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

Author

Doisy, Mathilde, Vacca, Ophélie, Fergus, Claire, Gileadi, Talia, Verhaeg, Minou, Saoudi, Amel, Tensorer, Thomas, Garcia, Luis, Kelly, Vincent P., Montanaro, Federica, Morgan, Jennifer E., van Putten, Maaike, Aartsma-Rus, Annemieke, Vaillend, Cyrille, Muntoni, Francesco, and Goyenvalle, Aurélie

Subjects
LABORATORY mice, ANIMAL disease models, DUCHENNE muscular dystrophy, GENETIC variation, DYSTROPHIN
Abstract

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. [ABSTRACT FROM AUTHOR]

Published
2023
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5. Investigating the Impact of Delivery Routes for Exon Skipping Therapies in the CNS of DMD Mouse Models.

Author

Saoudi, Amel, Fergus, Claire, Gileadi, Talia, Montanaro, Federica, Morgan, Jennifer E., Kelly, Vincent P., Tensorer, Thomas, Garcia, Luis, Vaillend, Cyrille, Muntoni, Francesco, and Goyenvalle, Aurélie

Subjects
LABORATORY mice, DUCHENNE muscular dystrophy, DYSTROPHIN genes, SPINAL cord, BLOOD-brain barrier
Abstract

Nucleic acid-based therapies have demonstrated great potential for the treatment of monogenetic diseases, including neurologic disorders. To date, regulatory approval has been received for a dozen antisense oligonucleotides (ASOs); however, these chemistries cannot readily cross the blood–brain barrier when administered systemically. Therefore, an investigation of their potential effects within the central nervous system (CNS) requires local delivery. Here, we studied the brain distribution and exon-skipping efficacy of two ASO chemistries, PMO and tcDNA, when delivered to the cerebrospinal fluid (CSF) of mice carrying a deletion in exon 52 of the dystrophin gene, a model of Duchenne muscular dystrophy (DMD). Following intracerebroventricular (ICV) delivery (unilateral, bilateral, bolus vs. slow rate, repeated via cannula or very slow via osmotic pumps), ASO levels were quantified across brain regions and exon 51 skipping was evaluated, revealing that tcDNA treatment invariably generates comparable or more skipping relative to that with PMO, even when the PMO was administered at higher doses. We also performed intra-cisterna magna (ICM) delivery as an alternative route for CSF delivery and found a biased distribution of the ASOs towards posterior brain regions, including the cerebellum, hindbrain, and the cervical part of the spinal cord. Finally, we combined both ICV and ICM injection methods to assess the potential of an additive effect of this methodology in inducing efficient exon skipping across different brain regions. Our results provide useful insights into the local delivery and associated efficacy of ASOs in the CNS in mouse models of DMD. These findings pave the way for further ASO-based therapy application to the CNS for neurological disease. [ABSTRACT FROM AUTHOR]

Published
2023
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6. Oligonucleotide Enhancing Compound Increases Tricyclo-DNA Mediated Exon-Skipping Efficacy in the Mdx Mouse Model.

Author

Bizot, Flavien, Fayssoil, Abdallah, Gastaldi, Cécile, Irawan, Tabitha, Phongsavanh, Xaysongkhame, Mansart, Arnaud, Tensorer, Thomas, Brisebard, Elise, Garcia, Luis, Juliano, Rudolph L, and Goyenvalle, Aurélie

Subjects
DUCHENNE muscular dystrophy, LABORATORY mice, ANIMAL disease models, NEUROMUSCULAR diseases, SMALL molecules
Abstract

Nucleic acid-based therapeutics hold great promise for the treatment of numerous diseases, including neuromuscular disorders, such as Duchenne muscular dystrophy (DMD). Some antisense oligonucleotide (ASO) drugs have already been approved by the US FDA for DMD, but the potential of this therapy is still limited by several challenges, including the poor distribution of ASOs to target tissues, but also the entrapment of ASO in the endosomal compartment. Endosomal escape is a well recognized limitation that prevents ASO from reaching their target pre-mRNA in the nucleus. Small molecules named oligonucleotide-enhancing compounds (OEC) have been shown to release ASO from endosomal entrapment, thus increasing ASO nuclear concentration and ultimately correcting more pre-mRNA targets. In this study, we evaluated the impact of a therapy combining ASO and OEC on dystrophin restoration in mdx mice. Analysis of exon-skipping levels at different time points after the co-treatment revealed improved efficacy, particularly at early time points, reaching up to 4.4-fold increase at 72 h post treatment in the heart compared to treatment with ASO alone. Significantly higher levels of dystrophin restoration were detected two weeks after the end of the combined therapy, reaching up to 2.7-fold increase in the heart compared to mice treated with ASO alone. Moreover, we demonstrated a normalization of cardiac function in mdx mice after a 12-week-long treatment with the combined ASO + OEC therapy. Altogether, these findings indicate that compounds facilitating endosomal escape can significantly improve the therapeutic potential of exon-skipping approaches offering promising perspectives for the treatment of DMD. [ABSTRACT FROM AUTHOR]

Published
2023
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7. Dystrophin myonuclear domain restoration governs treatment efficacy in dystrophic muscle.

Author

Morina, Adrien, Stantzou, Amalia, Petrova, Olga N., Hildyard, John, Tensorer, Thomas, Matouk, Meriem, Petkova, Mina V., Richard, Isabelle, Manoliu, Tudor, Goyenvallea, Aurélie, Falcone, Sestina, Schuelke, Markus, Laplace-Builhé, Corinne, Piercy, Richard J., Garcia, Luis, and Amthor, Helge

Subjects
DYSTROPHIN, TREATMENT effectiveness, DUCHENNE muscular dystrophy, MUSCULAR dystrophy, GENOME editing
Abstract

Dystrophin is essential for muscle health: its sarcolemmal absence causes the fatal, X-linked condition, Duchenne muscular dystrophy (DMD). However, its normal, spatial organization remains poorly understood, which hinders the interpretation of efficacy of its therapeutic restoration. Using female reporter mice heterozygous for fluorescently tagged dystrophin (DmdEGFP), we here reveal that dystrophin distribution is unexpectedly compartmentalized, being restricted to myonuclear-defined sarcolemmal territories extending ~80 µm, which we called “basal sarcolemmal dystrophin units (BSDUs).” These territories were further specialized at myotendinous junctions, where both Dmd transcripts and dystrophin protein were enriched. Genome-level correction in X-linked muscular dystrophy mice via CRISPR/Cas9 gene editing restored a mosaic of separated dystrophin domains, whereas transcript-level Dmd correction, following treatment with tricyclo-DNA antisense oligonucleotides, restored dystrophin initially at junctions before extending along the entire fiber—with levels ~2% sufficient to moderate the dystrophic process. We conclude that widespread restoration of fiber dystrophin is likely critical for therapeutic success in DMD, perhaps most importantly, at muscle–tendon junctions. [ABSTRACT FROM AUTHOR]

Published
2023
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8. Partial Restoration of Brain Dystrophin and Behavioral Deficits by Exon Skipping in the Muscular Dystrophy X‐Linked (mdx) Mouse.

Author

Zarrouki, Faouzi, Relizani, Karima, Bizot, Flavien, Tensorer, Thomas, Garcia, Luis, Vaillend, Cyrille, and Goyenvalle, Aurélie

Subjects
MUSCULAR dystrophy, DYSTROPHIN, LONG-term memory, DUCHENNE muscular dystrophy, FEAR, MEMORY disorders
Abstract

Objectives: Duchenne muscular dystrophy is associated with various degrees of cognitive impairment and behavioral disturbances. Emotional and memory deficits also constitute reliable outcome measures to assess efficacy of treatments in the mdx mouse lacking the muscle and neuronal full‐length dystrophins. The present study aimed to evaluate whether these deficits could be alleviated by the restoration of brain dystrophin. Methods: We performed intracerebroventricular administration of a new potent tricyclo‐DNA antisense oligonucleotide (tcDNA‐ASO) containing a full phosphodiester backbone conjugated to a palmitic acid moiety (tcDNA‐ASO), designed to skip the mutated exon 23 of mdx mice. Results: We first show that the tcDNA‐ASO rescues expression of brain dystrophin to 10–30% of wild‐type levels and significantly reduces the abnormal unconditioned fear responses in mdx mice in a dose‐dependent manner, 5 weeks post‐injection. Exon skipping efficiency, ASO biodistribution, protein restoration and effect on the fear response were optimal with a dose of 400 μg at 6–7 weeks post‐injection, with synaptic‐like expression in brain tissues such as the hippocampus and amygdala. Furthermore, this dose of tcDNA‐ASO restored long‐term memory retention of mdx mice in an object recognition task, but only had minor effects on fear conditioning. Interpretation: These results suggest for the first time that postnatal re‐expression of brain dystrophin could reverse or at least alleviate some cognitive deficits associated with Duchenne muscular dystrophy. ANN NEUROL 2022;92:213–229 [ABSTRACT FROM AUTHOR]

Published
2022
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