An iron-dependent metabolic vulnerability underlies VPS34-dependence in RKO cancer cells.

M.j Kobylarz ,Joseph Loureiro,Carsten Russ,Ellen O’Mahony,Jonathan M Goodwin,Leon O Murphy,Qiong Wang,Dmitri Wiederschain,Judith Knehr,John Alford,Guglielmo Roma,Christophe Antczak,Alicia Lindeman,Suchithra Menon,Beat Nyfeler,Martin Beibel,Sarah Hevi,Walter Carbone,Gregory Mcallister,John W Annand,John S Reece‐Hoyes ,Kang Zhao

doi:10.1371/journal.pone.0235551

M.j Kobylarz , Joseph Loureiro + Show 20 more

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https://doi.org/10.1371/journal.pone.0235551

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Journal: PloS one	Publication Date: Aug 24, 2020
Citations: 8	License type: CC BY 4.0

Affiliation: Novartis (United States), Novartis (Switzerland)

Abstract

VPS34 is a key regulator of endomembrane dynamics and cargo trafficking, and is essential in cultured cell lines and in mice. To better characterize the role of VPS34 in cell growth, we performed unbiased cell line profiling studies with the selective VPS34 inhibitor PIK-III and identified RKO as a VPS34-dependent cellular model. Pooled CRISPR screen in the presence of PIK-III revealed endolysosomal genes as genetic suppressors. Dissecting VPS34-dependent alterations with transcriptional profiling, we found the induction of hypoxia response and cholesterol biosynthesis as key signatures. Mechanistically, acute VPS34 inhibition enhanced lysosomal degradation of transferrin and low-density lipoprotein receptors leading to impaired iron and cholesterol uptake. Excess soluble iron, but not cholesterol, was sufficient to partially rescue the effects of VPS34 inhibition on mitochondrial respiration and cell growth, indicating that iron limitation is the primary driver of VPS34-dependency in RKO cells. Loss of RAB7A, an endolysosomal marker and top suppressor in our genetic screen, blocked transferrin receptor degradation, restored iron homeostasis and reversed the growth defect as well as metabolic alterations due to VPS34 inhibition. Altogether, our findings suggest that impaired iron mobilization via the VPS34-RAB7A axis drive VPS34-dependence in certain cancer cells.

Highlights

VPS34 is a class III PI3-kinase that is ubiquitously expressed across eukaryotes and essential for physiology and organismal development
Looking more closely at some of the strongest PIK-III suppressor hits with a significance RSA cutoff value of -7.0, we identified sphingolipid metabolism genes (SPTLC1, SPTLC2 and SPTSSA) as well as genes involved in endosomal-lysosomal maturation (RAB5C, RAB7A, CCZ1 and RMC1), phosphatidylinositol modification (VAC14 and FIG4), clathrindependent endocytosis (AP2S1), early endosome tethering (VPS8), lysosomal degradation (CTSL), and a retriever complex component (VPS35L) (Fig 2D)
This study identifies RKO as a highly VPS34-dependent cellular model and describes an irondependent metabolic vulnerability that underlies impaired RKO cell growth upon VPS34 inhibition

Summary

Introduction

VPS34 is a class III PI3-kinase that is ubiquitously expressed across eukaryotes and essential for physiology and organismal development. Perturbations of VPS34 result in pleiotropic defects by altering vesicular trafficking [1,2,3,4], intracellular signaling [5,6,7], metabolism [8, 9] and cellular growth [10, 11]. The manuscript was assessed by the Novartis legal department to ascertain that release of this manuscript did not contravene Novartis policy regarding release of proprietary information, but this was limited only to approval for release of the material and was not related to the results or interpretations/conclusions contained in the manuscript

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