muscular dystrophy (DMD) have been developed for patients with out-of-frame deletions where treatment will lead translation of an internally truncated but partially functional dystrophin protein. In contrast, we are focusing on treating duplications mutations, accounting for around 6% of all mutations, resulting in wild-type transcript and a full-length protein. Modeling the most common single exon duplication we have developed the first duplication mouse containing a duplicated exon 2. We have performed a proof-of-principle study using antisense oligomer (AO)-induced exon 2 skipping using this Dup2 mouse. Intramuscular (TA) injections of exon 2-directed different antisense peptide-morpholino conjugates (PPMO) were performed at either 10 or 20 ug total PPMO (N=6 muscles each) doses. Mice were injected at 8 weeks and sacrificed 1 month later for muscle analysis of DMD mRNA and dystrophin protein expression. Additionally, systemic (tail vein) injections are being conducted of at a dose of 30 ug/kg, at 1 week, 2 week and 1 month timepoints. For the IM studies, a gradient of exon 2 exclusion was seen by RT-PCR at both doses with corresponding high levels of properly localized dystrophin protein by IF and western blot.Analyses of RT-PCR and protein expression are underway for the systemic delivery PPMOs. These data suggest that skipping of a duplicated exon 2 may be a feasible therapeutic approach, particularly because skipping of exon 2 may be associated with an apparently unlimited therapeutic window. Over-skipping - to the exclusion of exon 2 entirely - results in activation of an internal ribosome entry site (IRES) located in exon 5 of dystrophin that allows for cap-independent translation from an alternative initiation site within exon 6. This alternate dystrophin isoform is highly functional despite being N-truncated, consistent with the observation that patients expressing it have minimally symptomatic (or even asymptomatic) Becker muscular dystrophy (BMD), and suggesting a potential route to therapy for any of the approximately 5% of patients with mutations in the 5’ end of the gene.

60. Intramuscular and Systemic Induction of the N-Truncated Dystrophin By Out-Of-Frame Exon 2 Skipping Restores Muscle Function in the Dup2 Mouse, Providing Further Support for a Therapeutic Pathway for 5’ DMD Mutations

Most mutations that truncate the reading frame of the DMD gene result in loss of dystrophin expression and lead the severe Duchenne muscular dystrophy. However, frame-truncating mutations within the first five exons of DMD result in mild dystrophinopathy with expression of a N-truncated dystrophin. We have recently shown that this is due to activation of an internal ribosome entry site (IRES) within exon 5 resulting in translation from an exon 6 AUG codon.We demonstrated that this IRES is active in patients expressing the N-truncated dystrophin, raising the possibility of the therapeutic use of this isoform. To explore this we developed a novel out-of-frame exon-skipping approach that uses AAV-mediated U7snRNA to efficiently skip exon 2. By injecting this AAV vector into a DMD mouse model carrying a duplication of exon 2 (Dup2), this generates a truncated reading frame, leading to activation of the IRES and synthesis of the N-truncated isoform.We now demonstrate that despite lacking the first half of the canonical actin binding domain 1, this N-truncated protein is highly functional. Intramuscular injection of the AAV1.U7snRNA vector into Dup2 mice results in high levels of expression of the N-truncated isoform by 4 to 6 weeks post-injection, along with complete correction of the physiologic and pathologic features as measured by Evans blue dye uptake, hindlimb grip strength, tibialis anterior specific force, and force correction after eccentric contraction. Preliminary results supports that systemic delivery of AAV9.U7snRNA vector into Dup2 mice induce expression of this functional isoform into all muscle including heart and diaphragm, thereby improving muscle histopathology.Following treatment, a genome-wide normalized RPF-Seq data analysis (Ribosome Protected Fragment) was performed to check if the treatment restored the Haslett gene lists (gene altered in DMD) to a ‘non-dystrophic’ pattern. Our data clearly indicates that the treatment restored the global expression pattern to a more normal pattern. This level of correction to that of control mice supports the idea that this novel therapeutic approach should be beneficial for the 6% of patients with mutations within the first five exons of DMD.