Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0026850 (muscular dystrophy)
 5,870 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Discovery of the gene encoding the protein dystrophin delineated not only the cause of Duchenne dystrophy but also an expanding family of at least eight different dystrophin-associated muscle proteins. These include two that span the membrane (the dystroglycans), at least five within the membrane (the sarcoglycans), and a submembrane protein (utrophin). In recent years, defects in the genes for several of these proteins have been identified in several different muscular dystrophies. The spectrum of clinical deficits associated with these genetic lesions is broad, but typically it encompasses both milder proximal myopathies characteristic of limb-girdle dystrophy and more severe disorders reminiscent of Duchenne dystrophy. These discoveries will provide the basis both for improved understanding of physiology of this complex of proteins at the muscle membrane and for new strategies in the treatment of muscular dystrophy.
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PMID:Dystrophin-associated proteins and the muscular dystrophies. 904 76

The absence of dystrophin at the muscle membrane leads to Duchenne muscular dystrophy (DMD), a severe muscle-wasting disease that is inevitably fatal in early adulthood. In contrast, dystrophin-deficient mdx mice appear physically normal despite their underlying muscle pathology. We describe mice deficient for both dystrophin and the dystrophin-related protein utrophin. These mice show many signs typical of DMD in humans: they show severe progressive muscular dystrophy that results in premature death, they have ultrastructural neuromuscular and myotendinous junction abnormalities, and they aberrantly coexpress myosin heavy chain isoforms within a fiber. The data suggest that utrophin and dystrophin have complementing roles in normal functional or developmental pathways in muscle. Detailed study of these mice should provide novel insights into the pathogenesis of DMD and provide an improved model for rapid evaluation of gene therapy strategies.
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PMID:Utrophin-dystrophin-deficient mice as a model for Duchenne muscular dystrophy. 928 51

Abnormalities in the dystrophic gene product, dystrophin, have been implicated in initiating the primary membrane defect and excessive intracellular calcium accumulation (EICA), which play fundamental pathogenic roles in hereditary muscular dystrophy (HMD). Two other cytoskeletal proteins, spectrin and utrophin, bear remarkable structural and functional homologies to dystrophin. CHF-146 strain dystrophic hamsters (DH), like patients with Duchenne muscular dystrophy (DMD), die prematurely from cardiopulmonary insufficiency, focal myonecrosis, and progressive degeneration of the cardiac and skeletal muscles with EICA. Although DH present a suitable model for HMD, there are controversies concerning their dystrophin and utrophin status. Using immunocytochemistry and Western blotting, we studied dystrophin, spectrin and utrophin anomalies in the cardiac and skeletal muscles of 6-mo-old male DH. Age- and sex-matched CHF-148 strain albino normal hamsters (NH) served as controls. Sarcolemmal dystrophin staining was much weaker and interruptive in the DH. The densitometric analysis of the immunoblots revealed that dystrophin is reduced in DH by 83% in cardiac muscle (p < 0.0001), and by 50% in skeletal muscle (p < 0.0001). We conclude that sarcolemmal dystrophin distribution is markedly reduced and discontinuous in the cardiac and skeletal muscles of DH, with simultaneous upregulation of utrophin and a varied degree of spectrin labelling. This observation suggests that reduced sarcolemmal dystrophin is associated with membrane hyperpermeability, which leads to progressive muscle degeneration via EICA and segmental necrosis in DH. As in DMD, utrophin appears to play an important compensatory role in hamster dystrophinopathy.
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PMID:Reduced sarcolemmal dystrophin distribution and upregulation of utrophin in the cardiac and skeletal muscles of CHF-146 dystrophic hamsters. 937 24

Recent studies with transgenic animals have considerably advanced our knowledge of the roles of dystrophin and utrophin in both muscle and non-muscle tissues. Rigorous analyses of the roles of the various mdx mutations in mice, as well as the use of artificial transgenes in an mdx background, are beginning to define the functional importance of various regions of the dystrophin protein in normal muscle. Furthermore, recent biochemical analyses have revealed new insights into the role and organization of dystrophin at the membrane-cytoskeleton interface. Transgenic approaches have also revealed surprising and encouraging results with respect to utrophin. Against expectations, the long-awaited utrophin knockout mice have a remarkably mild phenotype with only subtle changes in neuromuscular junction architecture. On the other hand, mdx mice transgenic for a mini-utrophin construct showed rescue of the muscular dystrophy phenotype, clearly an encouraging finding with obvious therapeutic possibilities. These and other recent findings are discussed in the context of the structure and function of dystrophin and utrophin at the membrane-cytoskeleton interface.
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PMID:The membrane-cytoskeleton interface: the role of dystrophin and utrophin. 942 56

Gene therapy was considered in the treatment of life-threatening muscular dystrophy such as Duchenne muscular dystrophy (DMD). Introduction of 6.3 kb minidystrophin cDNA using adenovirus vector into skeletal muscle of mdx mice was successful, when the recombinant adenovirus was injected during the neonatal period. Recombinant adenovirus, however, evoked strong immunological reactions, when it was injected during the adult stage. The usage of mutant adenovirus, where a full length dystrophin cDNA was inserted instead of all of adenovirus protein genes, might resolve the problems that initial generations of adenovirus vector raised. Upregulation of endogenous utrophin might also give a relief in DMD patients, since introduction of truncated utrophin gene considerably improved phenotypic expression of mdx mice, when introduced as a transgene.
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PMID:[Gene therapy to muscle diseases: perspective and issues on basic research]. 943 20

The possibility of using utrophin upregulation as a treatment for dystrophin-deficient muscular dystrophies has focused attention on the question of how many of dystrophin's various functions can be performed by the closely-related protein, utrophin. In Xenopus heart, little or no dystrophin was found on Western blots but the dystrophin-related protein, utrophin, was abundant. This utrophin was shown by immunofluorescence microscopy to be associated with cardiac muscle membranes and its distribution was similar to that of dystrophin in rabbit heart. The utrophin distribution pattern in the frog heart was shared by beta-dystroglycan, a transmembrane protein responsible for localizing both dystrophin and utrophin at cell membranes. The results suggest that utrophin in Xenopus heart can perform similar functions to dystrophin in mammalian heart, lending further support to the possibility of utrophin upregulation therapy in muscular dystrophy. In skeletal muscle, however, Xenopus resembles mammals in expressing dystrophin at the sarcolemma and very little utrophin.
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PMID:Dystrophin is replaced by utrophin in frog heart; implications for muscular dystrophy. 944 6

The extraocular muscles are one of few skeletal muscles that are structurally and functionally intact in Duchenne muscular dystrophy. Little is known about the mechanisms responsible for differential sparing or targeting of muscle groups in neuromuscular disease. One hypothesis is that constitutive or adaptive properties of the unique extraocular muscle phenotype may underlie their protection in dystrophinopathy. We assessed the status of extraocular muscles in the mdx mouse model of muscular dystrophy. Mice showed mild pathology in accessory extraocular muscles, but no signs of pathology were evident in the principal extraocular muscles at any age. By immunoblotting, the extraocular muscles of mdx mice exhibited increased levels of a dystrophin analog, dystrophin-related protein or utrophin. These data suggest, but do not provide mechanistic evidence, that utrophin mediates eye muscle protection. To examine a potential causal relationship, knockout mouse models were used to determine whether eye muscle sparing could be reversed. Mice lacking expression of utrophin alone, like the dystrophin-deficient mdx mouse, showed no pathological alterations in extraocular muscle. However, mice deficient in both utrophin and dystrophin exhibited severe changes in both the accessory and principal extraocular muscles, with the eye muscles affected more adversely than other skeletal muscles. Selected extraocular muscle fiber types still remained spared, suggesting the operation of an alternative mechanism for muscle sparing in these fiber types. We propose that an endogenous upregulation of utrophin is mechanistic in protecting extraocular muscle in dystrophinopathy. Moreover, data lend support to the hypothesis that interventions designed to increase utrophin levels may ameliorate the pathology in other skeletal muscles in Duchenne muscular dystrophy.
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PMID:The sparing of extraocular muscle in dystrophinopathy is lost in mice lacking utrophin and dystrophin. 962 43

The muscular dystrophy protein, dystrophin, and the closely related protein, utrophin, are large cytoskeletal proteins which link actin microfilaments to the plasma membrane. A panel of 38 monoclonal antibodies (mAbs) has been produced against the C-terminal domains of dystrophin and utrophin. This domain interacts with both dystrobrevins, via their "leucine zipper" coiled-coil helices, and syntrophins, adaptor proteins which also interact with nitric oxide synthetase and transmembrane sodium channels. The amino acid sequences recognized by the mAbs have now been identified using a variety of epitope mapping techniques, including fragmentation by transposon mutagenesis, synthetic peptides, phage-displayed peptide libraries, and mutant dystrophins expressed in transgenic mice. In addition to defining antibody recognition sites, mapping was sufficiently precise to provide structural information, since individual amino acids accessible on the surface of the native protein were identified in many cases. In two regions of the domain, short linear epitopes were found in proline-rich sequences which may form surface loops, turns, or linkers, but these were separated by a third region which contained mainly conformational epitopes. The results are consistent with a loose and flexible structure for much of the C-terminal domain, especially around the highly conserved second leucine zipper or coiled-coil helix (CC-H2), but there is evidence for denaturation-resistant tertiary structure in the syntrophin-binding region and the first coiled-coil helix (CC-H1).
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PMID:An epitope structure for the C-terminal domain of dystrophin and utrophin. 969 8

The absence of full-length dystrophin molecules in skeletal muscle fibres results in the most severe form of muscular dystrophy, the Duchenne form (DMD). Several years ago, an autosomal homologue to dystrophin, termed utrophin, was identified. Although utrophin is expressed along the sarcolemma in developing, regenerating and DMD muscles, it nonetheless accumulates at the postsynaptic membrane of the neuromuscular junction in both normal and DMD adult muscle fibres. Due to the high degree of sequence identity between dystrophin and utrophin, it has been previously suggested that utrophin could in fact functionally compensate for the lack of dystrophin. Recent studies using transgenic mouse model systems have directly tested this hypothesis and revealed that upregulation of utrophin throughout dystrophic muscle fibres represents indeed, a viable approach for the treatment of DMD. Current studies are therefore focusing on the elucidation of the various regulatory mechanisms presiding over expression of utrophin in muscle fibres in attempts to ultimately identify small molecules which could systematically increase utrophin levels in extrasynaptic compartments of dystrophic muscle fibres. This review presents some of the recent data relevant for our understanding of the transcriptional regulatory mechanisms involved in maintaining expression of utrophin at the neuromuscular junction. In addition, the contribution of specific cues originating from motoneurons and the putative involvement of signalling events are also discussed.
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PMID:Molecular mechanisms and putative signalling events controlling utrophin expression in mammalian skeletal muscle fibres. 971 51

Duchenne muscular dystrophy (DMD) is a lethal, progressive muscle wasting disease caused by a loss of sarcolemmal bound dystrophin, which results in the death of the muscle fiber leading to the gradual depletion of skeletal muscle. The molecular structure of dystrophin is very similar to that of the related protein utrophin. Utrophin is found in all tissues and is confined to the neuromuscular and myotendinous junctions in mature muscle. Sarcolemmal localization of a truncated utrophin transgene in the dystrophin-deficient mdx mouse significantly improves the dystrophic muscle phenotype. Therefore, up-regulation of utrophin by drug therapy is a plausible therapeutic approach in the treatment of DMD. Here we demonstrate that expression of full-length utrophin in mdx mice prevents the development of muscular dystrophy. We assessed muscle morphology, fiber regeneration and mechanical properties (force development and resistance to stretch) of mdx and transgenic mdx skeletal and diaphragm muscle. The utrophin levels required in muscle are significantly less than the normal endogenous utrophin levels seen in lung and kidney, and we provide evidence that the pathology depends on the amount of utrophin expression. These results also have important implications for DMD therapies in which utrophin replacement is achieved by delivery using exogenous vectors.
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PMID:Expression of full-length utrophin prevents muscular dystrophy in mdx mice. 984 86


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