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)

The study addressed the question of the functional significance of various isoforms of dystrophin. Mice bearing two different alterations of the dystrophin gene, mdx and mdx-beta geo, were examined. Dystrophic mice with mdx mutation do not express full-length dystrophins, while they express short dystrophins; on the other hand, the dystrophic mice with mdx-beta geo mutation express neither full-length nor short dystrophins. We found pathological changes typical for muscular dystrophy in the diaphragm of both mutant strains. No pathological changes were found in brains of either mdx or mdx-beta geo mutants. We concluded tentatively that short isoforms of dystrophin do not contribute to the muscular dystrophy and that they do not play any role in the development and maintenance of histological structure of the brain.
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PMID:Muscular dystrophy in mice caused by two different alterations of dystrophin gene. 1137 85

The most common form of muscular dystrophy in dogs and humans is caused by mutations in the dystrophin gene. The dystrophin gene is located on the X chromosome, and, therefore, disease-causing mutations in dystrophin occur most often in males. Therefore, females with dystrophin deficiency or other forms of muscular dystrophy may be undiagnosed or misdiagnosed. Immunohistochemistry was used to analyze dystrophin and a number of other muscle proteins associated with muscular dystrophy in humans, including sarcoglycans and laminin alpha2, in muscle biopsy specimens from 5 female dogs with pathologic changes consistent with muscular dystrophy. The female dogs were presented with a variety of clinical signs including generalized weakness, muscle wasting, tremors, exercise intolerance, gait abnormalities, and limb deformity. Serum creatine kinase activity was variably high. One dog had no detectable dystrophin in the muscle; another was mosaic, with some fibers normal and others partly dystrophin-deficient. A 3rd dog had normal dystrophin but no detectable laminin alpha2. Two dogs could not be classified. This study demonstrates the occurrence of dystrophin- and laminin alpha2-associated muscular dystrophy and the difficulty in clinical diagnosis of these disorders in female dogs.
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PMID:Muscular dystrophy in female dogs. 1138 33

Aminoglycosides have previously been shown to suppress nonsense mutations, allowing translation of full-length proteins in vitro and in animal models. In the mdx mouse, where muscular dystrophy is due to a nonsense mutation in the dystrophin gene, gentamicin suppressed truncation of the protein and ameliorated the phenotype. A subset of patients with Duchenne and Becker muscular dystrophy similarly possess a nonsense mutation, causing premature termination of dystrophin translation. Four such patients, with various stop codon sequences, were treated once daily with intravenous gentamicin at 7.5 mg/kg/day for 2 weeks. No ototoxicity or nephrotoxicity was detected. Full-length dystrophin was not detected in pre- and post-treatment muscle biopsies.
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PMID:Gentamicin treatment of Duchenne and Becker muscular dystrophy due to nonsense mutations. 1140 18

Dilated cardiomyopathy is one of the leading causes of heart failure and a primary cause for heart transplantation in patients below the age of 40 years. Despite major advances in diagnostic procedures such as examination of myocardial biopsies, the etiology remains unknown in many patients. Chronic inflammation or myocarditis and chronic alcohol abuse are considered two main etiologic factors in dilated cardiomyopathy. A third causal factor, namely genetic transmission of the disease, is at least as common as myocardial inflammation or toxic damage. Several prospective studies of relatives of patients with dilated cardiomyopathy proved that about 25-30% of all cases are of familial etiology. The most common mode of inheritance is autosomal dominant. Less frequently is the disease inherited as an X-chromosomal trait. Autosomal recessive and mitochondrial transmission is rare. The penetrance is highly variable and age dependent. Many relatives of patients with DCM show only minor cardiac abnormalities and it is unknown whether they progress to full cardiomyopathy in later life. Examination of families has identified so far eight disease genes, namely the dystrophin, tafazzin, cardiac actin, desmin, lamin A/C, delta- sarcoglycan, cardiac beta-myosin heavy chain, and cardiac troponin T gene. Certain mutations in lamin A/C cause conduction system disease and dilated cardiomyopathy, whereas other mutations cause in addition skeletal muscle myopathy. Dystrophin mutations are the cause of the rare X-linked dilated cardiomyopathy without skeletal muscle involvement and a progressive course in young men. Other mutations in the dystrophin gene, mainly deletions, are the cause of the muscular dystrophy Becker and Duchenne which also present with dilated cardiomyopathy. Mutations of the desmin, delta-sarcoglycan, the cardiac actin and beta-myosin heavy chain as well as the troponin T gene are known to cause autosomal dominant-dilated cardiomyopathy without other abnormalities. The infantile X-linked DCM is caused by mutations of the tafazzin gene. The onset of the disease is typically within the first year of life and death occurs usually in childhood. Most patients may in addition be characterized by skeletal myopathy, short stature, neutropenia and abnormal mitochondria, also referred to as Barth syndrome. Knowledge of the DCM disease genes led to the new hypothesis that dilated cardiomyopathy is a disease of the myocardial force generation or force transmission. Many more disease loci are known but the responsible disease genes are not yet identified. Better understanding of the expression and function of disease genes may eventually result in new diagnostic and therapeutic tools in order to improve the prognosis of this severe disorder.
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PMID:[Genetics of dilated cardiomyopathy]. 1151 75

The first reported female patient with the Fukuyama type of congenital muscular dystrophy associated with a lack of C-terminal domain of dystrophin is presented. Clinically, the patient had characteristic features and magnetic resonance imaging findings of Fukuyama muscular dystrophy. Dystrophin analysis revealed a lack of the C-terminal domain but preserved N-terminal and rod domains of dystrophin in biopsied muscle. Moreover, she had reduced expression of merosin, syntrophin, and beta-dystroglycan in the skeletal muscle. Reverse transcriptase-polymerase chain reaction analysis of mRNA in the patient's muscle illustrated a complete lack of exons 71-74 of the dystrophin gene. These deletions, which remove the beta-dystroglycan and syntrophin binding site, may cause changes in the function of both beta-dystroglycan and syntrophin in human muscle.
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PMID:Fukuyama muscular dystrophy associated with lack of C-terminal domain of dystrophin. 1151 13

In muscle, dystrophin anchors a complex of proteins at the cell surface which includes alpha-dystroglycan, beta-dystroglycan, syntrophins and dystrobrevins. Mutations in the dystrophin gene lead to muscular dystrophy and mental retardation. In contrast to muscle, little is known about the localization and the molecular interactions of dystrophin and dystrophin associated proteins (DAPs) in brain. In the present study, we show that alpha-dystroglycan and dystrophin are localized to large neurones in cerebral cortex, hippocampus, cerebellum and spinal cord. Furthermore, we show that dystroglycan is a member of three distinct dystrophin-containing complexes. Two of these complexes contain syntrophin and both dystrophin and syntrophin are enriched in post-synaptic densities. These data suggest that dystrophin and DAPs may have a role in the organization of CNS synapses. Interestingly, the enrichment for syntrophin in post-synaptic densities is not affected in mice mutant for all dystrophin isoforms. Thus in the brain, unlike in muscle, the association of syntrophin with dystrophin is not crucial for the DAP complex which suggests that it may be associated with other proteins.
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PMID:Dystroglycan contributes to the formation of multiple dystrophin-like complexes in brain. 1152 Sep 3

Duchenne and Becker muscular dystrophies (D/BMD) are caused by mutations in the dystrophin gene. Two-thirds of patients have large intragenic deletions or duplications and the remaining one-third have point mutations, small deletions or insertions. Point mutations are more difficult to detect due to the enormous size (2.4 Mb) of the gene and its large transcript (14 kb). In the present study, a total of 50 DNA samples from unrelated D/BMD (38 DMD and 12 BMD) patients who did not show intragenic deletions by multiplex PCR, were analyzed for detection of point mutations. Single stranded conformation analysis and heteroduplex analysis observed electrophoretic mobility shifts in one (BMD) and two (DMD and BMD) patients, respectively. The mobility shift and heteroduplexes were observed in exon 17 in all of the three patients. Sequencing of the amplified PCR products revealed a nucleotide change (-37 g to t) in the intronic region in two of the patients while a C2268T substitution in the exonic region in one. Mutation database search for D/BMD mutations showed the nucleotide substitution in the exonic region as a novel change in the human dystrophin gene, which was not reported earlier. It resulted in an amino acid transition from threonine to methionine in the 687th position of the dystrophin protein. This novel substitution has been included in the mutation database of Leiden muscular dystrophy pages (http://www.dmd.nl) in the rare polymorphism/mutation category. The substituted nucleotide segregated with the disease phenotype in the family suggesting that it can be directly used for carrier detection and prenatal diagnosis without identification of disease causing mutation.
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PMID:Point mutation and polymorphism in Duchenne/Becker muscular dystrophy (D/BMD) patients. 1179 88

Complex diagnosis of muscular dystrophies including clinical, bioptical and molecular genetic approaches has been provided in a limited extent in this country. Our group of neurologists, pathologists and geneticists has examined approximately 240 patients suspected of having muscular dystrophies, mostly coming from Southern and Northern Moravia. The patients were sent to the examination most often from departments of neurology and clinical genetics, and less frequently from departments of internal medicine. According to the final diagnosis, the patients were divided into groups: with dystrophinopathies and carriers of dystrophinopathies (DMD/BMD), merosin deficient form of congenital muscular dystrophy, and Emery-Dreifuss muscular dystrophy including the carriers of this disease. Some relatives of patients with dystrophinopathies were also examined using the methods of segregation analysis. High proportion of the DMD/BMD patients can be detected by the methods of molecular genetics. Analysis of mRNA using RT PCR and PTT enables the detection of deletions, duplications, and point mutations in dystrophin gene and encompasses a larger diagnostic scope in comparison with examinations of DNA level by the multiplex PCR method from the peripheral blood which enables only deletion detections. Immunophenotyping of the dystrophin protein plays an important role especially using antibodies against carboxyterminal (DYS2) and rod domain (DYS1) of dystrophin. Deficient sarcolemmal expression of DYS2 and DYS1 reveals unambiguously a pathological dystrophin. On the other hand, less pronounced deficiencies in dystrophin expression in BMD patients and DMD/BMD carriers may not always be detected in muscle biopsies. In this case, it is necessary to supplement the examination by Western blotting and genotype analysis. The examination of patients with clinically diagnosed muscular dystrophy should start with a muscle biopsy which enables the estimation of presence and degree of structural changes. Application of antibodies against the components of DGC and emerin may reveal a deficiency in expression of these proteins. Immunohistochemical examination completed by Western blotting leads to the subsequent molecular genetic analysis of DNA or mRNA. Secondary deficiencies in expression of other DGC proteins are often revealed in muscle biopsies of dystrophinopathies and this fact must be taken into account in the evaluation of immunohistochemical findings. There is a possibility of replacement of invasive muscle biopsy by skin biopsy or buccal mucosal smears in cases of merosin and emerin deficiencies. Commercially available antibodies against merosin, emerin, calpain and sarcoglycans enable extensive identification and detailed classification of muscular dystrophies. Screening of the patients based on the application of methods described and discussed in this report is the task of the forthcoming period.
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PMID:[Muscular dystrophies detected by immunophenotyping and genotype analysis (mRNA and DNA)]. 1181 30

Rhabdomyolysis is one of the perioperative complications in patients with Duchenne's muscular dystrophy (DMD). It has been suggested that sevoflurane can be used safely for anesthesia in patients with DMD. In this report, we describe a case with DMD who received anesthesia with sevoflurane, in which rhabdomyolysis developed postoperatively. A 6-year-old boy diagnosed as DMD was scheduled for tonsillectomy under general anesthesia. Preoperative laboratory examination revealed a high level of creatine kinase (CK) (16,000-32,000 IU.l-1). An abnormality of the dystrophin gene was detected by DNA analysis. Anesthesia was induced with sevoflurane without muscle relaxant, and maintained with sevoflurane in nitrous oxide and oxygen under controlled ventilation. The course of anesthesia was uneventful and the patient recovered smoothly. Three hours postoperatively, dark red urine with a high concentration of myoglobin (1,390,000 ng.ml-1) was recognized with a high level of CK (63,500 IU.l-1). Body temperature was 37.6 degrees C, and electrocardiogram and serum potassium were within normal ranges. After the diuresis with mannitol and furosemide, the urine became clear. On the 4th postoperative day, he was discharged without any complication. This case suggested that rhabdomyolysis can develop after sevoflurane anesthesia in patients with DMD.
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PMID:[Sevoflurane can induce rhabdomyolysis in Duchenne's muscular dystrophy]. 1188 91

Point mutations in the dystrophin gene cause dystrophin deficiency and muscular dystrophy in the mdx mouse and a subset of patients with Duchenne muscular dystrophy. As an approach to gene therapy for muscular dystrophies due to point mutations, we have studied the ability of RNA-DNA chimeric oligonucleotides (chimeraplasts) to induce repair of the dystrophin gene in mdx mice. We have previously demonstrated that targeting chimeraplasts can repair the exon 23 point mutation in differentiated myofibers in vivo after intramuscular injection. For long-term benefit to patients with muscular dystrophy, any gene therapy technology must target not only differentiated myofibers but also undifferentiated muscle precursor cells that are involved in ongoing muscle repair. The focus of the current studies was to test whether chimeraplasts could repair the dystrophin mutation in mdx muscle precursor cells. Initial studies were done by transfecting a targeting chimeraplast into mdx myoblasts in vitro. Gene repair was demonstrated at the DNA, RNA, and protein levels in these cells, whereas treatment of the cells with a control chimeraplast resulted in no gene correction. After differentiation of mdx cells that had been treated with a targeting chimeraplast, immunoblot analysis demonstrated full-length dystrophin expression. By quantitative analysis of independent cultures, the amount of dystrophin expressed ranged from 2 to 15% of that expressed in wild-type cells, providing a measure of the efficacy of gene conversion in vitro. To extend the assessment to muscle precursor cells in vivo, we injected targeting and control chimeraplasts into muscles of mdx mice. When muscle precursor cells were subsequently derived from muscles injected with a targeting chimeraplast, we found that gene repair had occurred in these cells as well. These results, taken together, further demonstrate that chimeraplast-mediated gene repair may be effective as an approach to gene therapy for muscular dystrophies due to point mutations.
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PMID:Dystrophin gene repair in mdx muscle precursor cells in vitro and in vivo mediated by RNA-DNA chimeric oligonucleotides. 1193 70

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