Gene/Protein Disease Symptom Drug Enzyme Compound
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The largest in-frame deletion in the dystrophin gene previously reported in a BMD patient encompasses exons 17 to 48, which corresponds to 46% of the coding region. Here we report a larger deletion of exons 13 to 48 in a 37 year-old BMD patient with a mild phenotype. Such deletion, which corresponds to 50% of the coding region is the largest reported so far associated with a benign clinical course. Dystrophin assessment (through immunofluorescence and Western blot) using antibodies against different regions of the dystrophin was concordant with his deletion. The observation of this patient has important implication for gene therapy trials based on minigenes, since it confirms that deletions of up to 66% of the rod domain are compatible with a mild phenotype.
Hum Mol Genet 1994 Jun
PMID:Half the dystrophin gene is apparently enough for a mild clinical course: confirmation of its potential use for gene therapy. 795 Dec 37

Two promoters in the distal half of the Duchenne Muscular Dystrophy gene drive transcription of mRNAs which have novel first exons and encode the shortened forms of dystrophin, apo-dystrophin-1 (Dp71) and apo-dystrophin-2 (Dp116). Apo-dystrophin-1 has a G + C rich promoter and is expressed in a wide range of cell types, whilst apo-dystrophin-2 is confined to peripheral nerve and brain. We have isolated and sequenced the unique 5' exon of rat apo-dystrophin-2 mRNA. Conceptual translation of this sequence indicates that apo-dystrophin-2 contains a unique 23 amino acid terminal peptide. Using specific probes derived from sequences at the 5' ends of apo-dystrophin-1 and apo-dystrophin-2 we have determined the expression of these two mRNAs during mouse embryonic development by RNA in situ hybridization. In contrast to full-length dystrophin, neither of these short dystrophin transcripts appear before organogenesis is well established. Apo-dystrophin-1 mRNA is detected in midline cells of the ventral neural tube and later, in the ependymal cells lining the ventricles of the brain. These results suggest that apo-dystrophin-1 mRNA is associated with glial cells in the CNS. Apo-dystrophin-1 transcripts are also abundant in the teeth primordia throughout their development. In contrast apo-dystrophin-2 mRNA is largely undetectable during development, although transcripts are seen in the newborn brain. Western blots of late human fetal tissue extracts confirm that apo-dystrophin-2 is most abundant in brain and analysis of RNA and protein in cultured cell lines reveal expression of apo-dystrophin-1 and apo-dystrophin-2 in glioma cells.
Hum Mol Genet 1994 Aug
PMID:Apo-dystrophin-1 and apo-dystrophin-2, products of the Duchenne muscular dystrophy locus: expression during mouse embryogenesis and in cultured cell lines. 798 7

PCR amplification has enabled a variety of studies to be performed on the murine dystrophin transcripts. Figure 7.12 displays a summary of the features of the murine dystrophin mRNA that have been described in this article. The location of the mutation in the original mdx mouse is indicated, as are the different spliced forms of the dystrophin transcript. Also shown are the location of various PCR primer binding sites that were used to deduce the alternative splicing pattern of the gene. It is likely that conventional cloning efforts aimed at identifying the variety of dystrophin spliced forms would have taken years to perform, particularly since several of the isoforms are expressed at levels significantly below the estimated 0.02% of total mRNA that dystrophin represents in skeletal muscle (Hoffman et al., 1987a, b). Amplification of dystrophin mRNA simplifies scanning methods for the identification of DNA sequence variations. Attempts to re-isolate and sequence the 14 kb cDNA to determine the mutation in separate strains of mdx mice are not likely to be time or cost effective. PCR enables these types of questions to be answered in a relatively short period of time, and similar types of analyses can be applied to human DMD tissues. Knowledge of the transcript diversity displayed by the dystrophin gene will enable the role of these separate isoforms to be addressed. Despite considerable effort by a variety of laboratories over the last five years, the precise functional role played by dystrophin remains unclear, and it can only be assumed that the separate isoforms act to modulate the functional role of dystrophin in separate tissues or in response to differing physiological states. PCR amplification of the dystrophin isoforms has enabled the variable regions of the transcript to be subcloned (Bies et al., 1992). These clones have been used to reintroduce the variable regions into full-length mini-gene expression vectors, which are currently being tested for functional activity through the generation of transgenic mdx mice. The transgenic mice can be easily identified through the PCR-ASO assays described in this article, and the reverse transcriptase PCR assays will enable a detailed analysis of the expression pattern of the introduced mini-genes. It is hoped that such analyses will further attempts to determine the feasibility of using gene therapy as a treatment for DMD/BMD.
Mol Cell Biol Hum Dis Ser 1993
PMID:PCR analysis of muscular dystrophy in mdx mice. 811 39

Utrophin and dystrophin are highly homologous proteins which are reciprocally expressed in DMD (Duchenne muscular dystrophy) muscle. The remarkable similarity of these proteins suggests that they may play a similar cellular role in some circumstances; if this were the case then utrophin may be capable of replacing dystrophin in DMD patients. In this paper we show that the genomic structure of the utrophin gene is similar to the dystrophin gene, further exemplifying the relatedness of the two genes and their gene products. We have constructed a 1.25 Mb contig of eight yeast artificial chromosome (YAC) clones covering the utrophin gene located on chromosome 6q24. Utrophin is encoded by multiple small exons spanning approximately 900 kb. The distribution of exons within the genomic DNA has similarities to that of the dystrophin gene. In contrast to dystrophin, the utrophin gene has a long 5' untranslated region composed of two exons and a cluster of unmethylated, rare-cutting restriction enzyme sites at the 5' end of the gene. Similarities between the genomic structure suggest that utrophin and dystrophin arose through an ancient duplication event involving a large region of genomic DNA.
Hum Mol Genet 1993 Nov
PMID:The utrophin and dystrophin genes share similarities in genomic structure. 828 Nov 35

Duchenne and Becker muscular dystrophies (DMD/BMD) are caused by mutations in the human dystrophin gene. About two-thirds of DMD/BMD patients exhibit gross rearrangements in the gene whereas the mutations in the remaining one third are thought to be point mutations or minor structural lesions. By means of various progressive PCR-based techniques hitherto a number of point mutations has been described that in most cases should cause premature translational termination. These data indicate a particular functional importance for the C-terminal region of dystrophin and consequently for its gene products Dp 71 and Dp 116. To screen for microheterogeneities in this gene region we applied PCR-SSCP analysis to exons 60-79 of twenty-six DMD/BMD patients without detectable deletions. The study identified seven point mutations and one intron polymorphism. Six point mutations, found in DMD patients, should cause premature translational termination. One point mutation, identified in a BMD patient, results in an amino acid exchange. Five of the DMD patients bearing a point mutation are mentally retarded suggesting that a disruption of the translational reading frame in the C-terminal region is associated with this clinical finding in DMD cases. Therefore our data raise the possibility, that Dp 71 and/or Dp 116, the C-terminal translational products of dystrophin, may be causally involved in cases of mental retardation that are associated with DMD.
Hum Mol Genet 1993 Nov
PMID:Point mutations at the carboxy terminus of the human dystrophin gene: implications for an association with mental retardation in DMD patients. 828 Nov 50

At the cellular level, the primary pathology in Duchenne muscular dystrophy (DMD) is caused by deficiency of the sarcolemmal-associated protein, dystrophin, in the striated musculature. Here we describe the somatic transfer and long-term expression of a human dystrophin minigene corresponding to a mild Becker muscular dystrophy (BMD) phenotype in skeletal muscle tissues of the dystrophin-deficient mdx mouse by direct retroviral transduction. Following a single intramuscular injection of recombinant retrovirus, sarcolemmal expression of dystrophin was observed in an average of approximately 6% of myofibres in treated tibialis anterior muscles and was associated with activated reappearance of at least one component (43kD) of the dystrophin-glycoprotein membrane complex (DGC). Furthermore, expression of recombinant dystrophin was observed in muscle tissues up to 9 months after treatment and a significant enhancement of retrovirus-mediated myofibre transduction was obtained in mdx muscle undergoing experimentally-induced regeneration. The results clearly demonstrate that retroviral transduction of activated satellite cells in regenerating skeletal muscle is a feasible route for direct and stable dystrophin gene transfer into muscle tissues in vivo.
Hum Mol Genet 1993 Jun
PMID:Direct retroviral-mediated transfer of a dystrophin minigene into mdx mouse muscle in vivo. 835 91

A 32 kilobase-pair fragment of intron 7 of the human dystrophin gene has been sequenced and analysed for the presence of repetitive elements and open reading frames. Two transposon-like human elements (THE-1 sequences), and three intervening, and related, long terminal repeat elements, together with three Alu sequences and a LINE sequence have been identified. These represent an unexpected clustering of highly-repetitive sequences within this single segment of intron DNA. Amplification of a region of chimpanzee genomic DNA by the polymerase chain reaction has provided evidence that at least one of the THE-1 sequences is present in the same position in the chimpanzee genome and the high homology between the human and chimpanzee sequences indicates that this element was fixed within the ancestral genome before the divergence of the two species. The possible role of repetitive, transposon-like sequences in natural mutagenesis of the dystrophin gene is discussed.
J Mol Biol 1993 Jul 05
PMID:A cluster of transposon-like repetitive sequences in intron 7 of the human dystrophin gene. 839 88

Two thirds of the Duchenne muscular dystrophy population have either gene deletions or duplications. The nondeletion/duplication cases are most likely the result of point mutations or small deletions and duplications that cannot be easily identified by current strategies. The major obstacle in identifying small mutations is due to the large size of the dystrophin gene. We selectively screened 5 DMD exons containing CpG dinucleotides in 110 DMD patients without detectable deletions or duplications. Nonsenses mutations are frequently due to a C- to -T transition within a CG dinucleotide pair. To screen for the nonsense mutations, we used the heteroduplex method. Utilizing this approach, we identified 2 different nonsense mutations and a single base deletion all occurring in exon 19. This is the first report of a clustering of small mutations in the dystrophin gene.
Hum Mol Genet 1993 Mar
PMID:Identification of two point mutations and a one base deletion in exon 19 of the dystrophin gene by heteroduplex formation. 849 22

The molecular defect in Duchenne muscular dystrophy is well established as being due to mutations at Xp21 which disrupt the normal synthesis of the 14kb dystrophin mRNA. More recently, several groups have identified a 4.8kb transcript from this locus which shares exons with the carboxy-terminal region of the dystrophin gene. In this paper we present evidence for an additional 2.2kb mRNA transcript. The 5' untranslated region and first 7 amino acids are identical to that published for the 4.8kb transcript. The position of the translational stop codon and 3' untranslated region is similar to that previously described as the truncated fetal dystrophin isoform. This 2.2kb mRNA has a similar tissue distribution to that described for the 4.8kb mRNA but unlike the other transcripts from the DMD locus, the 2.2kb mRNA is expressed in early development. The relevance of this transcript in the clinical expression of muscular dystrophy and developmental delay is discussed.
Hum Mol Genet 1993 May
PMID:Apo-dystrophin-3: a 2.2kb transcript from the DMD locus encoding the dystrophin glycoprotein binding site. 851 89

Microsatellites of the dystrophin gene have been used extensively in the genetic analysis of Duchenne and Becker muscular dystrophy families. The microsatellites that have been reported to date are clustered within disparate regions of the dystrophin gene, specifically at the 5'-end and in the central rod-domain. YACs encompassing the gene were screened for further microsatellites to improve the density of available genetic markers. Four microsatellites were localized to defined regions of the dystrophin gene by the analysis of patient DNA samples, somatic cell hybrids and YACs. In addition, varying combinations of microsatellite loci were amplified in multiplex PCRs, which complement those loci that have been studied to date.
Mol Cell Probes 1995 Oct
PMID:Molecular characterization of further dystrophin gene microsatellites. 856 78


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