Abstract
At present there is no metabolic characterization of acute promyelocytic leukemia (APL). Pathognomonic of APL, PML::RARα fusion protein rewires metabolic pathways to feed anabolic tumor cell's growth. All-trans retinoic acid (ATRA) and arsenic trioxide (ATO)-based therapies render APL the most curable subtype of AML, yet approximately 1% of cases are resistant and 5% relapse. We characterized the metabolic peculiarity and fuel requirement of PML::RARα expressing cells, to identify new targets for tailored therapies in resistant or relapsed APL patients. We analyzed cell metabolism in primary samples from seven APL patients, comparing them with normal CD34+ cells differentiated to promyelocyte and granulocyte, and different PML::RARα expressing cell lines. We show that the PML::RARα oncoprotein inhibits glycolysis, promotes tricarboxylic acid cycle (TCA), and favors long chain fatty acids (LCFA) catabolism. Targeting CD36 function, that promotes the cellular uptake of fatty acids to feed oxidative phosphorylation (OXPHOS), effectively restores sensitivity to ATO in NB4 ATO-resistant clones. Notably, our data demonstrate that glycolytic impairment via AKT inhibition by PML::RARα renders APL cells reliant on OXPHOS. This dependency confers high sensitivity to the VTX-AZA combination, suggesting the therapeutic efficacy of targeted combination treatment in resistant or relapsed APLs.