Basal Lamina Of Muscle Fibers Research Articles

Activity-dependent accumulation of basal lamina by cultured rat myotubes

Myoblasts from 20-day rat embryos fuse and differentiate in culture to form spontaneously active myotubes. The myotubes acquire an extracellular matrix that includes a patchy basal lamina (BL) and a layer of fibrils that runs among and above the cells. Several antibodies that bind to muscle fiber basement membrane in vivo were used to study the organization of the extracellular matrix and the effect of muscle activity on the accumulation of its components. Light and electron microscopic immunohistochemical methods showed that the composition and organization of myotube BL in vitro resemble those seen in vivo. Antibodies that bind to both synaptic and extrasynaptic muscle fiber BL in vivo stain the entire myotube BL in vitro, while antisera that bind preferentially to synaptic BL in vivo stain small patches of myotube BL, which are usually associated with regions rich in acetylcholine receptors. The effects of activity on accumulation of BL were studied by comparing control myotubes to myotubes paralyzed with tetrodotoxin or lidocaine. Immunohistochemical and 125I-antibody binding experiments with three antisera that stain the entire BL showed that paralyzed myotubes accumulate less BL than active myotubes. The effects of activity and inactivity are reversible: new BL forms if toxin is removed from cultures and BL is lost if active myotubes are paralyzed. Thus, accumulation of BL by myotubes is dependent, at least in part, on activity. In contrast, the number of patches stained by synapse-specific BL antibodies is increased in inactive cultures. Thus, immunologically distinguishable components of BL are differentially affected by activity.

Antibodies that bind specifically to synaptic sites on muscle fiber basal lamina.

Basal lamina (BL) ensheathes each skeletal muscle fiber and passes through the synaptic cleft at the neuromuscular junction. Synaptic portions of the BL are known to play important roles in the formation, function, and maintenance of the neuromuscular junction. Here we demonstrate molecular differences between synaptic and extrasynaptic BL. We obtained antisera to immunogens that might be derived from or share determinants with muscle fiber BL, and used immunohistochemical techniques to study the binding of antibodies to rat skeletal muscle. Four antisera contained antibodies that distinguished synaptic from extrasynaptic portions of the muscle fiber's surface. They were anti-anterior lens capsule, anti-acetylcholinesterase, anti-lens capsule collagen, and anti-muscle basement membrane collagen; the last two sera were selective only after antibodies binding to extrasynaptic areas had been removed by adsorption with connective tissue from endplate-free regions of muscle. Synaptic antigens revealed by each of the four sera were present on the external cell surface and persisted after removal of nerve terminal. Schwann cell, and postsynaptic plasma membrane. Thus, the antigens are contained in or connected to BL of the synaptic cleft. Details of staining patterns, differential susceptibility of antigens to proteolysis, and adsorption experiments showed that the antibodies define at least three different determinants that are present in synaptic but not extrasynaptic BL.

Reinnervation of muscle fiber basal lamina after removal of myofibers. Differentiation of regenerating axons at original synaptic sites.

Axons regenerate to reinnervate denervated skeletal muscle fibers precisely at original synaptic sites, and they differentiate into nerve terminals where they contact muscle fibers. The aim of this study was to determine the location of factors that influence the growth and differentiation of the regenerating axons. We damaged and denervated frog muscles, causing myofibers and nerve terminals to degenerate, and then irradiated the animals to prevent regeneration of myofibers. The sheath of basal lamina (BL) that surrounds each myofiber survives these treatments, and original synaptic sites on BL can be recognized by several histological criteria after nerve terminals and muscle cells have been completely removed. Axons regenerate into the region of damage within 2 wk. They contact surviving BL almost exclusively at original synaptic sites; thus, factors that guide the axon's growth are present at synaptic sites and stably maintained outside of the myofiber. Portions of axons that contact the BL acquire active zones and accumulations of synaptic vesicles; thus by morphological criteria they differentiate into nerve terminals even though their postsynaptic targets, the myofibers, are absent. Within the terminals, the synaptic organelles line up opposite periodic specializations in the myofiber's BL, demonstrating that components associated with the BL play a role in organizing the differentiation of the nerve terminal.

Protamine induced intracellular uptake of horseradish peroxidase and vacuolation in mouse skeletal muscle in vitro.

The uptake in vitro of horseradish peroxidase (HRP) in mouse skeletal muscle was examined by electron microscopy and chemical determination. In muscles exposed to an HRP solution for 60 min at +37 degrees C, HRP infiltrated the basal lamina of muscle fibres and caused an intense labelling of their sarcolemma. In addition HRP was found within the transverse tubules. Exposure to HRP for 30 min at +37 degrees C followed by HRP together with a polycationic protein (protamine) for 30 min at +37 degrees C caused an intracellular vesicular uptake of HRP. Intracellular HRP was found in numerous vesicles, membrane limited bodies and vacuoles. Protamine also induced focal autophagic vacuolation with progressive muscle fibre degeneration. An intracellular HRP uptake or muscle cell vacuolation could not be detected in the absence of protamine or when the incubation temperature was +4 degrees C. Chemical determination of HRP uptake was in general agreement with the morphological results. The uptake of HRP in the presence of protamine was stimulated at +37 degrees C and blocked at +4 degrees C. The results suggest that in skeletal muscle in vitro intracellular uptake of macromolecules occurs by endocytosis.