Project description:Duchenne muscular dystrophy (DMD) is a debilitating and typically fatal X-linked progressive neuromuscular disorder that results in progressive muscle degeneration aggravated by sterile inflammation. The P2RX7 purinoceptor is an extracellular ATP-gated ion channel expressed in immune cells, and has been targeted in treatment of infectious and inflammatory diseases. In particular, P2xr7 receptor abnormalities have been demonstrated in mdx dystrophic mice, a model for DMD lacking expression of the full length dystrophin transcript through a single point mutation in exon 23. Here, we looked at the differential effects in gene expression regulation in whole muscle in dystrophic mdx mice with or without ablation of the P2rx7 purinoceptor.

Project description:Duchenne muscular dystrophy (DMD) is a progressive severe muscle-wasting disease caused by mutations in DMD encoding dystrophin that leads to loss of muscle function with cardiac/respiratory failure and premature death. Since dystrophic muscles are sensed by infiltrating inflammatory cells and gut microbial communities can cause immune dysregulation and metabolic syndrome, we sought to investigate whether intestinal bacteria may support the muscle immune response in mdx dystrophic animal model. We assess this question here through unbiased profiling of muscle transcriptome through RNAseq. We found that the absence of gut microbes through the generation of a mdx GF animal model as well as modulation of the microbial community structure by antibiotic treatment revealed the ability of the dystrophic-associated intestinal microbiota to modulate immunity and secondary muscle pathogenetic mechanisms of DMD, including inflammation, fibrosis, and atrophy.

Project description:Duchenne muscular dystrophy (DMD) is characterized by progressive skeletal muscle degeneration. No treatments are currently available to prevent the disease. While the muscle enriched microRNA, miR-133b, has been implicated in muscle biogenesis, its role in DMD remains unknown. To assess miR-133b function in DMD-affected skeletal muscles, we genetically ablated miR-133b in the mdx mouse model of DMD. In the absence of miR-133b, the tibialis anterior muscle of juvenile and adult mdx mice is populated by small muscle fibers and exhibits increased fibrosis, characterized by thickened interstitial space. Additional analysis revealed that loss of miR-133b exacerbates DMD-pathogenesis partly by altering satellite cell numbers and through widespread transcriptomic changes. These include known miR-133b targets as well as genes involved in cell proliferation and fibrosis. Altogether, our data demonstrate that skeletal muscles utilize miR-133b to mitigate the deleterious effects of DMD.

Project description:Duchenne muscular dystrophy (DMD) is a genetic disease that results in the death of affected boys by early adulthood.The genetic defect responsible for DMD has been known for over 25 years, yet at present there is neither cure nor effective treatment for DMD. During early disease onset, the mdx mouse has been validated as an animal model for DMD and use of this model has led to valuable but incomplete insights into the disease process. For example, immune cells are thought to be responsible for a significant portion of muscle cell death in the mdx mouse; however, the role and time course of the immune response in the dystrophic process have not been well described. In this paper we constructed a simple mathematical model to investigate the role of the immune response in muscle degeneration and subsequent regeneration in the mdx mouse model of Duchenne muscular dystrophy. Our model suggests that the immune response contributes substantially to the muscle degeneration and regeneration processes. Furthermore, the analysis of the model predicts that the immune system response oscillates throughout the life of the mice, and the damaged fibers are never completely cleared.

Project description:Duchenne muscular dystrophy (DMD) is a fatal muscle-wasting disorder caused by mutations in the Dystrophin gene with no therapeutic option. To bridge the gap between preclinical and therapeutic evaluation studies, we have generated a rat model for DMD that carries an exon 52 deletion (R DMDdel52) causing a complete lack of dystrophin protein. Here we show that R DMDdel52 animals recapitulated human DMD pathophysiological trajectory more faithfully than the mdx mouse model. We report that R DMDdel52 rats displayed progressive and severe skeletal muscle loss associated with fibrotic deposition, fat infiltration and fibre type switch. Early fibrosis was also apparent in the cardiac muscle. These histological modifications led to severe muscle, respiratory and cardiac functional impairments leading to premature death around one year. Moreover, DMD muscle exhibited systemic inflammation with a mixed M1/M2 phenotype. A comparative single cell RNAseq analysis of the diaphragm muscle was performed, revealing cellular populations alteration and molecular modifications in all muscle cell types. We show that DMD fibroadipogenic progenitors produced elevated levels of cartilage oligomeric matrix protein (COMP), a glycoprotein responsible for modulating homeostasis of extracellular matrix, and whose increased concentration correlated with muscle fibrosis both in R DMDdel52 rats and human patients. Fibrosis is a component of tissue remodelling impacting the whole musculature of DMD patients, at the tissue level but most importantly at the functional level. We therefore propose that this specific biomarker can optimize the prognostic monitoring of functional improvement of patients included in clinical trials.

Project description:Duchenne muscular dystrophy (DMD) is caused by mutations in the X-linked dystrophin (DMD) gene. The absence of dystrophin protein leads to progressive muscle weakness and wasting, disability and death. To establish a tailored large animal model of DMD, we deleted DMD exon 52 in male pig cells by gene targeting and generated offspring by nuclear transfer. DMD pigs exhibit absence of dystrophin in skeletal muscles, increased serum creatine kinase levels, progressive dystrophic changes of skeletal muscles, impaired mobility, muscle weakness, and a maximum life span of 3 months due to respiratory impairment. To address the accelerated development of muscular dystrophy in DMD pigs as compared to human patients, we performed a genome-wide transcriptome study of M. biceps femoris samples from 2-day-old and 3-month-old DMD and age-matched wild-type pigs. The transcriptome changes in 3-month-old DMD pigs were in good accordance with the findings of gene expression profiles in human DMD, reflecting the processes of degeneration, regeneration, inflammation, fibrosis, and impaired metabolic activity. The transcriptome profile of 2-day-old DMD pigs pointed towards increased protein and DNA catabolism, reduced extracellular matrix formation and cell proliferation and showed similarities with transcriptome changes induced by exercise injury in muscle. Our transcriptome studies provide new insights into congenital changes associated with dystrophin deficiency and secondary complications arising during postnatal development. Thus the DMD pig is a useful model to determine the hierarchy of physiological derangements in dystrophin-deficient muscle. 13 samples, two conditions, two age-groups, 3-4 biological replicates

Project description:Duchenne muscular dystrophy (DMD) is an X-linked recessive disease caused by deleterious mutations in the DMD gene, rendering non-functional forms or complete absence of the protein dystrophin. Eccentric contraction-induced force loss is the most robust and reproducible phenotype of dystrophin-deficient skeletal muscle, yet the molecular mechanisms underlying force loss remain obscure. To this end, we utilized the mdx mouse model of DMD, which displays extreme sensitivity to eccentric contractions. An existing mouse line from our lab that overexpresses cytoplasmic gamma-actin specifically in skeletal muscle (mdx/Actg1-TG) was shown to significantly protect mdx muscle against contraction-induced force loss. To understand the mechanism behind this protection, we performed iTRAQ proteomics on mdx/Actg1-TG tibialis anterior (TA) muscle versus non-transgenic littermate controls to identify differentially-expressed proteins that may afford protection upon gamma-actin overexpression.

Project description:Pathophysiology of Duchenne Muscular Dystrophy (DMD) is still elusive. Although progressive damage to muscle fibres is a cause of muscle deterioration leading to premature death, there is a growing body of evidence indicating that the triggering effects of DMD mutation are present at the very early stage of muscle development. To study this, we have performed an RNA-seq experiment to compare the transcriptional profile of early stage myoblasts from dystrophic mice compared to WT mice. We have used a myoblast cell line carrying the mdx mutant allele (SC5), which results in a premature stop codon in the Dystrophin gene, leading to a dystrophic phenotype. The WT cell line is the IMO myoblast cell line.

Project description:ABSTRACT Stimulating the commitment of implanted dystrophin+ muscle derived stem cells (MDSC) into myogenic, as opposed to lipofibrogenic, lineages is a promising therapeutic strategy for Duchenne muscular dystrophy (DMD). To examine whether counteracting myostatin, a negative regulator of muscle mass and a pro-lipofibrotic factor, would help this process, we compared the in vitro myogenic and fibrogenic capacity of MDSC from wild type (WT), myostatin knockout (Mst KO), and mdx (DMD model) (mdx) young mice under various modulators, the expression of key stem cell and myogenic genes, and the capacity of these MDSC to repair the injured gastrocnemius in aged mdx mice with exacerbated lipofibrosis. Surprisingly, the potent in vitro myotube formation by WT MDSC was refractory to modulators of myostatin expression or activity, and the Mst KO and mdx MDSC failed to form myotubes under any condition, despite all MDSC expressed Oct-4 and various stem cell genes and differentiated into other lineages. The genetic inactivation of myostatin or dystrophin in MDSC was associated with silencing of critical genes for early myogenesis (Actc1, Acta1, and MyoD). WT MDSC implanted into the injured gastrocnemius of old mdx mice significantly improved myofiber repair and reduced fat deposition and, to a lesser extent, fibrosis. In contrast to their in vitro behavior, Mst KO MDSC in vivo also significantly improved myofiber repair, but had no significant effects on lipofibrotic degeneration. In conclusion, while WT MDSC are considerably myogenic in culture and stimulate muscle repair after injury in the aged mdx mouse, myostatin genetic inactivation blocks myotube formation in vitro but the myogenic capacity is recovered in vivo under the influence of the host tissue environment, presumably by reactivation of key genes originally silenced in the Mst KO MDSC. Key words: dystrophin, mdx mouse, Duchenne, fibrosis, dystrophy One sample each of mouse wild type (WT), myostatin knockout (KO), muscular dystrophy model mdx, and the transgenic OCT4 promoter plus reporter were grown, RNA was isolated, and subjected to the SABiosciences mouse stem cell oligo array.

Project description:Duchenne muscular dystrophy (DMD) is characterized by impaired cytoskeleton organization, cytosolic calcium handling oxidative stress and mitochondrial dysfunction. This results in progressive and fatal muscle damage, wasting and weakness. The Striated Muscle activator of Rho signalling (STARS) is an actin binding protein that activates the myocardin-related transcription factor-A (MRTFA)/serum response factor (SRF) transcriptional pathway; a pathway that regulates cytoskeletal structure, muscle function, growth and repair. Here we investigated the regulation of several members of the STARS signalling pathway in muscle from patients with DMD and the dystrophin-deficient mdx and dko (utrophin‐ and dystrophin‐null) mice. A reduction in protein levels of STARS, SRF and RHOA, and an increase in MRTFA were observed in quadriceps muscle of patients with DMD. STARS, SRF and MRTFA mRNA levels were also decreased in DMD muscle, while Stars mRNA levels were decreased in mdx tibialis anterior (TA) muscle and Srf and Mrtfa mRNAs were decreased in dko TA muscle. Overexpressing the human STARS (hSTARS) protein in mdx TA muscle increased maximal isometric specific force by 13%. This was not associated with changes in muscle mass, fibre cross-sectional area (CSA), fibre type, centralized nuclei or collagen deposition. Proteomics screening identified 31 upregulated and 22 downregulated proteins or individual peptides that were significantly regulated by hSTARS overexpression. Pathway enrichment analysis indicated that hSTARS overexpression regulated the keratin, NRF2 and oxidative phosphorylation (OXPHOS) pathways. These pathways are impaired in dystrophic muscle and regulate cytoskeleton organization, oxidative stress and mitochondrial energy production; processes that are vital for muscle function. We conclude that increasing the STARS protein in dystrophic muscle improves muscle force production, potentially via its regulation of multiple pathways that positively influence cytoskeletal structure, oxidative stress and energy production.