ATM inhibition enhances cancer immunotherapy by promoting mtDNA leakage and cGAS/STING activation
Mengjie Hu, … , Fang Li, Chuan-Yuan Li
Mengjie Hu, … , Fang Li, Chuan-Yuan Li
Published December 8, 2020
Citation Information: J Clin Invest. 2021;131(3):e139333. https://doi.org/10.1172/JCI139333.
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Research Article Oncology

ATM inhibition enhances cancer immunotherapy by promoting mtDNA leakage and cGAS/STING activation

Abstract

Novel approaches are needed to boost the efficacy of immune checkpoint blockade (ICB) therapy. Ataxia telangiectasia mutated (ATM) protein plays a central role in sensing DNA double-stranded breaks (DSBs) and coordinating their repair. Recent data indicated that ATM might be a promising target to enhance ICB therapy. However, the molecular mechanism involved has not been clearly elucidated. Here, we show that ATM inhibition could potentiate ICB therapy by promoting cytoplasmic leakage of mitochondrial DNA (mtDNA) and activation of the cGAS/STING pathway. We show that genetic depletion of ATM in murine cancer cells delayed tumor growth in syngeneic mouse hosts in a T cell–dependent manner. Furthermore, chemical inhibition of ATM potentiated anti–PD-1 therapy of mouse tumors. ATM inhibition potently activated the cGAS/STING pathway and enhanced lymphocyte infiltration into the tumor microenvironment by downregulating mitochondrial transcription factor A (TFAM), which led to mtDNA leakage into the cytoplasm. Moreover, our analysis of data from a large patient cohort indicated that ATM mutations, especially nonsense mutations, predicted for clinical benefits of ICB therapy. Our study therefore provides strong evidence that ATM may serve as both a therapeutic target and a biomarker to enable ICB therapy.

Authors

Mengjie Hu, Min Zhou, Xuhui Bao, Dong Pan, Meng Jiao, Xinjian Liu, Fang Li, Chuan-Yuan Li

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Figure 3

ATM inhibition increases the cytoplasmic release of mtDNA.

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ATM inhibition increases the cytoplasmic release of mtDNA. (A) WB verifi...
(A) WB verification of our cytosol fractionation protocol. Vector control and ATM-KO B16 cells were fractionated, and whole-cell extracts (WCE), pellets (Pel), cytosolic extracts (Cyt), and mitochondrion (Mito) were blotted using the indicated antibodies. (B) qRT-PCR quantification of cytosolic DNA extracted from digitonin-permeabilized cytosolic extracts of control and ATM-KO B16F10 cells. Normalization was carried out as described in Methods. (C) WB analysis of B16F10 cells treated with 1 μM AZD1390 for 48 hours and subjected to fractionation. (D) qRT-PCR analysis of DNA extracted from digitonin-permeabilized extracts of control and AZD1390-treated B16F10 cells. (E) Vector control and Atm-KO B16F10 cells were costained with anti-dsDNA (green), anti-Hsp60 (red), and DAPI. Scale bars: 10 μm. Original magnification, ×12 (insets). Data represent the mean ± SEM (B and D). **P < 0.01, ***P < 0.001, and ****P < 0.0001, by 2-way ANOVA. n = 3 (B and D). Nuc, nuclear.