PO-243 Uncoupling FOXO3A mitochondrial and nuclear functions in cancer cells undergoing metabolic stress and chemotherapy

Abstract

IntroductionWhile aberrant cancer cell growth is frequently associated with altered biochemical metabolism, normal mitochondrial functions are usually preserved and necessary for full malignant transformation. The transcription factor FoxO3A is a key determinant of cancer cell homeostasis, playing a dual role in survival/death response. We recently described a novel mitochondrial arm of the AMPK-FoxO3A axis in normal cells upon nutrient shortage.Material and methodsAfter extensive characterisation of mitochondrial FoxO3A function in vitro in several cell lines and tumours, we generated FoxO3A-knockout cancer cells with the CRISPR/Cas9 system and reconstituted FoxO3A expression with wild-type or mutant vectors.Results and discussionsHere we show that in metabolically stressed cancer cells, FoxO3A is recruited to the mitochondria through activation of MEK/ERK and AMPK which phosphorylate serine 12 and 30, respectively, on FoxO3A N-terminal domain. Subsequently, FoxO3A is imported and cleaved to reach mitochondrial DNA, where it activates expression of the mitochondrial genome to support mitochondrial metabolism and cell survival. Using FoxO3A-/- cancer cells generated with the CRISPR/Cas9 genome editing system and reconstituted with FoxO3A mutants being impaired in their nuclear or mitochondrial subcellular localization, we show that mitochondrial FoxO3A promotes survival in response to metabolic stress.In cancer cells treated with chemotherapeutic agents, accumulation of FoxO3A into the mitochondria promoted survival in a MEK/ERK-dependent manner, while mitochondrial FoxO3A was required for apoptosis induction by metformin.ConclusionElucidation of FoxO3A mitochondrial vs. nuclear functions in cancer cell homeostasis might help devise novel personalised therapeutic strategies to selectively disable FoxO3A pro-survival activity and manipulate cellular metabolism to counteract cancer initiation and progression.