Your search keyword '"Jingxin Fu"' showing total 2 results

1. Discovery of Targets for Immune–Metabolic Antitumor Drugs Identifies Estrogen-Related Receptor Alpha

Author

Avinash Sahu, Xiaoman Wang, Phillip Munson, Jan P.G. Klomp, Xiaoqing Wang, Shengqing Stan Gu, Ya Han, Gege Qian, Phillip Nicol, Zexian Zeng, Chenfei Wang, Collin Tokheim, Wubing Zhang, Jingxin Fu, Jin Wang, Nishanth Ulhas Nair, Joost A.P. Rens, Meriem Bourajjaj, Bas Jansen, Inge Leenders, Jaap Lemmers, Mark Musters, Sanne van Zanten, Laura van Zelst, Jenny Worthington, Jun S. Liu, Dejan Juric, Clifford A. Meyer, Arthur Oubrie, X. Shirley Liu, David E. Fisher, and Keith T. Flaherty

Subjects

Oncology

Abstract

Drugs that kill tumors through multiple mechanisms have the potential for broad clinical benefits. Here, we first developed an in silico multiomics approach (BipotentR) to find cancer cell–specific regulators that simultaneously modulate tumor immunity and another oncogenic pathway and then used it to identify 38 candidate immune–metabolic regulators. We show the tumor activities of these regulators stratify patients with melanoma by their response to anti–PD-1 using machine learning and deep neural approaches, which improve the predictive power of current biomarkers. The topmost identified regulator, ESRRA, is activated in immunotherapy-resistant tumors. Its inhibition killed tumors by suppressing energy metabolism and activating two immune mechanisms: (i) cytokine induction, causing proinflammatory macrophage polarization, and (ii) antigen-presentation stimulation, recruiting CD8+ T cells into tumors. We also demonstrate a wide utility of BipotentR by applying it to angiogenesis and growth suppressor evasion pathways. BipotentR (http://bipotentr.dfci.harvard.edu/) provides a resource for evaluating patient response and discovering drug targets that act simultaneously through multiple mechanisms.Significance:BipotentR presents resources for evaluating patient response and identifying targets for drugs that can kill tumors through multiple mechanisms concurrently. Inhibition of the topmost candidate target killed tumors by suppressing energy metabolism and effects on two immune mechanisms.This article is highlighted in the In This Issue feature, p. 517

Published

2023

2. Therapeutically Increasing MHC-I Expression Potentiates Immune Checkpoint Blockade

Author

Henry W. Long, Blair Stewig, Alba Font-Tello, Xiaoqing Wang, Michael Manos, Ziyi Li, X. Shirley Liu, Jingxin Fu, Paloma Cejas, Gordon J. Freeman, Alok K. Tewari, Scott J. Rodig, Yi Zhang, Zexian Zeng, F. Stephen Hodi, Clifford A. Meyer, Yingtian Xie, Xia Bu, Wubing Zhang, Collin Tokheim, Avinash Das Sahu, Jason L. Weirather, Jake Conway, Klothilda Lim, Myles Brown, Jin Hua Liang, Evisa Gjini, Shengqing Stan Gu, Ana Lako, Peng Jiang, Benjamin Kroger, Nicole Traugh, and Benjamin E. Gewurz

Subjects

0301 basic medicine, T cell, medicine.medical_treatment, B7-H1 Antigen, Article, 03 medical and health sciences, 0302 clinical medicine, Downregulation and upregulation, Neoplasms, MHC class I, Tumor Microenvironment, Data Mining, Humans, Medicine, Immune Checkpoint Inhibitors, biology, business.industry, Gene Expression Profiling, Histocompatibility Antigens Class I, Cancer, Immunotherapy, medicine.disease, Immune checkpoint, Blockade, 030104 developmental biology, medicine.anatomical_structure, Oncology, 030220 oncology & carcinogenesis, Cancer cell, Cancer research, biology.protein, business

Abstract

Immune checkpoint blockade (ICB) therapy revolutionized cancer treatment, but many patients with impaired MHC-I expression remain refractory. Here, we combined FACS-based genome-wide CRISPR screens with a data-mining approach to identify drugs that can upregulate MHC-I without inducing PD-L1. CRISPR screening identified TRAF3, a suppressor of the NFκB pathway, as a negative regulator of MHC-I but not PD-L1. The Traf3-knockout gene expression signature is associated with better survival in ICB-naïve patients with cancer and better ICB response. We then screened for drugs with similar transcriptional effects as this signature and identified Second Mitochondria-derived Activator of Caspase (SMAC) mimetics. We experimentally validated that the SMAC mimetic birinapant upregulates MHC-I, sensitizes cancer cells to T cell–dependent killing, and adds to ICB efficacy. Our findings provide preclinical rationale for treating tumors expressing low MHC-I expression with SMAC mimetics to enhance sensitivity to immunotherapy. The approach used in this study can be generalized to identify other drugs that enhance immunotherapy efficacy. Significance: MHC-I loss or downregulation in cancer cells is a major mechanism of resistance to T cell–based immunotherapies. Our study reveals that birinapant may be used for patients with low baseline MHC-I to enhance ICB response. This represents promising immunotherapy opportunities given the biosafety profile of birinapant from multiple clinical trials. This article is highlighted in the In This Issue feature, p. 1307

Published

2021