This proposal aims to characterize the role of the tumor suppressor protein PML in the regulation of metabolic processes, and the consequences of PML-loss in obesity, diabetes and cancer pathogenesis. The relevance of this study relies in the possible utilization of PML as a marker of metabolic diseases and target for therapy. We have cloned, characterized and identified PML, throughout the years, as a tumor suppressor frequently loss in blood and solid cancers. PML exerts its tumor suppressive activity through the regulation of senescence, apoptosis and neoangiogenesis. Surprisingly, a detailed analysis of the metabolic status of Pml-deficient mice and cells has unveiled a novel role for PML in the regulation of metabolism, which shows that Pml-loss results in altered energy source utilization, defective response to fasting, and reduced fatty acid oxidation. Preliminary data show that PML is required for proper AMPK activation, and for the response of mice to the antidiabetic drug Metformin. Additionally, cytoplasmic PML localization increases upon energy deprivation, thus suggesting that PML function is modulated according to the demand of energy. The notion of cancer genes directly regulating metabolic processes has been supported by the recent identification of tumor suppressors and oncogenes at the crossroad of metabolism and cancer, such as p53 and Myc. Hence, a metabolic function for PML becomes extremely attractive, not only in terms of metabolic diseases per se, but also in the context of cancer susceptibility. This application is based on the hypothesis that PML in the cytoplasm is required for the proper metabolic function of the cell and that, in turn, adequate metabolic regulation by PML is a key component for its tumor suppressive activity. We will address this hypothesis with the following specific aims: (1) To define the role of PML in nutrient adaptation and analyze the status of PML in obese and diabetic patients;(2) to assess the molecular mechanism of AMPK regulation by PML and the consequences of Pml-loss in metabolic pathways;(3) to ascertain the regulation and metabolic function of PML in the cytoplasm and (4) to study the implications of PML metabolic function on in its tumor suppressive activity in vivo.
Cancer, diabetes and obesity are by now epidemic disorders in the occidental world. Their development is intertwined because molecular pathways that are involved in the genesis of these metabolic disorders have been also implicated in cancer development. Exciting preliminary findings indicate that the PML tumor suppressor opposes cancer but also these metabolic syndromes. This proposal outlines an experimental program to study this novel function of PML with important therapeutic implications.
Carracedo, Arkaitz; Cantley, Lewis C; Pandolfi, Pier Paolo (2013) Cancer metabolism: fatty acid oxidation in the limelight. Nat Rev Cancer 13:227-32 |
Dos Santos, Guilherme Augusto; Kats, Lev; Pandolfi, Pier Paolo (2013) Synergy against PML-RARa: targeting transcription, proteolysis, differentiation, and self-renewal in acute promyelocytic leukemia. J Exp Med 210:2793-802 |
Ito, Keisuke; Carracedo, Arkaitz; Weiss, Dror et al. (2012) A PML–PPAR-? pathway for fatty acid oxidation regulates hematopoietic stem cell maintenance. Nat Med 18:1350-8 |
Carracedo, Arkaitz; Weiss, Dror; Leliaert, Amy K et al. (2012) A metabolic prosurvival role for PML in breast cancer. J Clin Invest 122:3088-100 |
Carracedo, Arkaitz; Ito, Keisuke; Pandolfi, Pier Paolo (2011) The nuclear bodies inside out: PML conquers the cytoplasm. Curr Opin Cell Biol 23:360-6 |