Degradation of IF1 controls energy metabolism during osteogenic differentiation of stem cells. [artículo]
Por: Cuezva, J.M [Instituto de Investigación i+12] | Sánchez Aragó, María [Instituto de Investigación i+12].
Colaborador(es): Instituto de Investigación imas12.
Editor: EMBO reports, 2013Descripción: 14(7):638-44.Recursos en línea: Acceso libre Resumen: Differentiation of human mesenchymal stem cells (hMSCs) requires the rewiring of energy metabolism. Herein, we demonstrate that the ATPase inhibitory factor 1 (IF1) is expressed in hMSCs and in prostate and colon stem cells but is not expressed in the differentiated cells. IF1 inhibits oxidative phosphorylation and regulates the activity of aerobic glycolysis in hMSCs. Silencing of IF1 in hMSCs mimics the metabolic changes observed in osteocytes and accelerates cellular differentiation. Activation of IF1 degradation acts as the switch that regulates energy metabolism during differentiation. We conclude that IF1 is a stemness marker important for maintaining the quiescence state.Tipo de ítem | Ubicación actual | Signatura | Estado | Fecha de vencimiento |
---|---|---|---|---|
Artículo | PC2864 (Navegar estantería) | Disponible |
Formato Vancouver:
Sánchez-Aragó M, García-Bermúdez J, Martínez-Reyes I, Santacatterina F, Cuezva JM. Degradation of IF1 controls energy metabolism during osteogenic differentiation of stem cells. EMBO Rep. 2013 Jul;14(7):638-44.
PMID: 23722655
Contiene 19 referencias
Differentiation of human mesenchymal stem cells (hMSCs) requires the rewiring of energy metabolism. Herein, we demonstrate that the ATPase inhibitory factor 1 (IF1) is expressed in hMSCs and in prostate and colon stem cells but is not expressed in the differentiated cells. IF1 inhibits oxidative phosphorylation and regulates the activity of aerobic glycolysis in hMSCs. Silencing of IF1 in hMSCs mimics the metabolic changes observed in osteocytes and accelerates cellular differentiation. Activation of IF1 degradation acts as the switch that regulates energy metabolism during differentiation. We conclude that IF1 is a stemness marker important for maintaining the quiescence state.
No hay comentarios para este ejemplar.