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Duchenne and the less severe Becker form of muscular dystrophy (DMD,BMD) result from genetic deficiency in the level and/or activity of the protein dystrophin. The recent availability of cDNA based minigenes encoding recombinant dystrophin polypeptides has raised the possibility of somatic gene transfer as a therapeutic approach to treat dystrophin deficiency. In this respect, the mdx mouse provides a useful model of DMD exhibiting features characteristic of both the early myopathic and later fibrotic phases of the human disease. Using a mutated human cDNA, compatible in size with virus-based somatic gene transfer vectors, the pathophysiological consequences of restoring dystrophin expression have been examined in transgenic mdx mice. Transgene expression was correlated with a marked reduction of the skeletal myofibre necrosis and regeneration which is a major feature of the dystrophin-deficient phenotype in young mdx mice. The cDNA construct which is based on a very mild BMD phenotype thus encodes a highly functional dystrophin molecule whose reduced size renders it an attractive candidate for development as a therapeutic gene transfer reagent.
Hum Mol Genet 1992 Apr
PMID:Human dystrophin expression corrects the myopathic phenotype in transgenic mdx mice. 130 Nov 34

The 14kb dystrophin transcript from the Duchenne muscular dystrophy (DMD) locus, which encodes a 427kDa protein, is differentially spliced at the amino terminal end giving rise to alternative transcripts expressed in muscle and brain. Here we present evidence for a 4.8kb transcript from the DMD locus which is ubiquitously expressed but is particularly abundant in Schwannoma cells where dystrophin could not be detected. The hybridisation of Western blots with dystrophin antibodies also identifies a protein of approximately 80kDa of variable abundance in different human and mdx tissues. Immunocytochemistry studies confirm the expression of this protein in nerve cells, a tissue in which full length dystrophin is not detected. Sequencing of the 5' end of a clone isolated from a rat Schwannoma cDNA library, shows that the 4.8kb transcript shares exons with the carboxy terminal end of dystrophin but the 5' untranslated region is not contained within the dystrophin transcript. We propose that the 4.8kb gene product be called apodystrophin-1 as its expression is distinct from the dystrophin 14kb mRNA but it is transcribed from the same locus.
Hum Mol Genet 1992 May
PMID:Characterization of a 4.8kb transcript from the Duchenne muscular dystrophy locus expressed in Schwannoma cells. 130 Nov 45

Cognitive impairment occurs in one-third of patients with Duchenne muscular dystrophy, a lethal X-linked, recessive disease caused by mutations in the dystrophin gene which is expressed in both brain and muscle, the two transcripts having alternative first exons. Previous reports have indicated that the 'brain-type' dystrophin transcript predominates in brain. Using in situ hybridisation with antisense oligonucleotides, expression of four distinct mRNAs in specific brain areas is demonstrated here; the 14 kb muscle-type and brain-type transcripts were found to coexist in cortical and hippocampal neurons and two new transcripts have been identified in dentate gyrus and cerebellar Purkinje neurons, respectively. The latter has a novel first exon which was isolated and sequenced from mouse and human, and which would encode a protein with a different amino-terminus from the known muscle- and brain-type isoforms. Mapping in human located this exon in a large intron between the muscle-type promoter and second exon of the dystrophin gene. This finding of four alternative transcripts regulated by different promoters in brain reveals a new complexity to dystrophin expression that may have important insights for mental retardation mechanisms.
Hum Mol Genet 1992 Oct
PMID:Expression of four alternative dystrophin transcripts in brain regions regulated by different promoters. 130 51

Both normal and pathological transcripts of tissue-specific genes may be detected by polymerase chain reaction (PCR) amplification in tissues not normally considered to express the gene product. The exploitation of constitutive basal mRNA levels ("ectopic" transcription) would be a major boon to diagnostic medicine since it promises both to simplify the analysis of complex genes and to avoid the requirement for an expressing tissue that is sometimes obtainable only by biopsy. We have demonstrated the feasibility of this novel strategy by characterizing a mutation in the X-chromosomal Duchenne (or Becker) muscular dystrophy (DMD/BMD) gene encoding dystrophin. The massive size of this gene has in the past often hindered carrier detection due to the high frequency of recombination and the high proportion of new mutations. In this study a deletion was identified in both a BMD patient and a heterozygous carrier using only a minimal volume of peripheral blood. Following specifically primed reverse transcription of lymphocyte RNA, the relevant region of the pathological cDNA was PCR-amplified. Sequence analysis indicated an in-frame deletion of exons 45 to 47.
Mol Biol Med 1990 Dec
PMID:Characterization of pathological dystrophin transcripts from the lymphocytes of a muscular dystrophy carrier. 170 53

Recent advances concerning the genetic and biochemical basis of Duchenne and Becker muscular dystrophies have resulted in a good understanding of the etiology of these common dystrophies. An important secondary consequence of the genetic and biochemical research has been the generation of gene-based and protein-based diagnostic tools which enable a 'molecular diagnosis' for patients and their families. This review summarizes our current understanding of the genetics, biochemistry, and pathophysiology of Duchenne dystrophy, and gives an overview of the molecular diagnostic tools and their applications. Recent correlations of clinical, genetic and biochemical data have indicated that dystrophinopathies can present with a wide range of neuromuscular symptoms, and that neither male sex nor proximal weakness are diagnostic prerequisites for consideration of an underlying dystrophin abnormality.
Mol Aspects Med 1991
PMID:Dystrophin and disease. 177 Aug 36

Through a process that has come to be known as reverse genetics, the gene and gene product involved in Duchenne muscular dystrophy (DMD) and Becker muscular dystrophy (BMD) have been identified. The DMD/BMD gene is over 2 million base pairs in size and over 50% of DMD/BMD patients harbor submicroscopic deletions for portions of the gene. The gene product, named dystrophin, is 400 Kd in size. Dystrophin is present in skeletal, cardiac, and smooth muscles, as well as brain. The protein is absent or altered in DMD/BMD patient muscle. The normal function of dystrophin and the reasons why its alteration results in the DMD/BMD phenotypes are presently unknown. The discoveries to date, however, provide a starting point for investigating the fundamental pathogenetic mechanisms involved in DMD/BMD.
Mol Chem Neuropathol 1989 Feb
PMID:Unraveling the mysteries of Duchenne and Becker muscular dystrophy. 266 Aug 36

The current hypothesis that the Duchenne/Becker muscular dystrophy locus encodes a single 2,000 kb gene is analyzed. The apparent encoding efficiency, the individual and total exon/intron ratios, and the heterogeneity of deletions associated with the disease, which are currently interpreted as supporting the single gene hypothesis, are also consistent with the alternative hypothesis that this locus is a portion of a complex of related gene clusters which include synthenic transcriptional units of enzymes and ligand transport proteins of one or more convergent metabolic pathways. The high recombination frequency and high rate of deletions are consistent with a locus that has recently evolved from pseudoautosomal origin. The propositions that nebulin or dystrophin is the product of the DMD locus, and that the mdx locus in the mouse is homologous to that of DMD, are critically evaluated. Several lines of evidence support the contention that developmental and tissue-specific enzymes of acyl-specific phospholipid synthesis are encoded in these clusters. Phenotypic variability not accountable for by deletion heterogeneity is postulated to arise from epistatic interactions with other loci within or outside these putative clusters. Some testable predictions of these hypotheses are suggested.
Mol Cell Biochem 1988 Jun
PMID:On the nature of the Duchenne muscular dystrophy locus: a portion of a complex of related gene clusters of recent pseudoautosomal origin? 305 Apr 49

The protein dystrophin is absent in muscles of patients with Duchenne muscular dystrophy (DMD) as well as in mdx mice. The mdx mouse diaphragm closely resembles the human DMD phenotype and should serve as an appropriate model for future studies of dystrophin gene replacement. In this regard, recombinant adenovirus (AV) holds great promise as a vector for delivering a functional dystrophin gene to muscle. However, the use of AV is hampered by the development of an immune response against transduced cells, resulting in short-lived transgene expression as well as possible adverse effects on organ function. In the present study, sensitive reporter genes were employed to determine the efficiency and functional consequences of AV-mediated gene transfer to the diaphragm in both normal and mdx adult mice. One week after direct intramuscular injection of AV into the diaphragm, the level of transgene expression was significantly increased in mdx compared with normal diaphragms. In addition, small-caliber fibers (< 500 microns2) demonstrated preferential transduction in both groups of mice. Normal diaphragms receiving AV exhibited a substantial reduction in maximal twitch and tetanic force generation, whereas no significant effect on diaphragm contractility was found in the mdx group at 1 wk after injection. At 1 mo after AV administration, however, there was a significant decrease in force production by both normal and mdx diaphragms. Immunosuppression with cyclosporine A over 1 mo did not augment the level of transgene expression, but a beneficial effect on diaphragm force-generating capacity was observed in both groups of animals. We conclude the following: (1) short-term transduction of the diaphragm is more efficient in mdx than in normal mice; (2) AV leads to reduced force production by the diaphragm, with this effect being more pronounced in normal than in mdx in the early (but not the late) postinjection period; and (3) immunosuppressive therapy with cyclosporine has a partially protective effect on muscle function after AV administration, which is apparently unrelated to sparing of transduced fibers from elimination by the host immune system. These findings have important implications for the application of AV-mediated dystrophin gene transfer to the treatment of DMD.
Am J Respir Cell Mol Biol 1995 Nov
PMID:Efficiency and functional consequences of adenovirus-mediated in vivo gene transfer to normal and dystrophic (mdx) mouse diaphragm. 757 85

Duchenne muscular dystrophy (DMD) is a lethal X-linked recessive disorder with a high spontaneous mutation rate and no effective treatment, hence development of genetic based therapies is an important goal. We report that expression of a recombinant human minidystrophin cDNA, compatible with current viral vectors, can significantly reduce the myopathic phenotype in transgenic mdx mice, even when expressed at only 20-30% of endogenous dystrophin levels at the sarcolemma. To the extent that data obtained in mouse studies are applicable to DMD, the virtual elimination of morphological and biochemical abnormalities in the mdx mouse supports the use of this cDNA in somatic gene therapy protocols for DMD.
Hum Mol Genet 1995 Aug
PMID:Expression of human full-length and minidystrophin in transgenic mdx mice: implications for gene therapy of Duchenne muscular dystrophy. 758 60

Duchenne and Becker muscular dystrophy are caused by defects in the dystrophin gene, and are candidates for treatment by gene therapy. We have shown previously that overexpression of a full-length dystrophin cDNA prevents the development of dystrophic symptoms in mdx mice. We show here that this functional correction can be achieved by expressing the full-length muscle isoform at a lower level than is present in control animals. Gene therapy for DMD may necessitate the use of truncated dystrophin mini-genes to accommodate the limited cloning capacity of current-generation viral delivery vectors. We have constructed both murine and human mini-genes deleted for exons 17-48, and have demonstrated that expression of either mini-gene can almost completely prevent the development of dystrophic symptoms in transgenic mdx mice. These results suggest that viral-mediated expression of moderate levels of a truncated dystrophin could be an effective treatment for DMD.
Hum Mol Genet 1995 Aug
PMID:Expression of full-length and truncated dystrophin mini-genes in transgenic mdx mice. 758 61


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