Stephen D. Wilton

A single administration of morpholino antisense oligomer rescues spinal muscular atrophy in mouse

Spinal muscular atrophy (SMA) is an autosomal-recessive disorder characterized by α-motor neuron loss in the spinal cord anterior horn. SMA results from deletion or mutation of the Survival Motor Neuron 1 gene (SMN1) and retention of SMN2. A single nucleotide difference between SMN1 and SMN2 results in exclusion of exon 7 from the majority of SMN2 transcripts, leading to decreased SMN protein levels and development of SMA. A series of splice enhancers and silencers regulate incorporation of SMN2 exon 7; these splice motifs can be blocked with antisense oligomers (ASOs) to alter SMN2 transcript splicing. We have evaluated a morpholino (MO) oligomer against ISS-N1 [HSMN2Ex7D(-10,-29)], and delivered this MO to postnatal day 0 (P0) SMA pups (Smn-/-, SMN2+/+, SMNΔ7+/+) by intracerebroventricular (ICV) injection. Survival was increased markedly from 15 days to >100 days. Delayed CNS MO injection has moderate efficacy, and delayed peripheral injection has mild survival advantage, suggesting that early CNS ASO administration is essential for SMA therapy consideration. ICV treatment increased full-length SMN2 transcript as well as SMN protein in neural tissue, but only minimally in peripheral tissue. Interval analysis shows a decrease in alternative splice modification over time. We suggest that CNS increases of SMN will have a major impact on SMA, and an early increase of the SMN level results in correction of motor phenotypes. Finally, the early introduction by intrathecal delivery of MO oligomers is a potential treatment for SMA patients.

Improved antisense oligonucleotide induced exon skipping in the mdx mouse model of muscular dystrophy

Duchenne muscular dystrophy (DMD) is a fatal genetic disorder caused by dystrophin gene mutations that preclude synthesis of a functional protein. One potential treatment of the disorder has utilised antisense oligoribonucleotides (AOs) to induce removal of disease‐associated exons during pre‐mRNA processing. Induced in‐frame mRNA transcripts encode a shorter but functional dystrophin. We have investigated and improved the design of AOs capable of removing exon 23, and thus the disease‐causing nonsense mutation, from mRNA in the mdx mouse model of DMD.

Molecular analysis of a spontaneous dystrophin `knockout' dog

We have determined the molecular basis for skeletal myopathy and dilated cardiomyopathy in two male German short-haired pointer (GSHP) littermates. Analysis of skeletal muscle demonstrated a complete absence of dystrophin on Western blot analysis. PCR analysis of genomic DNA revealed a deletion encompassing the entire dystrophin gene. Molecular cytogenetic analysis of lymphocytes from the dam and both dystrophic pups confirmed a visible deletion in the p21 region of the affected canine X chromosome. Utrophin is up-regulated in the skeletal muscle, but does not appear to ameliorate the dystrophic canine phenotype. This new canine model should further our understanding of the physiological and biochemical processes in Duchenne muscular dystrophy.

A novel morpholino oligomer targeting ISS-N1 improves rescue of severe spinal muscular atrophy transgenic mice.

In the search for the most efficacious antisense oligonucleotides (AOs) aimed at inducing SMN2 exon 7 inclusion, we systematically assessed three AOs, PMO25 (-10, -34), PMO18 (-10, -27), and PMO20 (-10, -29), complementary to the SMN2 intron 7 splicing silencer (ISS-N1). PMO25 was the most efficacious in augmenting exon 7 inclusion in vitro in spinal muscular atrophy (SMA) patient fibroblasts and in vitro splicing assays. PMO25 and PMO18 were compared further in a mouse model of severe SMA. After a single intracerebroventricular (ICV) injection in neonatal mice, PMO25 increased the life span of severe SMA mice up to 30-fold, with average survival greater by 3-fold compared with PMO18 at a dose of 20 μg/g and 2-fold at 40 μg/g. Exon 7 inclusion was increased in the CNS but not in peripheral tissues. Systemic delivery of PMO25 at birth achieved a similar outcome and produced increased exon 7 inclusion both in the CNS and peripherally. Systemic administration of a 10-μg/g concentration of PMO25 conjugated to an octaguanidine dendrimer (VMO25) increased the life span only 2-fold in neonatal type I SMA mice, although it prevented tail necrosis in mild SMA mice. Higher doses and ICV injection of VMO25 were associated with toxicity. We conclude that (1) the 25-mer AO is more efficient than the 18-mer and 20-mer in modifying SMN2 splicing in vitro; (2) it is more efficient in prolonging survival in SMA mice; and (3) naked Morpholino oligomers are more efficient and safer than the Vivo-Morpholino and have potential for future SMA clinical applications.

Target selection for antisense oligonucleotide induced exon skipping in the dystrophin gene

Duchenne muscular dystrophy (DMD) is an X‐linked recessive muscle wasting disorder characterised by the absence of the protein dystrophin. Antisense oligonucleotides have been used to re‐direct dystrophin pre‐mRNA processing by blocking sequences crucial to pre‐mRNA splicing, thereby inducing skipping of specific exons. We wished to determine which splicing motifs are most amenable as targets for antisense oligonucleotide induction of efficient and specific skipping of selected exons.

Dystrophin gene transcripts skipping the mdx mutation

The mdx mouse, an animal model used to study Duchenne muscular dystrophy, has a nonsense mutation in exon 23 of the dystrophin gene which should result in a truncated protein that cannot be correctly localized at the sarcolemma of the muscle fibers. Immunohistochemical staining with antidystrophin antibodies has shown that while most of the muscle tissue is dystrophin‐negative, a small percentage of muscle fibers is clearly dystrophin‐positive and has somehow bypassed the primary nonsense mutation. A sensitive nested polymerase chain reaction‐based examination of dystrophin gene transcripts around the mdx mutation has revealed several alternatively processed transcripts. Four mRNA species skipped the mutation in exon 23, were in‐frame, and could be translated into a shorter but still functional dystrophin protein. Specific tests for these transcripts demonstrated these were also present in normal mouse muscle tissue.

Alternative dystrophin gene transcripts in golden retriever muscular dystrophy

Golden retriever muscular dystrophy (GRMD), the canine model of Duchenne muscular dystrophy (DMD), is caused by a splice site mutation in the dystrophin gene. This mutation predicts a premature termination codon in exon 8 and a peptide that is 5% the size of normal dystrophin. Western blot analysis of skeletal muscle from GRMD dogs reveals a slightly truncated 390‐kD protein that is approximately 91% the size of normal dystrophin. This 390‐kD dystrophin suggests that GRMD dogs, like some DMD patients, employ a mechanism to overcome their predicted frameshift. Reverse‐transcriptase polymerase chain reaction on GRMD muscle has revealed two in‐frame dystrophin transcripts which lack either exons 3–9 or exons 5–12. Both transcripts could be translated into a dystrophin protein of approximately 390 kD. An understanding of how truncated dystrophin is produced in GRMD may allow this mechanism to be manipulated toward a potential therapy for DMD.

Revertant fibres: a possible genetic therapy for Duchenne muscular dystrophy?

The mdx mouse, an animal model used to study Duchenne muscular dystrophy (DMD), has a nonsense mutation in exon 23 of the dystrophin gene which should result in a truncated protein that cannot be correctly localized at the sarcolemma of the muscle fibres. Immunohistochemical staining with anti-dystrophin antibodies had shown that while most of the muscle tissue was dystrophin-negative, a small percentage of muscle fibres were clearly dystrophin-positive and had somehow by-passed the primary nonsense mutation. A nested PCR-based examination of dystrophin gene transcripts around the mdx mutation revealed several alternatively processed transcripts, of which four mRNA species skipped the mutation in exon 23, were in-frame and could be translated into a shorter, but still functional dystrophin protein. Specific tests for these transcripts demonstrated these were also present in normal adult and embryonic mouse muscle tissue.

Smart functional nucleic acid chimeras: enabling tissue specific RNA targeting therapy.

A major obstacle for effective utilization of therapeutic oligonucleotides such as siRNA, antisense, antimiRs etc. is to deliver them specifically to the target tissues. Toward this goal, nucleic acid aptamers are re-emerging as a prominent class of biomolecules capable of delivering target specific therapy and therapeutic monitoring by various molecular imaging modalities. This class of short oligonucleotide ligands with high affinity and specificity are selected from a large nucleic acid pool against a molecular target of choice. Poor cellular uptake of therapeutic oligonucleotides impedes gene-targeting efficacy in vitro and in vivo. In contrast, aptamer-oligonucleotide chimeras have shown the capacity to deliver siRNA, antimiRs, small molecule drugs etc. toward various targets and showed very promising results in various studies on different diseases models. However, to further improve the bio-stability of such chimeric conjugates, it is important to introduce chemically-modified nucleic acid analogs. In this review, we highlight the applications of nucleic acid aptamers for target specific delivery of therapeutic oligonucleotides.

Long-term administration of antisense oligonucleotides into the paraspinal muscles of mdx mice reduces kyphosis.

The mdx mouse model of muscular dystrophy has a premature stop codon preventing production of dystrophin. This results in a progressive phenotype causing centronucleation of skeletal muscle fibers, muscle weakness, and fibrosis and kyphosis. Antisense oligonucleotides alter RNA splicing to exclude the nonsense mutation, while still maintaining the open reading frame to produce a shorter, but partially functional dystrophin protein that should ameliorate the extent of pathology. The present study investigated the benefits of chronic treatment of mdx mice by once-monthly deep intramuscular injections of antisense oligonucleotides into paraspinal muscles. After 8 mo of treatment, mdx mice had reduced development of kyphosis relative to untreated mdx mice, a benefit that was retained until completion of the study at 18 mo of age (16 mo of treatment). This was accompanied by reduced centronucleation in the latissimus dorsi and intercostals muscles and reduced fibrosis in the diaphragm and latissimus dorsi. These benefits were accompanied by a significant increase in dystrophin production. In conclusion, chronic antisense oligonucleotide treatment provides clear and ongoing benefits to paralumbar skeletal muscle, with associated marked reduction in kyphosis.