Project description:Duchenne muscular dystrophy (DMD) is an X-linked progressive muscle disorder resulting in muscle weakness and cardiomyopathy. MicroRNAs have shown to play a significant role in muscle development, metabolism, and disease pathologies. We demonstrated that miR-486 expression is reduced in DMD muscles and its expression levels correlate with dystrophic disease severity. miR-486 knockout mice developed disrupted myofiber architecture, decreased myofiber size, decreased locomotor activity, increased fibrosis, and metabolic defects that were exacerbated on the dystrophic mdx5cv background. We integrated RNA-sequencing and chimeric eCLIP-sequencing data to identify direct in vivo targets of miR-486 and associated dysregulated gene signatures in skeletal muscle. Together, our studies identify miR-486 as a driver of muscle remodeling in DMD, a useful biomarker for dystrophic disease progression, and highlight chimeric eCLIP-sequencing as a useful tool to identify direct in vivo microRNA target transcripts.

Project description:Duchenne muscular dystrophy (DMD) is an X-linked progressive muscle disorder resulting in muscle weakness and cardiomyopathy. MicroRNAs have shown to play a significant role in muscle development, metabolism, and disease pathologies. We demonstrated that miR-486 expression is reduced in DMD muscles and its expression levels correlate with dystrophic disease severity. miR-486 knockout mice developed disrupted myofiber architecture, decreased myofiber size, decreased locomotor activity, increased fibrosis, and metabolic defects that were exacerbated on the dystrophic mdx5cv background. We integrated RNA-sequencing and chimeric eCLIP-sequencing data to identify direct in vivo targets of miR-486 and associated dysregulated gene signatures in skeletal muscle. Together, our studies identify miR-486 as a driver of muscle remodeling in DMD, a useful biomarker for dystrophic disease progression, and highlight chimeric eCLIP-sequencing as a useful tool to identify direct in vivo microRNA target transcripts.

Project description:Asynchronous skeletal muscle degeneration/regeneration is a hallmark feature of Duchenne muscular dystrophy (DMD); however, traditional -omics technologies that lack spatial context make it difficult to study the biological mechanisms of how asynchronous regeneration contributes to disease progression. Here, using the severely dystrophic D2-mdx mouse model, we generated a high-resolution cellular and molecular spatial atlas of dystrophic muscle by integrating spatial transcriptomics and single-cell RNAseq datasets.

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:We report here on the identification and functional characterization of Sca1-positive muscle interstitial cells that contribute to regeneration or fibroadipogenic degeneration of dystrophic muscles and mediate the beneficial effects of HDAC inhibitors (HDACi) in mdx mice. We found that the phenotype adopted by these cells and their biological activity are influenced by changes in muscle environment. While Sca1-positive muscle interstitial cells from healthy muscles spontaneously adopt a fibro-adipogenic phenotype, Sca1-positive muscle interstitial cells isolated from dystrophic muscles of young mdx mice show a latent myogenic phenotype that is implemented by the exposure to HDACi. Co-culture assays in vitro and co-transplantation experiments in vivo demonstrate that HDACi also improve Sca1-positive muscle interstitial cell ability to enhance the differentiation potential of adjacent satellite cells. Importantly, HDACi-induced myogenic phenotype and pro-regeneration activity were not observed in Sca1-positive muscle interstitial cells isolated from muscles of old mdx mice. The different phenotype of Sca1-positive muscle interstitial cells from mdx mice at different stages of disease progression correlated with the stage-dependent beneficial effect of HDACi, which were effective only at early stages of disease. Transplantation of Sca1-positive muscle interstitial cells isolated from regenerating young muscles into muscles of old mdx mice restored HDACi ability to increase myofiber size. These results indicate that Sca1-positive muscle interstitial cells are key cellular determinants of disease progression and mediate the beneficial effect of HDACi in a mouse model of muscular dystrophy. Isolation of Sca1+ muscle interstitial cells from TSA treated DMD/MDX mice and MuSc from DMD/MDX mice

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:Fibro-adipogenic progenitors (FAPs) are emerging cellular components of the skeletal muscle regenerative environment. The alternative functional phenotype of FAPs - either supportive of muscle regeneration or promoting fibro-adipogenic degeneration - is a key determinant in the pathogenesis of muscular diseases, including Duchenne Muscular Dystrophy (DMD). However, the molecular regulation of FAPs is still unknown. We show here that an "HDAC-myomiR-BAF60 variant network" regulates the functional phenotype of FAPs in dystrophic muscles of mdx mice. Combinatorial analysis of gene expression microarray and genome-wide chromatin remodeling by Nuclease accessibility (NA)-seq revealed that HDAC inhibitors de-repress a "latent" myogenic program in FAPs from dystrophic muscles at early stages of disease progression. In these cells HDAC inhibition promoted the expression of two core components of the myogenic transcriptional machinery, MyoD and BAF60C, and upregulated the myomiRs (miRs) miR-1.2, miR-133 and miR-206, which target two alternative BAF60 variants (BAF60A and B) ultimately leading to the activation of a pro-myogenic program at the expense of the fibro-adipogenic phenotype. By contrast, FAPs from dystrophic muscles at late stages of disease progression displayed resistance to HDACi-induced chromatin remodeling at myogenic loci and fail to activate the pro-myogenic phenotype. These results reveal a previously unappreciated disease stage-specific bipotency of mesenchimal cells within the regenerative environment of dystrophic muscles. Resolution of such bi-potency by epigenetic interventions, such as HDACi, provides the molecular rationale for the in situ reprogramming of target cells to promote therapeutic regeneration of dystrophic muscles. miRNA modulation upon Histone Deacetylase inhibition in Fibro-Adipogenic Progenitors (FAPs) derived from young mdx mice was evaluated by small RNA-sequencing in 2 controls and 2 treated samples

Project description:Fibro-adipogenic progenitors (FAPs) are emerging cellular components of the skeletal muscle regenerative environment. The alternative functional phenotype of FAPs - either supportive of muscle regeneration or promoting fibro-adipogenic degeneration M-bM-^@M-^S is a key determinant in the pathogenesis of muscular diseases, including Duchenne Muscular Dystrophy (DMD). However, the molecular regulation of FAPs is still unknown. We show here that an M-bM-^@M-^\HDAC-myomiR-BAF60 variant networkM-bM-^@M-^] regulates the functional phenotype of FAPs in dystrophic muscles of mdx mice. Combinatorial analysis of gene expression microarray and genome-wide chromatin remodeling by Nuclease accessibility (NA)-seq revealed that HDAC inhibitors de-repress a M-bM-^@M-^\latentM-bM-^@M-^] myogenic program in FAPs from dystrophic muscles at early stages of disease progression. In these cells HDAC inhibition promoted the expression of two core components of the myogenic transcriptional machinery, MyoD and BAF60C, and upregulated the myomiRs (miRs) 1.2, 133 and 206, which target two alternative BAF60 variants (BAF60A and B) ultimately leading to the activation of a pro-myogenic program at the expense of the fibro-adipogenic phenotype. By contrast, FAPs from dystrophic muscles at late stages of disease progression displayed resistance to HDACi-induced chromatin remodeling at myogenic loci and fail to activate the pro-myogenic phenotype. These results reveal a previously unappreciated disease stage-specific bipotency of mesenchimal cells within the regenerative environment of dystrophic muscles. Resolution of such bi-potency by epigenetic interventions, such as HDACi, provides the molecular rationale for the in situ reprogramming of target cells to promote therapeutic regeneration of dystrophic muscles. Genome-wide chromatin accessibility patterns in FAPs cells derived from mdx mice at different ages treated either with HDAC inhibitor Trichostatin A (TSA) or with vehicle (saline solution) were assessed using NA-seq (PMID: 19289091)

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 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.