Although the mechanisms controlling skeletal muscle homeostasis have been identified, there is a lack of knowledge of the integrated dynamic processes occurring during myogenesis and their regulation. Here, metabolism, autophagy and differentiation were concomitantly analyzed in mouse muscle satellite cell (MSC)-derived myoblasts and their cross-talk addressed by drug and genetic manipulation. We show that increased mitochondrial biogenesis and activation of mammalian target of rapamycin complex 1 inactivation-independent basal autophagy characterize the conversion of myoblasts into myotubes. Notably, inhibition of autophagic flux halts cell fusion in the latest stages of differentiation and, conversely, when the fusion step of myocytes is impaired the biogenesis of autophagosomes is also impaired. By using myoblasts derived from p53 null mice, we show that in the absence of p53 glycolysis prevails and mitochondrial biogenesis is strongly impaired. P53 null myoblasts show defective terminal differentiation and attenuated basal autophagy when switched into differentiating culture conditions. In conclusion, we demonstrate that basal autophagy contributes to a correct execution of myogenesis and that physiological p53 activity is required for muscle homeostasis by regulating metabolism and by affecting autophagy and differentiation.
In human neuroblastoma SH-SY5Y cells, hydrogen peroxide (H(2)O(2), 200μM) rapidly (< 5 min) induced autophagy, as shown by processing and vacuolar relocation of light chain 3(LC3). Accumulation of autophagosome peaked at 30 min of H(2)O(2) exposure. The continuous presence of H(2)O(2) eventually (at > 60 min) caused autophagy-dependent annexin V-positive cell death. However, the cells exposed to H(2)O(2) for 30 min and then cultivated in fresh medium could recover and grow, despite ongoing autophagy. H(2)O(2) rapidly (5 min) triggered the formation of dichlorofluorescein-sensitive HO(·)-free radicals within mitochondria, whereas the mitochondria-associated oxidoradicals revealed by MitoSox (O(2)(·-)) became apparent after 30 min of exposure to H(2)O(2). 3-Methyladenine inhibited autophagy and cell death, but not the generation of HO(·). Genetic silencing of beclin-1 prevented bax- and annexin V-positive cell death induced by H(2)O(2), confirming the involvement of canonical autophagy in peroxide toxicity. The lysosomotropic iron chelator deferoxamine (DFO) prevented the mitochondrial generation of both HO(.) and O(2)(·-) and suppressed the induction of autophagy and of cell death by H(2)O(2). Upon exposure to H(2)O(2), Akt was intensely phosphorylated in the first 30 min, concurrently with mammalian target of rapamycin inactivation and autophagy, and it was dephosphorylated at 2 h, when > 50% of the cells were dead. DFO did not impede Akt phosphorylation, which therefore was independent of reactive oxygen species (ROS) generation but inhibited Akt dephosphorylation. In conclusion, exogenous H(2)O(2) triggers two parallel independent pathways, one leading to autophagy and autophagy-dependent apoptosis, the other to transient Akt phosphorylation, and both are inhibited by DFO. The present work establishes HO(·) as the autophagy-inducing ROS and highlights the need for free lysosomal iron for its production within mitochondria in response to hydrogen peroxide.
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