Approches de thérapies géniques pour des maladies neuromusculaires / Gene therapy approaches for neuromuscular disorders

Moulay, Gilles

09 July 2010

La thérapie génique de myopathies telles que la dystrophie musculaire de Duchenne nécessite une approche systémique afin de traiter l’ensemble de la musculature. Le vecteur AAV est actuellement le plus efficace pour transduire le muscle. Nous montrons que la biodistribution du vecteur AAV administré par voie veineuse peut être modifiée en utilisant diverses stratégies adjuvantes chez la souris saine. La pré-injection de polymères permet ainsi d’améliorer la transduction des muscles par le vecteur AAV, ou encore de baisser la réponse immune neutralisante induite par l’injection intraveineuse du vecteur. Nous abordons également l’impact de facteurs modulateurs exogènes ou endogènes – tels que la procédure d’administration ou certains facteurs sanguins – sur la transduction systémique de l’AAV. Dans une seconde approche, nous avons évalué le transfert de gènes dans le muscle dystrophique afin de sécréter dans la circulation sanguine une protéine transgénique fusionnant le récepteur soluble I du TNF-α avec le fragment constant d’une immunoglobuline (TNFR-Is/mIgG1). La comparaison des cinétiques de sécrétion obtenu après le transfert de gène dans le muscle de souris saines ou de souris dystrophiques mdx indique que le contexte inflammatoire du muscle dystrophique favorise une réponse immune contre le transgène. Nous montrons que l’expression et la sécrétion d’un variant murin peu immunogène du TNFR-Is/mIgG1 améliore la fonction musculaire de la souris mdx sans toutefois conférer un avantage sélectif aux fibres musculaires dystrophiques qui continuent leur cycle de nécrose et de régénération. / Gene therapy of myopathies such as Duchenne muscular dystrophy requires a systemic approach in order to treat the whole musculature. The AAV vector is currently the most efficient delivery system for muscle transduction. We show that the biodistribution of AAV administered intravenously can be modified using different adjuvant strategies in healthy mice. In particular, the pre-injection of polymers enables an improvement of muscle transduction by AAV, and can also decrease the neutralizing immune response induced by the intravenous injection of this vector. We also explored in this work the impact of exogenous and endogenous modulating factors – such as the administration procedure or some blood factors – on the AAV transduction capacity. In a second approach, we evaluated gene transfer in dystrophic muscles in order to secrete in the blood circulation a transgenic protein associating the soluble TNF-α receptor I and the Fc fragment of an immunoglobulin (TNFR-Is/mIgG1). The comparison of the kinetic of secretion after muscle gene transfer in healthy and dystrophic mice indicates that the inflammatory context of dystrophic muscle increases the immune response against the transgene. We also show that while the expression and secretion of a low immunogenic murine variant of TNFR-Is/mIgG1 improves the mdx muscle function, it does not confer a selective advantage to muscle fibers which still undergo cycles of necrosis and regeneration.

Muscle dystrophique

Dystrophic muscle

Characterisation and strategic treatment of dystrophic muscle

Laws, Nicola

January 2005

The mdx mouse is widely used as a model for Duchenne Muscular Dystrophy, a fatal X-linked disease caused by a deficiency of the sub-sarcolemmal protein, dystrophin. This dissertation reports characterisation of the features of dystrophy in the mdx mouse, including parameters such as electrophysiological and contractile properties of dystrophic cardiac tissue, quantitative evaluation of kyphosis throughout the mdx lifespan, and contractile properties of respiratory and paraspinal muscles. Following these characterisation studies, the efficacy of antisense oligonucleotides (AOs) to induce alternative mRNA splicing in mdx skeletal muscles (diaphragm and paraspinal muscles) was evaluated. The left atria of younger (<6 weeks) and older (>15 months) mdx mice showed consistently lower basal forces and responsiveness to increased calcium, while action potential duration was significantly shorter in young mice (3 weeks) and older mice (9 and 12 months) (P<0.05). Cardiac fibrosis increased with age in mdx atria and ventricles and was elevated in young (6-8 weeks) and old (15 months) mdx compared to control mice (P<0.01). This study provided insights into DMD cardiomyopathy, and suggested that very young or old mdx mice provide the most useful models. Mdx mice show thoracolumbar kyphosis like boys with Duchenne Muscular Dystrophy. A novel radiographic index, the Kyphotic Index (KI), was developed and showed that mdx mice are significantly more kyphotic from 9 months of age, an effect maintained until 17 months (P<0.05). At 17 months, the paraspinal and respiratory muscles (latissimus dorsi, diaphragm and intercostal muscles) are significantly weaker and more fibrotic (P<0.05). Administration of AOs at four sites within the diaphragm at 4 and 5 months of age significantly increased twitch and tetanic forces compared to sham treated mdx (P<0.05). However, no difference in collagen was evident and dystrophin was not detected, possibly due to the low concentration of AO utilised. This study suggested that AOs can provide functional improvement in treated skeletal muscles. Monthly injections with AOs into the paraspinal muscles from 2 months to 18 months of age alleviated kyphosis, without significantly altering twitch and tetanic forces of latissimus dorsi, diaphragm and intercostal muscles. There was evidence of less fibrosis in diaphragm and latissimus dorsi muscles (P<0.05) and reduced central nucleation of the latissimus dorsi and intercostal muscles (P<0.05). Again, dystrophin was not detected by immunoblot. These studies indicate that very young and old mdx mice display previously uncharacterised dystrophic features, and are useful models for testing new therapies such as AOs. Low doses of AOs were shown to be safe and efficacious for long-term use, however there remains a need for testing higher concentrations and improved delivery strategies.

dystrophic muscle

Duchenne Muscular Dystrophy (DMD)

antisense oligonucleotides (AOs)

dystrophin

muscular dystrophy X-linked mouse (mdx)