Isabelle Courdier-Früh scite author profile

Chronic inflammation is a secondary reaction of Duchenne muscular dystrophy and may contribute to disease progression. To examine whether immunosuppressant therapies could benefit dystrophic patients, we analyzed the effects of cyclosporine A (CsA) on a dystrophic mouse model. Mdx mice were treated with 10 mg/kg of CsA for 4 to 8 weeks throughout a period of exercise on treadmill, a protocol that worsens the dystrophic condition. The CsA treatment fully prevented the 60% drop of forelimb strength induced by exercise. A significant amelioration (P < 0.05) was observed in histological profile of CsA-treated gastrocnemius muscle with reductions of nonmuscle area (20%), centronucleated fibers (12%), and degenerating area (50%) compared to untreated exercised mdx mice. Consequently, the percentage of normal fibers increased from 26 to 35% in CsA-treated mice. Decreases in creatine kinase and markers of fibrosis were also observed. By electrophysiological recordings ex vivo, we found that CsA counteracted the decrease in chloride conductance (gCl), a functional index of degeneration in diaphragm and extensor digitorum longus muscle fibers. However, electrophysiology and fura-2 calcium imaging did not show any amelioration of calcium homeostasis in extensor digitorum longus muscle fibers. No significant effect Duchenne muscular dystrophy (DMD) is a fatal genetic disorder for which no definitive cure is available. The X-linked mutation of the dystrophin gene leads to the absence of dystrophin in skeletal muscle fibers, a biochemical defect also observed in the mdx mouse, the murine phenotype of DMD. 1 Dystrophin is a subsarcolemmal protein involved in the link between the contractile machinery and the extracellular matrix. It is generally accepted that the absence of dystrophin weakens the sarcolemma and impairs the transduction of the mechanical signal imposed by the contraction. This leads to a complex and still not fully understood network of interconnected pathogenic events responsible for progressive muscle degeneration; these events involve the increased entrance of calcium, the activation of proteases, and the occurrence of a functional ischemic state. [1][2][3][4] Recent evidence suggests that a chronic inflammatory state is a secondary reaction that strongly contributes to the progression of the pathology. A significant overexpression of inflammatory and immune response genes has been described by microarray in muscle of dystrophic subjects. 5,6 Also, activated helper and cytotoxic T cells have been found to be present in higher number in muscles of dystrophic mdx mice and to promote pathology in this phenotype. 7 According to this view, immunoSupported by Telethon-Italy (to project no. 1150) and the Association Franç ais Contre les Myopathies (as part of postdoctoral fellowships to

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Reduced expression of nicotinic AChRs in myotubes from spinal muscular atrophy I patients

Arnold¹,

Gueye²,

Guettier‐Sigrist³

et al. 2004

Laboratory Investigation

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Spinal muscular atrophy (SMA) is an autosomal recessive disorder characterized by degeneration of motoneurons and skeletal muscle atrophy. In its most severe form, it leads to death before the age of 2 years. While primary degeneration of motor neurons is well established in this disease, and this results in neurogenic atrophy of skeletal muscle, we have previously reported evidence for a primary muscle defect. In this study, we used primary cultures of embryonic human skeletal muscle cells from patients with SMA and from controls to examine the effects of muscle fiber differentiation in the absence of a nerve component. Cultured SMA skeletal muscle cells are unable to fuse correctly to form multinuclear myotubes, the precursors of the myofibers. We also show that agrin-induced aggregates of nicotinic acetylcholine receptors, one of the earliest steps of neuromuscular junction formation, cannot be visualized by confocal microscopy on cells from SMA patients. In binding experiments, we demonstrate that this lack of clustering is due to defective expression of the nicotinic acetylcholine receptors in the myotubes of SMA patients whereas the affinity of a-bungarotoxin for its receptor remains unchanged regardless of muscle cell type (SMA or control). These observations suggest that muscle cells from SMA patients have intrinsic abnormalities that may affect proper formation of the neuromuscular junction. Keywords: spinal muscular atrophy; myotubes; neuromuscular junction; nicotinic acetylcholine receptors; aggregation; binding Spinal muscular atrophy (SMA) is a neuromuscular disorder characterized by degeneration of spinal motor neurons leading to a muscle weakness and paralysis. SMA is traditionally classified into three types based on the age of onset and the severity of symptoms. 1 The SMA I or Werdnig-Hoffmann disease is the most severe form. Patients never attain the ability to sit, and their lifespan does not exceed infancy in most cases. SMA II is the intermediate form. Patients are unable to stand or walk unaided, and death usually occurs in adulthood. SMA III or Kugelberg-Welander disease presents a milder phenotype. Patients are able to stand and walk and present a near-normal life expectancy. The gene responsible for all three types of SMA was mapped to the region 5q11.2-13.3 by linkage analysis. [2][3][4][5] This gene, named SMN for 'survival of motor neurons', is mutated in 98% of the SMA patients, and the majority of mutations occur in exon 7. 6 It encodes a ubiquitously expressed SMN protein present in both the cytoplasm and the nucleus. In this last compartment, the SMN protein is concentrated in structures called gems (for 'gemini of coiled bodies') located in the close proximity of Cajal bodies (previously named coiled bodies). 7,8 The SMN protein participates in the formation of the SMN complex, which is associated with small nuclear ribonucleoproteins (snRNP) in the cytoplasm and plays a crucial role in the spliceosomal snRNP assembly. 9 In the nucleus, the SMN complex participates in the regener...

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Omigapil Ameliorates the Pathology of Muscle Dystrophy Caused by Laminin-α2 Deficiency

Erb

Meinen²,

Barzaghi³

et al. 2009

J Pharmacol Exp Ther

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Laminin ␣2-deficient congenital muscular dystrophy, called MDC1A, is a rare, devastating genetic disease characterized by severe neonatal hypotonia ("floppy infant syndrome"), peripheral neuropathy, inability to stand or walk, respiratory distress, and premature death in early life. Transgenic overexpression of the apoptosis inhibitor protein BCL-2, or deletion of the proapoptotic Bax gene in a mouse model for MDC1A prolongs survival and mitigates pathology, indicating that apoptotic events are involved in the pathology. Here we demonstrate that the proapoptotic glyceraldehyde-3-phosphate dehydrogenase (GAPDH)-Siah1-CBP/p300-p53 pathway is activated in a mouse model for MDC1A. Moreover, we show that omigapil, which inhibits GAPDH-Siah1-mediated apoptosis, ameliorates several pathological hallmarks in the MDC1A mouse model. Specifically, we demonstrate that treatment with omigapil inhibits apoptosis in muscle, reduces body weight loss and skeletal deformation, increases locomotive activity, and protects from early mortality. These data qualify omigapil, which is in late phase of clinical development for human use, as a drug candidate for the treatment of MDC1A.

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Long-term blinded placebo-controlled study of SNT-MC17/idebenone in the dystrophin deficient mdx mouse: cardiac protection and improved exercise performance

Buyse

Mieren

Erb

et al. 2008

European Heart Journal

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AimsDuchenne muscular dystrophy (DMD) is a severe and still incurable disease, with heart failure as a leading cause of death. The identification of a disease-modifying therapy may require early-initiated and long-term administration, but such type of therapeutic trial is not evident in humans. We have performed such a trial of SNT-MC17/idebenone in the mdx mouse model of DMD, based on the drug’s potential to improve mitochondrial respiratory chain function and reduce oxidative stress.Methods and resultsIn this study, 200 mg/kg bodyweight of either SNT-MC17/idebenone or placebo was given from age 4 weeks until 10 months in mdx and wild-type mice. All evaluators were blinded to mouse type and treatment groups. Idebenone treatment significantly corrected cardiac diastolic dysfunction and prevented mortality from cardiac pump failure induced by dobutamine stress testing in vivo, significantly reduced cardiac inflammation and fibrosis, and significantly improved voluntary running performance in mdx mice.ConclusionWe have identified a novel potential therapeutic strategy for human DMD, as SNT-MC17/idebenone was cardioprotective and improved exercise performance in the dystrophin-deficient mdx mouse. Our data also illustrate that the mdx mouse provides unique opportunities for long-term controlled prehuman therapeutic studies.

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