UMLS:C0026850 - FACTA Search

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Query: UMLS:C0026850 (muscular dystrophy)
5,870 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Myogenic regulatory factors (MRFs) promote differentiation of muscle cells from fibroblasts and are induced by insulin-like growth factor I (IGF-1). Prior studies have shown synthesis of new muscle protein and improved muscle morphology when mature dy mice with muscular dystrophy are treated with IGF-1. We investigated whether these salutary effects of IGF-1 might be attributable to stimulation of MRFs. Male dy (129ReJ) mice and controls (129J) were assigned to IGF-1 treatment (10 micrograms twice daily) or non-treatment at about 5 weeks of life and sacrificed 6 weeks later. RNA was extracted from skeletal muscles, reverse transcribed, and amplified by polymerase chain reaction (PCR) using primers specific for each MRF. Competitive PCR was performed to quantify MyoD expression in response to IGF-1 treatment. Transcripts for myf-5, MRF4, and myogenin were detected in both control and dy mouse muscles; no apparent differences were observed between treatment groups. Quantitative analysis of transcripts for MyoD indicated no significant basal differences between control and dy mice. There was, however, significantly higher MyoD expression in the dy group, and a trend toward significance in the control group, following IGF-1 treatment. These data suggest that IGF-1 exerts its in vivo effects in postembryonal muscle by stimulating MRFs.
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PMID:Expression of myogenic regulatory factors in normal and dystrophic mice: effects of IGF-1 treatment. 916 95

Four sarcoglycan subunit proteins, alpha-, beta-, gamma- and delta-sarcoglycans, form a complex on the skeletal muscle cell surface membrane and a gene defect in any one of them causes the loss or marked decrease of whole sarcoglycan complex, resulting in an autosomal recessive muscular dystrophy, sarcoglycanopathy. To characterize the regulation of sarcoglycan transcription during myocyte differentiation, we isolated the promoter regions for all sarcoglycan transcripts and measured the level of transcriptional activity of these promoter regions in the C2C12 skeletal muscle cell line. The promoters of gamma-sarcoglycan and one of two promoters of alpha-sarcoglycan exhibited marked transcriptional activation following differentiation to myotubes. Then, we characterized the 1.5-kb region of the gamma-sarcoglycan promoter by generating reporter-constructs having various deletions and measuring their transcriptional activities. In this promoter, we identified a basal promoter region and two enhancer regions dependent on differentiation. We also showed that A/T-rich and E box elements in the upstream enhancer region are essential for the activation of gamma-sarcoglycan transcription following myotube formation. Furthermore, from the identification of binding proteins to these elements together with the cotransfection experiments with the gamma-sarcoglycan promoter reporter construct and cDNAs encoding these binding factors to 10T1/2 fibroblast cell line, it was suggested that MyoD directs the transcription of gamma-sarcoglycan gene as one of the trans activators.
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PMID:Identification of myogenesis-dependent transcriptional enhancers in promoter region of mouse gamma-sarcoglycan gene. 1117 61

Syndecan-3 and syndecan-4 function as coreceptors for tyrosine kinases and in cell adhesion. Syndecan-3(-/-) mice exhibit a novel form of muscular dystrophy characterized by impaired locomotion, fibrosis, and hyperplasia of myonuclei and satellite cells. Explanted syndecan-3(-/-) satellite cells mislocalize MyoD, differentiate aberrantly, and exhibit a general increase in overall tyrosine phosphorylation. Following induced regeneration, the hyperplastic phenotype is recapitulated. While there are fewer apparent defects in syndecan-4(-/-) muscle, explanted satellite cells are deficient in activation, proliferation, MyoD expression, myotube fusion, and differentiation. Further, syndecan-4(-/-) satellite cells fail to reconstitute damaged muscle, suggesting a unique requirement for syndecan-4 in satellite cell function.
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PMID:Essential and separable roles for Syndecan-3 and Syndecan-4 in skeletal muscle development and regeneration. 1537 36

We recently developed a new cDNA microarray encompassing more than 5,000 genes expressed in human skeletal muscle. We successfully identified the differences at the gene expression profiles among Duchenne muscular dystrophy patients. Using our microarray, we catalogued gene expression during myogenic differentiation. The resultant expression patterns were classified into eight groups by hierarchical cluster analysis. Among them, clusters 6, 7, and 8 contain genes which show high expression level at the later differentiation stage and encode mainly sarocmere and extracellular matrix proteins. We used genes in these clusters as markers for regeneration. We identified that these regeneration-associated genes were not necessarily upregulated in Fukuyama congenital muscular dystrophy (FCMD) even though necrosis-associated genes were highly upregulated, suggesting the insufficient regenerating capability in FCMD. We have also characterized genes regulated by IGF-I simulation. We subject cascade specific inhibitors and IGF-I to human myotubes and performed gene expression profiling using our cDNA microarray. We found that PI3K/Akt-1 cascade first activates transcriptional factors such as MyoD, myogenin, and MEF2C, and then genes in clusters 6, 7, and 8, which have E-box and MEF-box where these transcriptional factors associate. We expect to develop a new therapeutic method by elucidating the molecular mechanism of muscular dystrophy and the effect of IGF-I and anti-myostatin treatments.
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PMID:[The pathomechanism and the direction of therapy development in view of cDNA microarray]. 1565 27

To examine the role of apoptosis in neuromuscular disease progression, we have determined whether pathogenesis in dystrophin-deficient (mdx) and laminin alpha2-deficient (Lama2-null) mice is ameliorated by overexpression of the anti-apoptosis protein BCL2 in diseased muscles. The mdx mice are a model for the human disease, Duchenne muscular dystrophy (DMD), and the Lama2-null mice are a model for human congenital muscular dystrophy type 1A (MDC1A). For these studies, we generated transgenic mice that overexpressed human BCL2 under control of muscle-specific MyoD or MRF4 promoter fragments. We then used cross-breeding to introduce the transgenes into diseased mdx or Lama2-null mice. In mdx mice, we found that overexpression of BCL2 failed to produce any significant differences in muscle pathology. In contrast, in the Lama2-null mice, we found that muscle-specific expression of BCL2 led to a several-fold increase in lifespan and an increased growth rate. Thus, BCL2-mediated apoptosis appears to play a significant role in pathogenesis of laminin alpha2 deficiency, but not of dystrophin deficiency, suggesting that therapies designed to ameliorate disease by inhibition of apoptosis are more likely to succeed in MDC1A than in DMD.
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PMID:Muscle-specific BCL2 expression ameliorates muscle disease in laminin {alpha}2-deficient, but not in dystrophin-deficient, mice. 1575 77

Mutations of lamin A/C (LMNA) cause a wide range of human disorders, including progeria, lipodystrophy, neuropathies and autosomal dominant Emery-Dreifuss muscular dystrophy (EDMD). EDMD is also caused by X-linked recessive loss-of-function mutations of emerin, another component of the inner nuclear lamina that directly interacts with LMNA. One model for disease pathogenesis of LMNA and emerin mutations is cell-specific perturbations of the mRNA transcriptome in terminally differentiated cells. To test this model, we studied 125 human muscle biopsies from 13 diagnostic groups (125 U133A, 125 U133B microarrays), including EDMD patients with LMNA and emerin mutations. A Visual and Statistical Data Analyzer (VISDA) algorithm was used to statistically model cluster hierarchy, resulting in a tree of phenotypic classifications. Validations of the diagnostic tree included permutations of U133A and U133B arrays, and use of two probe set algorithms (MAS5.0 and MBEI). This showed that the two nuclear envelope defects (EDMD LMNA, EDMD emerin) were highly related disorders and were also related to fascioscapulohumeral muscular dystrophy (FSHD). FSHD has recently been hypothesized to involve abnormal interactions of chromatin with the nuclear envelope. To identify disease-specific transcripts for EDMD, we applied a leave-one-out (LOO) cross-validation approach using LMNA patient muscle as a test data set, with reverse transcription-polymerase chain reaction (RT-PCR) validations in both LMNA and emerin patient muscle. A high proportion of top-ranked and validated transcripts were components of the same transcriptional regulatory pathway involving Rb1 and MyoD during muscle regeneration (CRI-1, CREBBP, Nap1L1, ECREBBP/p300), where each was specifically upregulated in EDMD. Using a muscle regeneration time series (27 time points) we develop a transcriptional model for downstream consequences of LMNA and emerin mutations. We propose that key interactions between the nuclear envelope and Rb and MyoD fail in EDMD at the point of myoblast exit from the cell cycle, leading to poorly coordinated phosphorylation and acetylation steps. Our data is consistent with mutations of nuclear lamina components leading to destabilization of the transcriptome in differentiated cells.
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PMID:Nuclear envelope dystrophies show a transcriptional fingerprint suggesting disruption of Rb-MyoD pathways in muscle regeneration. 1647 98

Mutations within LMNA, encoding A-type nuclear lamins, are associated with multiple tissue-specific diseases, including Emery-Dreifuss (EDMD2/3) and Limb-Girdle muscular dystrophy (LGMD1B). X-linked EDMD results from mutations in emerin, a lamin A-associated protein. The mechanisms through which these mutations cause muscular dystrophy are not understood. Here we show that most, but not all, cultured muscle cells from lamin A/C knockout mice exhibit impaired differentiation kinetics and reduced differentiation potential. Similarly, normal muscle cells that have been RNA interference (RNAi) down-regulated for either A-type lamins or emerin have impaired differentiation potentials. Replicative myoblasts lacking A-type lamins or emerin also have decreased levels of proteins important for muscle differentiation including pRB, MyoD, desmin, and M-cadherin; up-regulated Myf5; but no changes in Pax3, Pax7, MEF2C, MEF2D, c-met, and beta-catenin. To determine whether impaired myogenesis is linked to reduced MyoD or desmin levels, these proteins were individually expressed in Lmna(-/-) myoblasts that were then induced to undergo myogenesis. Expression of either MyoD or, more surprisingly, desmin in Lmna(-/-) myoblasts resulted in increased differentiation potential. These studies indicate roles for A-type lamins and emerin in myogenic differentiation and also suggest that these effects are at least in part due to decreased endogenous levels of other critical myoblast proteins. The delayed differentiation kinetics and decreased differentiation potential of lamin A/C-deficient and emerin-deficient myoblasts may in part underlie the dystrophic phenotypes observed in patients with EDMD.
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PMID:Lamin A/C and emerin are critical for skeletal muscle satellite cell differentiation. 1648 76

The MAML (mastermind-like) proteins are a family of three co-transcriptional regulators that are essential for Notch signaling, a pathway critical for cell fate determination. Though the functions of MAML proteins in normal development remain unresolved, their distinct tissue distributions and differential activities in cooperating with various Notch receptors suggest that they have unique roles. Here we show that mice with a targeted disruption of the Maml1 gene have severe muscular dystrophy. In vitro, Maml1-null embryonic fibroblasts failed to undergo MyoD-induced myogenic differentiation, further suggesting that Maml1 is required for muscle development. Interestingly, overexpression of MAML1 in C2C12 cells dramatically enhanced myotube formation and increased the expression of muscle-specific genes, while RNA interference (RNAi)-mediated MAML1 knockdown abrogated differentiation. Moreover, we determined that MAML1 interacts with MEF2C (myocyte enhancer factor 2C), functioning as its potent co-transcriptional regulator. Surprisingly, however, MAML1's promyogenic effects were completely blocked upon activation of Notch signaling, which was associated with recruitment of MAML1 away from MEF2C to the Notch transcriptional complex. Our study thus reveals novel and nonredundant functions for MAML1: It acts as a coactivator for MEF2C transcription and is essential for proper muscle development. Mechanistically, MAML1 appears to mediate cross-talk between Notch and MEF2 to influence myogenic differentiation.
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PMID:The Notch coactivator, MAML1, functions as a novel coactivator for MEF2C-mediated transcription and is required for normal myogenesis. 1651 Aug 69

Mutations in dysferlin cause a type of muscular dystrophy known as dysferlinopathy. Dysferlin may be involved in muscle repair and differentiation. We compared normal human skeletal muscle cultures expressing dysferlin with muscle cultures from dysferlinopathy patients. We quantified the fusion index of myoblasts as a measure of muscle development and conducted optic and electronic microscopy, immunofluorescence, Western blot, flow cytometry, and real-time PCR at different developmental stages. Short interference RNA was used to corroborate the results obtained in dysferlin-deficient cultures. A luciferase reporter assay was performed to study myogenin activity in dysferlin-deficient cultures. Myoblasts fusion was consistently delayed as compared with controls whereas the proliferation rate did not change. Electron microscopy showed that control cultured cells at 10 days were fusiform, whereas dysferlin-deficient cells were star-shaped and large. After 15 days the normal multinucleated appearance and structured myofibrils were not present in dysferlin-deficient cells. Strikingly, myogenin was not detected in myotubes from dysferlin-deficient cultures using Western blot, and mRNA analysis showed low levels (p < 0.05) compared with controls. Flow cytometry and immunofluorescence also showed reduced levels of myogenin in dysferlin-deficient cultures. When the dysferlin gene was knocked down ( approximately 80%), myogenin mRNA leveled down to approximately 70%. MyoD and desmin mRNA levels in controls and dysferlin-deficient cultures were similar. The reporter luciferase assay demonstrated a low myogenin activity in dysferlin-deficient cultures. These results point to a functional link between dysferlin and myogenin, and both proteins may share a new signaling pathway involved in differentiation of skeletal muscle in vitro.
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PMID:Absence of dysferlin alters myogenin expression and delays human muscle differentiation "in vitro". 1660 42

Here, we present the first study of a human neuromuscular disorder at transcriptional and proteomic level. Autosomal dominant facio-scapulo-humeral muscular dystrophy (FSHD) is caused by a deletion of an integral number of 3.3-kb KpnI repeats inside the telomeric region D4Z4 at the 4q35 locus. We combined a muscle-specific cDNA microarray platform with a proteomic investigation to analyse muscle biopsies of patients carrying a variable number of KpnI repeats. Unsupervised cluster analysis divides patients into three classes, according to their KpnI repeat number. Expression data reveal a transition from fast-glycolytic to slow-oxidative phenotype in FSHD muscle, which is accompanied by a deficit of proteins involved in response to oxidative stress. Besides, FSHD individuals show a disruption in the MyoD-dependent gene network suggesting a coregulation at transcriptional level during myogenesis. We also discuss the hypothesis that D4Z4 contraction may affect in trans the expression of a set of genes involved in myogenesis, as well as in the regeneration pathway of satellite cells in adult tissue. Muscular wasting could result from the inability of satellite cells to successfully differentiate into mature fibres and from the accumulation of structural damages caused by a reactive oxygen species (ROS) imbalance induced by an increased oxidative metabolism in fibres.
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PMID:Parallel protein and transcript profiles of FSHD patient muscles correlate to the D4Z4 arrangement and reveal a common impairment of slow to fast fibre differentiation and a general deregulation of MyoD-dependent genes. 1701 91

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