eIF4A supports an oncogenic translation program in pancreatic ductal adenocarcinoma

Karina Chan; Françis Robert; Christian Oertlin; Dana Kapeller-Libermann; Daina Avizonis; Johana Gutierrez; Abram Handly-Santana; Mikhail Doubrovin; Julia Park; Christina Schoepfer; Brandon Da Silva; Melissa A. Yao; Faith Gorton; Junwei Shi; Craig J. Thomas; Lauren E. Brown; John A. Porco; Michaël Pollak; Ola Larsson; Jerry Pelletier; Iok In Christine Chio

doi:10.1038/s41467-019-13086-5

eIF4A supports an oncogenic translation program in pancreatic ductal adenocarcinoma

Karina Chan(Columbia University Irving Medical Center), Françis Robert(McGill University Health Centre), Christian Oertlin(Karolinska Institutet), Dana Kapeller-Libermann(Columbia University Irving Medical Center), Daina Avizonis(McGill University Health Centre), Johana Gutierrez(Columbia University Irving Medical Center), Abram Handly-Santana(Cold Spring Harbor Laboratory), Mikhail Doubrovin(Columbia University Irving Medical Center), Julia Park(Cold Spring Harbor Laboratory), Christina Schoepfer(Cold Spring Harbor Laboratory), Brandon Da Silva(SUNY Downstate Health Sciences University), Melissa A. Yao(Cold Spring Harbor Laboratory), Faith Gorton(Cold Spring Harbor Laboratory), Junwei Shi(University of Pennsylvania), Craig J. Thomas(National Cancer Institute), Lauren E. Brown(Boston University), John A. Porco(Boston University), Michaël Pollak(McGill University), Ola Larsson(Karolinska Institutet), Jerry Pelletier(McGill University Health Centre), Iok In Christine Chio(Columbia University Irving Medical Center)

Nature Communications

November 13, 2019

10.1038/s41467-019-13086-5

Cited by 113Open Access

Full Text

Abstract

Pancreatic ductal adenocarcinoma (PDA) is a lethal malignancy with limited treatment options. Although metabolic reprogramming is a hallmark of many cancers, including PDA, previous attempts to target metabolic changes therapeutically have been stymied by drug toxicity and tumour cell plasticity. Here, we show that PDA cells engage an eIF4F-dependent translation program that supports redox and central carbon metabolism. Inhibition of the eIF4F subunit, eIF4A, using the synthetic rocaglate CR-1-31-B (CR-31) reduced the viability of PDA organoids relative to their normal counterparts. In vivo, CR-31 suppresses tumour growth and extends survival of genetically-engineered murine models of PDA. Surprisingly, inhibition of eIF4A also induces glutamine reductive carboxylation. As a consequence, combined targeting of eIF4A and glutaminase activity more effectively inhibits PDA cell growth both in vitro and in vivo. Overall, our work demonstrates the importance of eIF4A in translational control of pancreatic tumour metabolism and as a therapeutic target against PDA.

Related Papers

No related papers found

Powered by citation graph analysis