The mdx mouse is an X-linked myopathic mutant, an animal model for human Duchenne muscular dystrophy. In both mouse and man the mutations lie within the dystrophin gene, but the phenotypic differences of the disease in the two species confer much interest on the molecular basis of the mdx mutation. The complementary DNA for mouse dystrophin has been cloned, and the sequence has been used in the polymerase chain reaction to amplify normal and mdx dystrophin transcripts in the area of the mdx mutation. Sequence analysis of the amplification products showed that the mdx mouse has a single base substitution within an exon, which causes premature termination of the polypeptide chain.
We have mapped human and mouse X chromosome‐specific genomic and cDNA probes through an interspecies Mus musculus/spretus pedigree which contains the mdx mutation. The positions of these markers relative to one another and to the mdx mutation were delineated. Using probes corresponding to segments of the human Duchenne muscular dystrophy (DMD) gene transcript, the position of a cross‐hybridizing mouse equivalent gene (mDMD) was located. In more than 200 animals mapped, three were identified which show recombination within this mDMD gene. Analysis of these three animals shows that the mDMD gene is oriented with its 5′ end centromeric and its 3′ end telomeric on the mouse X chromosome. Furthermore, their recombinational breakpoints are on either side of the mdx mutation, thus providing the first unequivocal demonstration that the mdx mutation is located within the mDMD gene and defining limits within that gene between which the mutation must lie. Within that segment the evidence indicates that there is no major deletion of an exon as detectable by Southern blot analysis in mdx animals. The mdx mouse becomes important as an animal model for the study of the expression of the DMD gene and its developmental consequences, for transgenic and other corrective manipulations.
Phosphorylase kinase is a glycogenolytic enzyme in several animal tissues. Within the last few years all four subunits of the enzyme have been cloned. The β, γ, and δ subunits are known to be autosomal. We have mapped the α subunit of phosphorylase kinase, recently cloned by Zander et al. (1988), in an interspecific mouse pedigree and localized it on the X chromosome, where it maps between the X-linked zinc finger protein and phosphogly cerate kinase genes, close to the latter. In man and mouse several X-linked disorders of this enzyme have been described. Although the X-linked phosphorylase kinase deficiency in mice may be caused by a mutation in the structural gene for the α subunit, mapped here, the existence of a separate regulatory locus, important in the normal expression or function of the enzyme in muscle, still remains a possibility.
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