Profound reprogramming towards stemness in pancreatic cancer cells as adaptation to AKT inhibition

Cancer cells acquire resistance to cytotoxic therapies targeting major survival pathways by adapting their metabolism. The AKT pathway is a major regulator of human pancreatic adenocarcinoma progression and a key pharmacological target. The mechanisms of adaptation to long-term silencing of AKT isof...

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Autores: Arasanz, H. (Hugo)|||/items/af58f0cb-4fe5-409c-a96a-b2a6b6831b48, Hernández, C. (Carlos)|||/items/68e53601-57fa-4c2b-b8cd-70a92647b1f7, Bocanegra, A. (Ana)|||/items/bb0c2c14-2f4e-4fcb-a6de-a1268735f4cd, Chocarro, L. (Luisa)|||/items/6f7649fe-4d5c-4596-8bff-0a4c4797e891, Zuazo, M. (Miren)|||/items/b3adff74-ba07-454d-a65b-1c19349daa54, Gato-Cañas, M. (María)|||/items/ed21e1d0-319e-4b1c-a1f5-2c1be4560659, Ausin, K. (Karina)|||/items/a623ce0f-3882-47be-a0f8-0fbaaffd4d32, Santamaria, E. (Enrique)|||/items/fc2c70d6-973c-4d67-8185-6c56a59477c8, Fernandez-Irigoyen, J. (Joaquín)|||/items/700f4366-d68f-4161-af03-2cac47ea718d, Fernandez, G. (Gonzalo)|||/items/d6febcb8-38b2-4de5-a9c0-9a7274cddfd1, Santamaría, E. (Eva)|||/items/7060efc6-8410-47f8-a7c4-51845be6a4a3, Rodríguez, C. (Carlos)|||/items/d4aefe81-9936-4d84-bc6a-e3a4d2508422, Blanco-Luquin, I. (Idoia)|||/items/fa72529e-5158-4c97-8404-1c33cd9b084d, Vera, R. (Ruth)|||/items/c5e822da-e29b-4f65-bb1c-be8bb5b999e1, Escors, D. (David)|||/items/82737dd6-3010-4c11-ae0f-a6efb4f177a6, Kochan, G. (Grazyna)|||/items/bf76a215-0675-467b-bb79-f2b4192fa4b2
Tipo de recurso: artículo
Fecha de publicación:2020
País:España
Institución:Universidad de Navarra
Repositorio:Dadun. Depósito Académico Digital de la Universidad de Navarra
Idioma:inglés
OAI Identifier:oai:dadun.unav.edu:10171/67707
Acceso en línea:https://hdl.handle.net/10171/67707
Access Level:acceso abierto
Palabra clave:Pancreatic cancer
Cancer stem cell
AKT
Descripción
Sumario:Cancer cells acquire resistance to cytotoxic therapies targeting major survival pathways by adapting their metabolism. The AKT pathway is a major regulator of human pancreatic adenocarcinoma progression and a key pharmacological target. The mechanisms of adaptation to long-term silencing of AKT isoforms of human and mouse pancreatic adenocarcinoma cancer cells were studied. Following silencing, cancer cells remained quiescent for long periods of time, after which they recovered proliferative capacities. Adaptation caused profound proteomic changes largely affecting mitochondrial biogenesis, energy metabolism and acquisition of a number of distinct cancer stem cell (CSC) characteristics depending on the AKT isoform that was silenced. The adaptation to AKT1 silencing drove most de-differentiation and acquisition of stemness through C-MYC down-modulation and NANOG upregulation, which were required for survival of adapted CSCs. The changes associated to adaptation sensitized cancer cells to inhibitors targeting regulators of oxidative respiration and mitochondrial biogenesis. In vivo pharmacological co-inhibition of AKT and mitochondrial metabolism effectively controlled pancreatic adenocarcinoma growth in pre-clinical models.