AIF-regulated oxidative phosphorylation supports lung cancer development

Rao S ,Franz Quehenberger ,Alexander Lercher ,Tsung-Pin Pai ,Helmut Popper ,Andréas Bergthaler ,Gautier Stoll ,I Kozieradzki ,Masahiro Onji ,Rubina Koglgruber ,Kaican Cai ,Katharina Haigh ,Laura Mondragón ,Shane J F Cronin ,Guido Kroemer ,Oliver Kepp ,Peng Zhang ,Nazanine Modjtahedi ,Zhi‐Gang She ,Jody J Haigh ,Valentina Sica ,Blanka Pranjic ,Malgorzata Rak ,Daniel Schramek ,Reiko Hanada ,Thomas Köcher ,Marion Leduc ,Iris Uribesalgo ,Lukas Kenner ,Toshikatsu Hanada ,Alexander Jais ,Josef Penninger

doi:10.1038/s41422-019-0181-4

Abstract

Cancer is a major and still increasing cause of death in humans. Most cancer cells have a fundamentally different metabolic profile from that of normal tissue. This shift away from mitochondrial ATP synthesis via oxidative phosphorylation towards a high rate of glycolysis, termed Warburg effect, has long been recognized as a paradigmatic hallmark of cancer, supporting the increased biosynthetic demands of tumor cells. Here we show that deletion of apoptosis-inducing factor (AIF) in a KrasG12D-driven mouse lung cancer model resulted in a marked survival advantage, with delayed tumor onset and decreased malignant progression. Mechanistically, Aif deletion leads to oxidative phosphorylation (OXPHOS) deficiency and a switch in cellular metabolism towards glycolysis in non-transformed pneumocytes and at early stages of tumor development. Paradoxically, although Aif-deficient cells exhibited a metabolic Warburg profile, this bioenergetic change resulted in a growth disadvantage of KrasG12D-driven as well as Kras wild-type lung cancer cells. Cell-autonomous re-expression of both wild-type and mutant AIF (displaying an intact mitochondrial, but abrogated apoptotic function) in Aif-knockout KrasG12D mice restored OXPHOS and reduced animal survival to the same level as AIF wild-type mice. In patients with non-small cell lung cancer, high AIF expression was associated with poor prognosis. These data show that AIF-regulated mitochondrial respiration and OXPHOS drive the progression of lung cancer.

Highlights

apoptosis-inducing factor (AIF) was first cloned as a caspaseindependent death effector released from mitochondria.[1]
Similar to the key cell death effector molecule cytochrome c, AIF contributes to cell death pathways, and exerts a vital housekeeping function inside mitochondria, where it determines the rate of oxidative phosphorylation (OXPHOS) via posttranscriptional regulation of complex I proteins in the mitochondrial respiratory chain.[3,5,6,7,8]
Since AIF is a protein with a dual function in cell death and OXPHOS, we tested whether genetic modulation of Aif would affect lung cancer tumorigenesis

Summary

Introduction

AIF (apoptosis-inducing factor) was first cloned as a caspaseindependent death effector released from mitochondria.[1]. Cancer cells have a fundamentally different metabolic profile from that of normal tissue and this shift away from mitochondrial

Methods

Results

Conclusion