Duchenne muscular dystrophy (DMD) is a fatal X-linked recessive disorder of muscle in children. The DMD gene product, "dystrophin", is absent from DMD, while the allelic disease, Becker muscular dystrophy (BMD), exhibits dystrophin of abnormal size and/or quantity. But we are still uncertain about the scenario that internally deleted (or duplicated) dystrophin in BMD possesses its carboxy (C)-terminal region, and severely truncated dystrophin in DMD does not. Here we use a new monoclonal antibody directed against an peptide in the C-terminal end of the dystrophin molecule to show that the C-terminus is preserved in 30 BMD and 24 control skeletal muscles but not in 21 DMD specimens. This result, taken together with data on deletions of the dystrophin gene, emphasizes both the diagnostic and biological importance of the C-terminal domain which is required for proper function and stability of dystrophin, and substantiates the validity of the reading frame hypothesis for DMD versus BMD deletions on a biochemical level.

We examined normal and dystrophic human myotubes in cell culture for expression of dystrophin, the protein product of the Duchenne muscular dystrophy locus. Dystrophin levels in developing myotubes detected by Western blotting increased after 24 hours and reached maximum levels after 10 days in fusion medium. We did not detect dystrophin in myotubes cultured from Duchenne myoblasts (7 cases). Myotubes from a Becker muscular dystrophy patient's biopsy produced a lower molecular weight (approximately 408 kd) dystrophin, which was the same size in a whole muscle preparation from the same biopsy. This 408-kd dystrophin was the expected size for this Becker patient whose DNA was deleted for exons 45-48 of the Duchenne gene. This cell culture system will allow a detailed analysis of the effects of potential pharmacologic agents on steady-state dystrophin levels.

We describe oligonucleotide primer sequences that can be used to amplify eight exons plus the muscle promoter of the dystrophin gene in a single multiplex polymerase chain reaction (PCR). When used in conjunction with an existing primer set, these two multiplex reactions detect about 98% of deletions in patients with Duchenne or Becker muscular dystrophy (DMD, BMD). Furthermore, these primers amplify most of the exons in the deletion prone "hot spot" region around exons 44 to 53, allowing determination of deletion endpoints and prediction of mutational effects on the translational reading frame. Thus, use of these PCR-based assays will allow deletion detection and prenatal diagnosis for most DMD/BMD patients in a fraction of the time required for Southern blot analysis.

We describe a patient with a duplication of more than 400,000 bp of the dystrophin gene. The duplication is completely contained within the gene, and the duplicated exons are predicted to be "in frame" with the rest of the gene. Dystrophin protein is detected in the patient's muscle as a single species of approximately 600 kDa (normal, approximately 400 kDa), indicating that the resulting mutated gene codes for a translatable mRNA of over 100 exons (normal, approximately 70 exons). The patient's mother carries the duplicated gene as determined by both DNA and protein analysis. The described duplication of the dystrophin gene is by far the largest characterized to date. This observation is of significant biologic interest in that, despite the gross alteration of the gene and the encoded protein, the patient has a relatively mild clinical progression compatible with a diagnosis of Becker muscular dystrophy.

The highly restricted host range of JC virus (JCV) has made it difficult to study the biology of this common human papovavirus. To increase our understanding of the tissue specificity of this virus, we have examined the expression of the T antigen (T-Ag) in primary and established cell lines from various tissues of transgenic mice containing the JCV early region. In contrast to earlier results from a simian virus 40-containing transgenic mouse, there was no T-Ag expression in mesenchymal fibroblasts derived from two lines of JCV-transgenic mice. Instead, we isolated T-Ag-positive (T-Ag+) cells that had characteristics consistent with a neural crest origin. Furthermore, primary brain cultures contained many T-Ag+ astrocytes, but no expression was detected in macrophages, epithelial cells, neuronal cells nor, surprisingly, in oligodendrocytes. Continued passage of these cultures resulted in vigorously growing glial fibrillary acidic protein-positive, T-Ag+ astrocytes. Thus, the strict tissue specificity of JCV expression was maintained, despite the fact that the viral genome pre-existed in every tissue of these transgenic mice and these constraints on expression were preserved even when cells were explanted in vitro.

About 60% of both Duchenne muscular dystrophy (DMD) and Becker muscular dystrophy (BMD) is due to deletions of the dystrophin gene. For cases with a deletion mutation, the "reading frame" hypothesis predicts that BMD patients produce a semifunctional, internally deleted dystrophin protein, whereas DMD patients produce a severely truncated protein that would be unstable. To test the validity of this theory, we analyzed 258 independent deletions at the DMD/BMD locus. The correlation between phenotype and type of deletion mutation is in agreement with the "reading frame" theory in 92% of cases and is of diagnostic and prognostic significance. The distribution and frequency of deletions spanning the entire locus suggests that many "in-frame" deletions of the dystrophin gene are not detected because the individuals bearing them are either asymptomatic or exhibit non-DMD/non-BMD clinical features.