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Mitochondrial dysfunction increases fatty acid β-oxidation and translates into impaired neuroblast maturation.

FEBS letters (2019-08-23)
Matteo Audano, Silvia Pedretti, Maurizio Crestani, Donatella Caruso, Emma De Fabiani, Nico Mitro
RÉSUMÉ

The metabolic transition from anaerobic glycolysis and fatty acid β-oxidation to glycolysis coupled to oxidative phosphorylation is a key process for the transition of quiescent neural stem cells to proliferative neural progenitor cells. However, a full characterization of the metabolic shift and the involvement of mitochondria during the last step of neurogenesis, from neuroblasts to neuron maturation, is still elusive. Here, we describe a model of neuroblasts, Neuro2a cells, with impaired differentiation capacity due to mitochondrial dysfunction. Using a detailed biochemical characterization consisting of steady-state metabolomics and metabolic flux analysis, we find increased fatty acid β-oxidation as a peculiar feature of neuroblasts with altered mitochondria. The consequent metabolic switch favors neuroblast proliferation at the expense of neuron maturation.

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Albumine de sérum bovin, heat shock fraction, pH 5.2, ≥96%
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