Neurons induce contractions in myotubes containing only muscular dysgenic nuclei

Muscle fibers from dysgenic mouse in vivo lack a surface component of peripheral couplings

We have studied the structure of developing normal and dysgenic (mdg/mdg) mouse muscle fibers in vivo, with special attention to the components of the junctions between the sarcoplasmic reticulum and either the surface membrane or the transverse tubules. Triads and dyads are rare in dysgenic muscle fibers, but have apparently normal disposition of feet and calsequestrin. Peripheral couplings in normal developing muscle fibers have junctional tetrads in their surface membrane in association with the junctional feet. Muscle fibers in dysgenic mice lack junctional tetrads. This provides indirect evidence for the identification of the components of junctional tetrads with dihydropyridine receptors, which are known to be absent in dysgenic muscle fibers.

Invited review: myoblast transfer: a possible therapy for inherited myopathies?

A potential therapeutic strategy for genetic diseases is to alter the genetic constitution of the affected tissues by means of grafts of normal precursor or stem cells. Over several years, evidence has accumulated to suggest that primary diseases of skeletal muscle, such as Duchenne muscular dystrophy, may be susceptible to this approach. This review makes a critical examination of such background evidence, and also of more recent data directly addressing the concept of therapy by means of grafts of normal myogenic cells. It is concluded that the data establish the principle that such grafts effect an alteration of the genetic constitution and phenotype of skeletal muscle and, therefore, might be used to alleviate recessively inherited myopathies. Several obstacles to the therapeutic application of this method to human disease are also identified; these seem to be problems of a technical nature rather than of basic principle, and none appears insuperable.

Appearance of the slow Ca conductance in myotubes from mutant mice with "muscular dysgenesis"

Voltage gated Ca conductance in skeletal muscle cells from mice with muscular dysgenesis (mdg/mdg) and from normal mice was studied using the whole cell recording technique. The physiological properties of the myotubes from the mutant mice (uncoupling of excitation-contraction, deficiency in the voltage gated slow Ca conductance) were changed to normal when the mdg/mdg myotubes were cocultured with spinal cord cells from normal mice. Spinal cord cells from mutant mice failed to induce normal muscle activity in the mutant myotubes. In aged mutant myotubes cultured without spinal cord cells, the slow Ca conductance sometimes developed, although with smaller amplitude. The number of mdg/mdg myotubes with partial development of the slow Ca conductance increased with the age of the culture. E-C coupling was never established in aged mutant myotubes. The phenotypic reversion did not require functional synaptic transmission since it was also obtained when neuromuscular transmission was chronically blocked with alpha-bungarotoxin (4-40 micrograms/ml).

Tissue culture studies of muscle disorders: Part 2. Biochemical studies, nerve-muscle culture, metabolic myopathies, and animal models

This review continues with studies of protein, lipid, and purine metabolism of Duchenne muscular dystrophy (DMD) cells in vitro and of muscle cells in combined culture with nerve cells. In vitro studies of human metabolic myopathies are tabulated. Results using the hamster, chicken, and mouse (dy25, dy, mdg, and mdx) myopathies are discussed. Interesting findings include suggestions of altered collagen synthesis by DMD cells. Analysis of cell proteins by two-dimensional gel electrophoresis and the use of combined nerve-muscle cultures remain important areas of development. It is disappointing that so few attempts have been made to repeat significant findings in this field, and when a number of laboratories have examined the same phenomenon, the results are often contradictory. It remains to be shown how these various abnormalities found in cells in vitro are related to each other and to those pathologic features of diseased muscle observed in vivo.

Disease expression in +-/+- ----mdg/mdg mouse chimeras: evidence for an extramuscular component in the pathogenesis of both dysgenic abnormal diaphragm innervation and skeletal muscle 16 S acetylcholinesterase deficiency

Homozygous mdg/mdg mice die at birth and express a syndrome of abnormalities, the most striking of which is a gross failure of skeletal muscle development. Recently, additional abnormalities in the development of nerve-muscle relationships have been recognized; in particular, on muscle fibers within the diaphragm, motor end plates are inappropriately dispersed and, in all muscles, there is a paucity of the 16 S form of acetylcholinesterase (AChE). These abnormalities could result entirely as secondary consequences of the primary muscle defect or from expression of the mdg defect in additional cell types, e.g., motor neurons. To determine if the muscle genotype alone is responsible for these defects in dysgenic mice, chimeras composed of both dysgenic and normal cells have been investigated. Different glucosephosphate isomerase variants existed in the mdg/mdg and normal cells comprising these chimeras and the mutant, normal, or mosaic genotypes of chimera diaphragm and skeletal muscle was estimated by measuring the relative proportions of each isozyme. In two chimeras, the diaphragm innervation pattern was revealed by AChE cytochemistry and in both, discrete regions of abnormally dispersed and normally restricted motor end-plate zones were observed. No correlation between these patterns of innervation and the assessed genotype of the muscle fibers existing in each area was observed. The relative 16 S AChE content in the limbs of four chimeras was found to range from 2.5 to 42.0%. Here also, no correlation between 16 S AChE content and the muscle genotype was observed. The results of these investigations are not consistent with a model of mdg/mdg pathogenesis in which only the skeletal muscle is primarily affected; an extramuscular deficiency responsible for at least part of the full mdg/mdg syndrome is therefore suggested.