We have investigated whether the phenotype of myogenic clones derived from satellite cells of different muscles from the transgenic immortomouse depended on muscle type origin. Clones derived from neonatal, or 6-to 12-week-old fast and slow muscles, were analyzed for myosin and enolase isoforms as phenotypic markers. All clones derived from slow-oxidative muscles differentiated into myotubes with a preferentially slow contractile phenotype, whereas some clones derived from rapid-glycolytic or neonatal muscles expressed both fast and slow myosin isoforms. Thus, muscle origin appears to bias myosin isoform expression in myotubes. The neonatal clone (WTt) was cultivated in various medium and substrate conditions, allowing us to determine optimized conditions for their differentiation. Matrigel allowed expressions of adult myosin isoforms, and an isozymic switch from embryonic ␣-toward muscle-specific -enolase, never previously observed in vitro. These cells will be a useful model for in vitro studies of muscle fiber maturation and plasticity.
Transforming growth factor-beta1 (TGF-beta1) is known to be expressed in the environment of developing fast muscle fibres during ontogenesis. In the present study, we have examined effects of administration of either TGF-beta1 or neutralizing TGF-beta1 antibody on the induction of fast type phenotype in regenerating skeletal muscles in rats. Expressions of fast and slow myosin heavy chain (MHC) isoforms were studied using protein electrophoresis, at 3 and 6 weeks after myotoxic treatment. Muscle contractile properties were also measured in situ. The results have shown that a single injection of TGF-beta1 into the regenerating slow soleus muscle increased the expression of fast MHC-2x/d and MHC-2a and decreases that of slow MHC-1 (P<0.05). Moreover, it reduced the degree of tetanic fusion during contraction (P<0.05). Conversely, injection of neutralizing antibody against TGF-beta1 into the regenerating fast EDL muscle increased the expression of MHC-2a and MHC-1 (P<0.05). In conclusion, when the slow muscle was regenerating in the presence of an increased level of TGF-beta1, it induced a shift to a less slow MHC phenotype and contractile characteristics. Conversely, neutralization of TGF-beta1 in the regenerating fast muscle induced a shift to a less fast MHC expression. Together these results suggest that TGF-beta1 influences some aspects of fast muscle-type patterning during skeletal muscle regeneration.
Contraction and energy metabolism are functions of skeletal muscles co-regulated by still largely unknown signals. To help elucidating these interconnecting pathways, we are developing new cellular models that will allow to control the switch from a neonatal to an adult slow-oxidative or fast-glycolytic phenotype of myofibers, during in vitro differentiation. Thus, our purpose was to direct the differentiation of the newly characterized WTt clone, from a mixed towards either fast or slow phenotype, by modifying amounts of two transcription factors respectively involved in control of glycolytic and oxidative energy metabolism, namely HIF-1alpha and PPARdelta. Our data support the idea that HIF-1alpha protein stabilization would favor expression of fast phenotypic markers, accompanied or not by a decreased expression of slow markers, depending on treatment conditions. Conversely, PPARdelta over-expression appears to enhance the slow-oxidative phenotype of WTt myotubes. Furthermore, we have observed that expression of PGC-1alpha, a coregulator of PPAR, is also modified in this cell line upon conditions that stabilize HIF-1alpha protein. This observation points to the existence of a regulatory link between pathways controlled by the two transcription factors HIF-1alpha and PPARdelta. Therefore, these cells should be useful to analyze the balance between oxidative and glycolytic energy production as a function of phenotypic transitions occurring during myogenic maturation. The newly characterized murine WTt clone will be a good tool to investigate molecular mechanisms implicating HIF-1alpha and PPARdelta in the coordinated metabolic and contractile regulations involved in myogenesis.
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