Intersection of Immune and Oncometabolic Pathways Drives Cancer Hyperprogression During Immunotherapy

Overview

Journal Cancer Cell

Publisher Cell Press

Specialty Oncology

Date 2023 Jan 13

PMID 36638784

Authors

Gaopeng Li

Jae Eun Choi

Ilona Kryczek

Yilun Sun

Peng Liao

Shasha Li

Shuang Wei

Sara Grove

Linda Vatan

Reagan Nelson

Grace Schaefer

Steven G Allen

Kamya Sankar

Leslie A Fecher

Mishal Mendiratta-Lala

Timothy L Frankel

Angel Qin

Jessica J Waninger

Alangoya Tezel

Ajjai Alva

Christopher D Lao

Nithya Ramnath

Marcin Cieslik

Paul W Harms

Michael D Green

Arul M Chinnaiyan

Weiping Zou

Affiliations

Soon will be listed here.

Abstract

Immune checkpoint blockade (ICB) can produce durable responses against cancer. We and others have found that a subset of patients experiences paradoxical rapid cancer progression during immunotherapy. It is poorly understood how tumors can accelerate their progression during ICB. In some preclinical models, ICB causes hyperprogressive disease (HPD). While immune exclusion drives resistance to ICB, counterintuitively, patients with HPD and complete response (CR) following ICB manifest comparable levels of tumor-infiltrating CD8 T cells and interferon γ (IFNγ) gene signature. Interestingly, patients with HPD but not CR exhibit elevated tumoral fibroblast growth factor 2 (FGF2) and β-catenin signaling. In animal models, T cell-derived IFNγ promotes tumor FGF2 signaling, thereby suppressing PKM2 activity and decreasing NAD, resulting in reduction of SIRT1-mediated β-catenin deacetylation and enhanced β-catenin acetylation, consequently reprograming tumor stemness. Targeting the IFNγ-PKM2-β-catenin axis prevents HPD in preclinical models. Thus, the crosstalk of core immunogenic, metabolic, and oncogenic pathways via the IFNγ-PKM2-β-catenin cascade underlies ICB-associated HPD.

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