Browsing by Subject "Myoblasts"

Now showing 1 - 3 of 3
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    First ultrastructural differentiation of myoblasts of chicken embryos: appearance of the initial filaments
    (Murcia : F. Hernández, 1990) González Santander, R.; Martínez Cuadrado, G.; Martínez Alonso, F.J.; Toledo Lobo, M.V.
    A study is made of the structure and ultrastructure of myoblasts located in the myotome in chicken embryos, between stages 18 and 19, for electron microscope observation of the occurrence of the first myogenetic filamentous molecules. We suggest a hypothesis for the formation of initial filaments consisting of an initial synthesis of actin globular molecules, carried out in the centre of the myoblast, near the nucleus, with the participation of RNA and the ribosomes. These molecules accumulate peripherically in areas below the plasmatic membrane where they polymerize into actin filamentous molecules which form the initial filaments. These move towards the sharp ends of the myoblast, under the plasmatic membrane, and thence to the interior of the cytoplasm, where they are evenly distributed. This genesis of initial filaments is independent of the influence of the nervous system. We postulate the existence of a single type of myoblast, of fibrillar form, with a dark central area containing the nucleus and the cell organelles, and two sharp, light end zones which contain only the initial filaments in a very light cytoplasmic matrix.
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    The peculiar apoptotic behavior of skeletal muscle cells
    (F. Hernández y Juan F. Madrid. Universidad de Murcia. Departamento de Biología Celular e Histología, 2013) Salucci, Sara; Burattini, Sabrina; Baldassarri, Valentina
    Apoptosis plays an active role in maintaining skeletal muscle homeostasis. Its deregulation is involved in several skeletal muscle disorders such as dystrophies, myopathies, disuse and sarcopenia. The aim of this work was to study in vitro the apoptotic behavior induced by etoposide, staurosporine and hydrogen peroxide in the C2C12 skeletal muscle cell line, comparing myoblast vs myotube sensitivity, investigated by means of morphological and cytofluorimetric analyses. Myotubes appeared more resistant than myoblasts to apoptotic induction. In myoblasts treated with etoposide, nuclei with chromatin condensation were observed, in the presence of a diffuse DNA fragmentation, as shown by confocal microscopy. The latter also appeared in myotubes, where apoptotic and normal nuclei coexisted inside the same syncytium. After staurosporine treatment, myobalsts evidenced late apoptotic features and a high number of TUNEL-positive nuclei. Secondary necrosis appeared in myotubes, where myonuclei with cleaved DNA again coexisted with normal myonuclei. After H2O2 exposure, myotubes, differently from myoblasts, showed a poor sensitivity to cell death. Intriguingly, autophagic granules appeared abundantly in myotubes after each treatment. In myotubes, mitochondria were better preserved than in myoblasts since those which were damaged were probably degraded through autophagic processes. These findings demonstrate a scarce sensitivity of myotubes to apoptotic stimuli due to acquisition of an apoptosis-resistant phenotype during differentiation. The presence of nuclear-dependent “territorial” death domains in the syncytium could explain a slower death of myotubes compared to mononucleated cells. In addition, autophagy could preserve and protect muscle cell integrity against chemical stimuli, making C2C12 cells, in particular myotubes, more resistant to apoptosis induction.
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    Ultrastructure of myotendinous junctions in tendon-skeletal muscle constructs engineered in vitro
    (Murcia: F. Hernández, 2009) Kostrominova, Tatiana Y.; Calve, Sarah; Arruda, Hellen M.; Larkin, Lisa M.
    During development, the interaction between tenocytes and myotubes leads to the formation of highly specialized muscle-tendon structural interfaces: myotendinous junctions (MTJs). Structural integrity of MTJs is critical for force transmission from contracting muscle through tendon to bone. We recently developed an in vitro model of three-dimensional (3-D) skeletal muscle-tendon constructs to address mechanisms of the MTJs development. We hypothesized that engineered in vitro 3-D skeletal muscle-tendon constructs would develop MTJs ultrastructurally resembling those found during fetal development in vivo. To test this hypothesis we compared MTJs structures in vivo to those developed in 3-D skeletal muscle constructs co-cultured with engineered self-organized tendon constructs (SOT), or segments of adult (ART) or fetal rat tail (FRT) by means of electron microscopy. Our study showed that at sites of termination some of the myofibers of the engineered 3-D skeletal muscle-FRT and -SOT constructs displayed emerging finger-like sarcolemmal projections surrounded by collagen fibers. These structures resemble fetal MTJs in vivo. Muscle-ART constructs did not develop MTJs. Muscle-FRT constructs in addition to muscle and tendon also demonstrated well developed cartilage, possessing high potential for development into bone. The muscle-FRT construct model could be used for studies of developmental mechanisms involved in the establishment of interfaces among all four muscularskeletal tissues: muscle, tendon and cartilage/bone.