Fine structure of the myotendinous junction of lathyritic rat muscle with special reference to connectin, a muscle elastic protein

Distribution of connectin (titin), nebulin and alpha-actinin at myotendinous junctions of chicken pectoralis muscles: an immunofluorescence and immunoelectron microscopic study

The distribution of connectin (titin), nebulin and alpha-actinin in the areas of myotendinous junctions of chicken pectoralis muscles was examined by immunocytochemical methods. Staining with antibodies against connectin (4C9, SM1 and P1200) and nebulin formed 'doublets' flanking nonterminal Z-bands; near the end of muscle fibres 'singlets' were seen within the terminal sarcomere on the side adjacent to the terminal Z-bands. The apical regions of muscle processes, where no myosin filaments are present although actin filaments exist, were reactive with anti-nebulin but not with anti-connectin. Antibodies against pectoralis (skeletal muscle type) alpha-actinin stained non terminal Z-bands and that against gizzard (smooth muscle type) the sarcolemma. Terminal Z-bands were unreactive with both of these antibodies. These findings indicate that, although terminal and nonterminal Z-bands differ in their molecular composition, connectin and nebulin filaments appear to link myosin and actin filaments, respectively, to both Z-band types.

Dystrophin and a dystrophin-related protein in intrafusal muscle fibers, and neuromuscular and myotendinous junctions

To determine whether or not and how dystrophin exists in neuromuscular junctions (NMJs) and myotendinous junctions (MTJs), we studied the mid-belly and peripheral portions of control and mdx muscles, immunohistochemically and immunoelectrophoretically, using six kinds of polyclonal antibodies, and an antibody against a dystrophin-related protein (DRP). In controls these regions and the polar region of intrafusal muscle fibers showed a rather clearer immunohistochemical dystrophin reaction than those of extrafusal muscle fibers with all antibodies used. In the muscles of mdx mice NMJs only showed a positive dystrophin reaction with the c-terminal antibody, that is, no reaction with the other five antibodies, and MTJs in mdx showed a positive reaction with the c-terminal antibody and a faint to negative reaction with the other five antibodies. In biopsied human muscles NMJs and MTJs also showed a clear reaction with all ten antibodies, i.e., six polyclonal and four monoclonal ones. Although an immunohistochemical DRP reaction was clearly seen at NMJs, only a faint or no reaction was seen on MTJs and on intrafusal muscle fibers in both mouse and human materials. Western blot analysis of control mouse muscle for dystrophin showed a clearer band for the peripheral portion, which contains many MTJs, than for the mid-belly portion. These data suggest that dystrophin really exists on MTJs, and that dystrophin and DRP exist on NMJs in mouse and human muscles.

Force transmission across muscle cell membranes

Myotendinous junctions (MTJs) display both morphological and molecular specializations for force transmission from contractile, cytoskeletal proteins to extracellular, structural proteins. MTJ membrane folding may be a mechanically important feature in junction structure in that it reduces membrane stress and situates the junction for loading primarily under shear. Force is likely to be transmitted, at least in part, by a chain of proteins including vinculin, talin, integrin, fibronectin and collagen. However, the concentration at MTJs of other structural proteins and of proteins involved in cell adhesion indicate that additional, force transmitting mechanisms also exist. Myonexin and dystrophin, muscle-specific proteins found at MTJs, may also be associated with MTJ force transmission. Periodic structures at non-MTJ membrane, called costameres, have molecular compositions similar to MTJs and may therefore also be involved in force transmission across the muscle cell membrane. Muscle tears occurring during muscle use following periods of disuse occur at or near MTJs. Disuse atrophy is associated with decreased MTJ folding and, therefore, an increase in MTJ stress during loading. This decrease in membrane folding may be the basis of increased tears in atrophied muscle.

Immunolocalization and developmental expression of dystrophin related protein in skeletal muscle

Dystrophin Related Protein is the recently identified protein product of a large autosomal transcript, showing significant similarity to dystrophin at the carboxyl terminus. Dystrophin related protein and dystrophin share a similar abundance and molecular weight, however, they differ both in their tissue distribution and expression in Duchenne/Becker muscular dystrophy. Here we define the immunolocalization of dystrophin related protein to neuromuscular and myotendinous junctions, along with peripheral nerves and vasculature of skeletal muscle. Groups of regenerating muscle fibres as well as embryonic and neonatal muscle express far greater amounts of dystrophin related protein compared with adult mdx mice. These findings may explain the paradoxical labelling seen using dystrophin antibodies in Duchenne patients and dystrophin deficient mdx mice. Finally, no abnormalities of dystrophin related protein expression were detected in three patients with Duchenne-like autosomal recessive muscular dystrophy.

Immunocytochemical study of dystrophin at the myotendinous junction

Dystrophin is the protein whose deficiency results in Duchenne muscular dystrophy. The protein has homologies with a number of cytoskeletal proteins, is localized at the muscle sarcolemma and it may provide stability to the muscle plasma membrane. Using immunocytochemical techniques, we have studied dystrophin localization at the myotendinous junction, a region of membrane complexity that requires more stability because it is subjected to great mechanical stress during the transmission of contractile force to the tendon. The results showed subsarcolemmal deposits of dystrophin at the junctional folds of the myotendon as well as membrane-associated dystrophin at extrajunctional sarcolemma. The findings suggest that dystrophin may be one of the components linking terminal actin filaments to the subplasmalemmal surface of the junctional folds of the myotendon.

The human muscle-tendon junction. A morphological study during normal growth and at maturity

The myotendon junction of human paravertebral skeletal muscle was studied by light and electron microscopy. Transverse and longitudinal sections of myotendinous regions of normal multifidus muscles were examined at three chronological stages from birth to maturity. Variations in the appearance of surface extensions at the terminal ends of muscle fibers consisted of brush-like evaginations at birth and villous-like projections in the adult. Regardless of age, they were invariably covered by a prominent external lamina, and mutually interdigitated with connective-tissue elements in the adjacent tendon. Various stages of myofibrillar assembly and sarcomere alignment were evident in the muscle fiber terminus at birth. With advancing age, splitting of terminal sarcomeres at Z bands commonly gave rise to diverging myofilament bundles that attached to electron-dense patches under the sarcolemma. In these regions, leptomeric organelles were also encountered in neonatal and adolescent myotendons. At all stages, the ends of muscle fibers possessed cytological features consistent with active synthesis and secretion. Densely-packed sarcoplasmic organelles including multiple Golgi complexes, clusters of ribosomes, mitochondria, cytoplasmic vesicles, and elements of rough- and smooth-surfaced endoplasmic reticulum were prevalent. Peripheral and centrally-placed heterochromatic nuclei with prominent nucleoli were arranged singly or in groups at the ends of muscle fibers. Satellite cell profiles and unmyelinated axons in the subjacent tendon were also identified at these sites in the adult. Fibroblasts in growing tendon were plentiful, and at all stages, possessed morphological features indicative of high metabolic and secretory activities.

Alpha-actinin is absent from the terminal segments of myofibrils and from subsarcolemmal densities in frog skeletal muscle

The presence and distribution of alpha-actinin, an actin-bundling protein, was investigated at sites where frog skeletal muscle forms junctions with tendon collagen fibers. These sites, called myotendinous junctions, are regions where myofibrils terminate and where the force of muscular contraction is transmitted from muscle cells to the substratum. An antibody manufactured to chicken smooth muscle alpha-actinin was used as a probe for alpha-actinin localization in this study. The cross-reactivity of this antibody with frog skeletal muscle alpha-actinin is demonstrated in immunoblots of one-dimensional (1D) electrophoretic separations of muscle proteins. Immunofluorescent localization of anti-alpha-actinin and electron microscopic immunolabelling confirms that the antibody binds to Z-discs with high affinity. However, in sections treated for electron microscopy with affinity-purified anti-alpha-actinin and a ferritin-conjugated, second antibody, there was no significant difference between experimental or control preparations in the number of ferritin grains overlying dense, subsarcolemmal material at junctional or non-junctional regions. Furthermore, Z-discs near myotendinous junctions displayed less binding of anti-alpha-actinin than Z-discs located several micrometers or more from the cells' termini. These findings indicate that thin filaments are not bundled by alpha-actinin near the sarcolemma. The results also provide evidence for molecular heterogeneity between Z-discs at the ends of muscle cells compared with other regions of the cell in that the terminal Z-discs of myofibrils contain very little or no alpha-actinin relative to non-terminal Z-discs.

Three-dimensional structure of the murine muscle-tendon junction

At the muscle-tendon junction of skeletal muscle fibers the structural interface between muscle cell and connective tissue is amplified by tapering, by indentation, and by surface folding. The precise form taken by the surface folds has been unknown due to a lack of studies on the three-dimensional geometry of the muscle-tendon junction. Analysis of this region by scanning electron microscopy, using conventional preparative techniques, is uninformative because the muscle surface is covered by connective tissue. Removal of the connective tissue from individual murine muscle fibers by incubation of fixed fibers in hot HCl, followed in some instances by treatment with collagenase, permits SEM analysis of the uncovered fiber ends. The muscle fiber end is characterized by surface specializations in the form of anastamotic cylindrical folds. Transmission electron micrographs of cross sections and of serial longitudinal sections of muscle fiber ends confirm that the SEM observations are correct.

Regulation of sarcomere number in skeletal muscle: a comparison of hypotheses

Sarcomere lengths from 16 locations in the muscles of mastication were measured from pigs fixed in maximum excursion (wide jaw opening) and in postural position (near occlusion). These data, plus published data on sarcomere lengths in rabbit jaw muscles, were used to evaluate conflicting hypotheses about the factors which regulate serial sarcomere number in striated muscles. According to the most successful hypothesis, sarcomere number is adjusted so as to achieve an optimum sarcomere length when the muscle is experiencing a high level of tension. Most often, this occurs at jaw positions where the muscle is electrically active.

Myotendinous junction: morphological changes and mechanical failure associated with muscle cell atrophy

The ultrastructures of the myotendinous junctions of healthy and atrophied twitch fibers from frog semitendinosus muscle are compared. The degree of plasma membrane folding at the junction of these cell types are quantified. The junctional surface area of healthy cells is increased 13.2 times by membrane folding. Calculations indicate that the junctional plasma membrane of these cells bears an average load of 2.6 X 10(4) N X m-2 during maximum isometric tension. The junctional surface area of atrophied cells is similarly increased by a factor of 6.3. The degree of junctional membrane folding does not vary with degree of cell contraction. Ultrastructural findings indicate that mechanical failure of the junction occurs just external to the junctional plasma membrane in atrophied cells. Healthy cells do not exhibit mechanical failure at the junction. These findings suggest that increased stress at the junction is associated with muscle atrophy and may cause failure at the myotendinous junction.

Skeletal muscle-smooth muscle interaction: an unusual myoelastic system

The serratus superficialis metapatagialis (SSM) of pigeons is a skeletal muscle with unusual properties. It lies between the ribs and the trailing edge of the wing, where it is attached to the skin by a system of smooth muscles having elastic tendons. Wing movements during flight induce marked changes in this muscle's length. The SSM inserts onto the deep fascia, and at its termination the skeletal muscle contains large numbers of microtubules. Many myofibrils attach to leptomeric organelles, which then attach to the terminal end of the skeletal muscle fiber. The deep fascia next connects to the dermis of the skin by bundles of smooth muscles that have elastic tendons at both ends. This system allows large movements of the muscle while preventing its fibers from overstretching. The movements and presumed forces acting at this muscle make the presence of sensory receptors such as muscle spindles unlikely. Spindles are absent in this muscle.

Studies on the structure of connectin in muscle

Enzymic hydrolysis, followed by amino acid analysis, provided no evidence for the presence of epsilon-(gamma-glutamyl) lysine or other isopeptide crosslinks in connectin. Gel elecrrophoresis in the presence of sodium dodecyl sulphate did not reveal any difference in connectin between normal and lathyritic muscle, indicating that lysyl oxidase does not initiate cross-link formation in connectin. Although connectin may be covalently crosslinked by some unknown mechanism, the available evidence suggests that the subunit of MW approximately to 900 000 is synthesised as a single polypeptide chain. In developing fetal muscle, myosin heavy chains are apparent some weeks earlier than connectin. This, together with the known susceptibility of connectin to hydrolysis, suggests that connectin exists in an exposed environment rather than as a core to the thick filament.