Abstract
Activation of the hepatocyte growth factor/Met receptor is involved in muscle regeneration, through promotion of proliferation and inhibition of differentiation in myogenic stem cells (MSCs). We previously described that the specific expression of an oncogenic version of the Met receptor (Tpr–Met) in terminally-differentiated skeletal muscle causes muscle wasting in vivo. Here, we induced Tpr–Met in differentiated myotube cultures derived from the transgenic mouse. These cultures showed a reduced protein level of myosin heavy chain (MyHC), increased phosphorylation of Erk1,2 MAPK, the formation of giant sacs of myonuclei and the collapse of elongated myotubes. Treatment of the cultures with an inhibitor of the MAPK kinase pathway or with an inhibitor of the proteasome increased the expression levels of MyHC. In addition, the inhibition of the MAPK kinase pathway prevented the formation of myosacs and myotube collapse. Finally, we showed that induction of Tpr–Met in primary myotubes was unable to produce endoreplication in their nuclei. In conclusion, our data indicate that multinucleated, fused myotubes may be forced to disassemble their contractile apparatus by the Tpr–Met oncogenic factor, but they resist the stimulus toward the reactivation of the cell cycle.
Highlights
Skeletal muscle regeneration relies on proliferation, differentiation and self-renewal of myogenic stem cells (MSCs)
Terminal differentiation of newly-formed myotubes requires the irreversible withdrawal from the cell cycle, coupled to the upregulation of muscle-specific genes [1]
We investigated whether forced hyperactivation of Met signaling in differentiated skeletal muscle could induce the reversal of the differentiation and re-entry of myotubes into cell cycle
Summary
Skeletal muscle regeneration relies on proliferation, differentiation and self-renewal of myogenic stem cells (MSCs). MSCs exit the cell cycle, start terminal differentiation through upregulation of muscle-specific genes, such as myosin heavy chain (MyHC), and fuse with each other and with adjacent fibers to form multinucleated myotubes [1]. Release of HGF ligand from injured muscle activates the Met receptor on MSCs, induces their activation and increases their proliferation and migration to the site of injury. HGF is one of the factors capable of inducing the alert state of MSCs after injury. Some activated MSCs can reenter mitotic quiescence and maintain the so-called self-renewed myoblast population required to fuel the muscle regeneration process. HGF seems to have double and opposite effects on MSCs
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