Ultrastructure of the developing myotendinous junction of genetic dystrophic chickens

Treatment with a triazole inhibitor of the mitochondrial permeability transition pore fully corrects the pathology of sapje zebrafish lacking dystrophin

High-throughput screening identified isoxazoles as potent but metabolically unstable inhibitors of the mitochondrial permeability transition pore (PTP). Here we have studied the effects of a metabolically stable triazole analog, TR001, which maintains the PTP inhibitory properties with an in vitro potency in the nanomolar range. We show that TR001 leads to recovery of muscle structure and function of sapje zebrafish, a severe model of Duchenne muscular dystrophy (DMD). PTP inhibition fully restores the otherwise defective respiration in vivo, allowing normal development of sapje individuals in spite of lack of dystrophin. About 80 % sapje zebrafish treated with TR001 are alive and normal at 18 days post fertilization (dpf), a point in time when not a single untreated sapje individual survives. Time to 50 % death of treated zebrafish increases from 5 to 28 dpf, a sizeable number of individuals becoming young adults in spite of the persistent lack of dystrophin expression. TR001 improves respiration of myoblasts and myotubes from DMD patients, suggesting that PTP-dependent dysfunction also occurs in the human disease and that mitochondrial therapy of DMD with PTP-inhibiting triazoles is a viable treatment option.

Caveolin-3: A Causative Process of Chicken Muscular Dystrophy

The etiology of chicken muscular dystrophy is the synthesis of aberrant WW domain containing E3 ubiquitin-protein ligase 1 (WWP1) protein made by a missense mutation of WWP1 gene. The β-dystroglycan that confers stability to sarcolemma was identified as a substrate of WWP protein, which induces the next molecular collapse. The aberrant WWP1 increases the ubiquitin ligase-mediated ubiquitination following severe degradation of sarcolemmal and cytoplasmic β-dystroglycan, and an erased β-dystroglycan in dystrophic αW fibers will lead to molecular imperfection of the dystrophin-glycoprotein complex (DGC). The DGC is a core protein of costamere that is an essential part of force transduction and protects the muscle fibers from contraction-induced damage. Caveolin-3 (Cav-3) and dystrophin bind competitively to the same site of β-dystroglycan, and excessive Cav-3 on sarcolemma will block the interaction of dystrophin with β-dystroglycan, which is another reason for the disruption of the DGC. It is known that fast-twitch glycolytic fibers are more sensitive and vulnerable to contraction-induced small tears than slow-twitch oxidative fibers under a variety of diseased conditions. Accordingly, the fast glycolytic αW fibers must be easy with rapid damage of sarcolemma corruption seen in chicken muscular dystrophy, but the slow oxidative fibers are able to escape from these damages.

Fiber Metabolism, Procollagen and Collagen Type III Immunoreactivity in Broiler Pectoralis Major Affected by Muscle Abnormalities

The present study aimed to evaluate the muscle fiber metabolism and assess the presence and distribution of both procollagen and collagen type III in pectoralis major muscles affected by white striping (WS), wooden breast (WB), and spaghetti meat (SM), as well as in those with macroscopically normal appearance (NORM). For this purpose, 20 pectoralis major muscles (five per group) were selected from the same flock of fast-growing broilers (Ross 308, males, 45-days-old, 3.0 kg live weight) and were used for histochemical (nicotinamide adenine dinucleotide tetrazolium reductase (NADH-TR) and alpha-glycerophosphate dehydrogenase (α-GPD)) and immunohistochemical (procollagen and collagen type III) analyses. When compared to NORM, we found an increased proportion (p < 0.001) of fibers positively stained to NADH-TR in myopathic muscles along with a relevant decrease (p < 0.001) in the percentage of those exhibiting a positive reaction to α-GPD. In addition, an increased proportion of fibers exhibiting a positive reaction to both stainings was observed in SM, in comparison with NORM (14.3 vs. 7.2%; p < 0.001). After reacting to NADH-TR, SM exhibited the lowest (p < 0.001) cross-sectional area (CSA) of the fibers (-12% with respect to NORM). On the other hand, after reacting to α-GPD, the CSA of WS was found to be significantly larger (+10%) in comparison with NORM (7480 vs. 6776 µm2; p < 0.05). A profound modification of the connective tissue architecture involving a different presence and distribution of procollagen and collagen type III was observed. Intriguingly, an altered metabolism and differences in the presence and distribution of procollagen and collagen type III were even observed in pectoralis major muscle classified as NORM.

The effect of immobilization on myotendinous junction: an ultrastructural, histochemical and immunohistochemical study

The effect of immobilization on the myotendinous junction of the calf muscles in the rat was studied histochemically, immunohistochemically and morphometrically with a transmission electron microscope. After 3 weeks of immobilization, the contact area between the muscle cells and tendineal collagen fibres was reduced by almost 50% in both type I (slow-twitch) and type II (fast-twitch) muscle fibres. The terminal finger-like processes of the muscle cells became shallow and cylindrical or were completely atrophied. Their basal membranes were slightly thickened. Histochemically, the most remarkable alteration in the myotendinous junction was the marked decrease in the sulphate containing glycosaminoglycans. In the basal lamina of the muscle fibres, the glycosaminoglycan and proteoglycan content was also reduced. Immunohistochemical analyses revealed that the amount of type III collagen was markedly increased on the myotendinous interface, but the amount and distribution of type I collagen was not affected by immobilization. These findings suggest that immobilization causes degenerative changes at the myotendinous junction, which, in turn, most likely decrease its tensile strength and may predispose it to rupture during activity.

Structural changes at the myogenic cell surface during the formation of myotendinous junctions

Myotendinous junctions are sites which are morphologically and molecularly specialized for force transmission between intracellular and extracellular structural proteins. In the present investigation, the formation of these specialized junctions is studied in chicken embryos from 9 days following fertilization to 1 day posthatching, using light and electron microscopy. Observations indicate that the first discernible event in myotendinous junction formation is the appearance of basement membrane at the incipient junction at 9-10 days postfertilization, concomitant with the aggregation of fibroblasts at the junctional regions of myogenic cells. Subsequently, subsarcolemmal densities appear at sites opposite basement membrane locations by 13 days postfertilization. Myofibrils insert into subsarcolemmal densities by day 15 and invaginations of the cell membrane are initiated at those insertions. Type I collagen fibers appear at the cell surface at day 17. Junctional structure at day 17 qualitatively resembles that of adult myotendinous junctions. Changes in junctional structure following day 17 are primarily increases in the amount of subsarcolemmal densities, myofibril-membrane associations, and amount of junctional membrane folding.

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.

Connective tissue metabolism in muscular dystrophy. Early amino acid changes in collagen types isolated from the gastrocnemius muscle of developing dystrophic chicken embryos

The amino acid composition of all collagen types present in the gastrocnemius muscle of dystrophic chick embryos showed an altered profile at both day 14 and day 20 in ovo when compared with the controls. The changes observed at both day 14 and day 20 in ovo suggests that there is a removal of polar side-chains in dystrophic collagen and substitution with non-polar amino acids. The amino acid composition data between day 14 and day 20 indicated: (a) a decrease in hydroxylation (hydroxyproline and hydroxylysine) with a concurrent increase in proline and lysine and a decrease in the levels of arginine; (b) the levels of glycine and alanine did not change with age; and (c) the ratios of glycine to hydroxyproline and proline to hydroxyproline changed significantly in all dystrophic collagen types between day 14 and day 20. Contrast analysis results clearly showed that the changes in amino acid composition observed in each dystrophic type of collagen between day 14 and day 20 were not due to the effect of aging but to some other factor(s). This study provides more evidence that a problem lies in the biosynthesis of collagen present in developing muscles of dystrophic chick embryos, particularly with respect to the transcription or translation of procollagen genes and/or a failure in the processing and differentiation of collagen types.

Connective tissue metabolism in muscular dystrophy. Amino acid composition of native types I, III, IV and V collagen isolated from the gastrocnemius muscle of embryonic chickens with genetic muscular dystrophy

The amino acid composition data on types I, III, IV and V collagen isolated from embryonic dystrophic skeletal muscle strongly indicate that alterations in collagen synthesis occur in intramuscular connective tissue of developing muscles in embryonic dystrophic chickens. The changes observed in the amino acid composition of dystrophic collagen were: (a) a selective removal of polar amino acids and substitution with non-polar amino acids; (b) significant decreases in basic (lysine, hydroxylysine and arginine) and hydroxylated (4-hydroxyproline and hydroxylysine) amino acids; and (c) significant increases in the amounts of glycine, proline and alanine. The amino acid substitutions suggest a genetic alteration in the collagen synthesizing process and a change in its structure. The variations in amino acid composition of collagen from dystrophic chickens could give rise to a decrease in both inter- and intramolecular cross-linking, thus decreasing the stability and functionality of newly formed collagen fibrils. The differences associated with the dystrophic collagen reported in this study are probably due to the differences in primary structure in terms of amino acid sequence rather than post-translational modifications. The structural differences noted would also lead to an alteration of the role collagen plays in regulating the differentiation of developing muscles. The changes in amino acid structure strongly suggest that the 'collagen' formed by dystrophic chickens should be considered a collagen-like protein or 'collagenoid'.

Ontogenetic aspects of changes in muscular potentials at medial gastrocnemius muscles of dystrophic mice due to prolonged stimulation

Changes in muscular potentials at medial gastrocnemius (MG) muscles induced by prolonged stimulation at 5 Hz were compared in dystrophic mice and their normal littermates at various ages. A rapid and notable reduction in the amplitude of muscular potentials at MG muscles was observed in normal mice. This was in contrast with a slight decrease or even an increase in the amplitude in dystrophic mice. The magnitude of reduction in normal mice increased with age, but in dystrophic mice where the change (a decrease or even an increase) was slight, it was similar in extent regardless of age. The slight change in dystrophic mice under the present regimen would be called a fatigue, resistant-like property, and this was discussed in conjunction with analogous properties observed in electrophysiological, histological and biochemical fields.

Differences among dystrophic, dwarf, and their crossbred mice in the time course of changes in extracellular muscle action potentials induced by 5-Hz stimulation

With urethane anesthesia, extracellular action potentials were recorded in medial gastrocnemius muscles of dystrophic, dwarf, and their crossbred mice. When repetitive stimulation was delivered at 5 Hz for a relatively long period, characteristic features were revealed. (i) Dystrophic mice showed a slight decrease or even an increase in action potentials whereas in littermate normal mice the amplitudes were rapidly and notably reduced. (ii) In both dwarf and their littermate normal mice, a considerable reduction in amplitude was observed. Slightly more depression was produced than in nondystrophic mice of a comparable age. (iii) Crossbred mice were in two classes. A rapid and notable reduction in the amplitude of muscle action potentials was observed in one class, and slight changes in the potentials were produced in another class showing dystrophy-specific symptoms.