Mitochondrial AKAP1 supports mTOR pathway and tumor growth

Laura Rinaldi,Kristel Conte,Stefano Amente,Gaetano Rocco,Maria Sepe,Monia Porpora,Sara Pignatiello,Luigi Insabato,Giuseppe Matarese,Maria Antonietta Oliva ,Deriggio Faicchia,Claudio Procaccini,Domenica Borzacchiello,Rossella Delle Donne,Federica Zito Marino,Renato Franco,Fernanda De Vita,Corrado Garbi,Barbara Majello,Antonietta Arcella,Antonio Feliciello

doi:10.1038/cddis.2017.241

Abstract

Mitochondria are the powerhouses of energy production and the sites where metabolic pathway and survival signals integrate and focus, promoting adaptive responses to hormone stimulation and nutrient availability. Increasing evidence suggests that mitochondrial bioenergetics, metabolism and signaling are linked to tumorigenesis. AKAP1 scaffolding protein integrates cAMP and src signaling on mitochondria, regulating organelle biogenesis, oxidative metabolism and cell survival. Here, we provide evidence that AKAP1 is a transcriptional target of Myc and supports the growth of cancer cells. We identify Sestrin2, a leucine sensor and inhibitor of the mammalian target of rapamycin (mTOR), as a novel component of the complex assembled by AKAP1 on mitochondria. Downregulation of AKAP1 impaired mTOR pathway and inhibited glioblastoma growth. Both effects were reversed by concomitant depletion of AKAP1 and sestrin2. High levels of AKAP1 were found in a wide variety of high-grade cancer tissues. In lung cancer, AKAP1 expression correlates with high levels of Myc, mTOR phosphorylation and reduced patient survival. Collectively, these data disclose a previously unrecognized role of AKAP1 in mTOR pathway regulation and cancer growth. AKAP1/mTOR signal integration on mitochondria may provide a new target for cancer therapy.

Highlights

Damage to mitochondria leads to ageing and degenerative diseases.[1]
We determined if MYCN regulates AKAP1 expression in neuroblastoma cells, where MYCN is critical to oncogenesis
We provide evidence that mitochondrial AKAP1 is a novel Myc transcriptional target and is highly expressed in a wide array of human cancer tissues

Summary

Introduction

Damage to mitochondria leads to ageing and degenerative diseases.[1]. In normal cells, dynamic adjustment of mitochondrial activities promotes metabolic adaptation to changes in extracellular microenvironment and nutrient availability.[2]. Signaling events generated at the cell membrane by hormones and growth factors modulate mitochondrial activity, helping to adapt the cell to changes in metabolic demands. CAMP-dependent protein kinase (PKA) mediates hormone effects on cellular respiration. Localization of PKA at membranes, cytoskeleton and cellular organelles is achieved by direct interaction with A-kinase-anchor-proteins (AKAPs).[5]. AKAPs act as local signal transduction units that direct and amplify cAMP signals at target sites.[6,7] AKAP1 targets PKA to the outer mitochondrial membrane.[8] AKAP121/149, AKAP100 and AKAP84 are alternate splice products of a single gene (AKAP1).[9] These splice variants share a similar. NH2-terminal core, which includes the mitochondrial-targeting domain and the PKA-binding domain, but diverge significantly at the C-terminus.

Methods

Results

Conclusion