Inhibition of the ATM/Chk2 axis promotes cGAS/STING signaling in ARID1A-deficient tumors
Lulu Wang, Lin Yang, Chen Wang, Wei Zhao, Zhenlin Ju, Wei Zhang, Jianfeng Shen, Yang Peng, Clemens An, Yen T. Luu, Shumei Song, Timothy A. Yap, Jaffer A. Ajani, Gordon B. Mills, Xuetong Shen, Guang Peng
Lulu Wang, Lin Yang, Chen Wang, Wei Zhao, Zhenlin Ju, Wei Zhang, Jianfeng Shen, Yang Peng, Clemens An, Yen T. Luu, Shumei Song, Timothy A. Yap, Jaffer A. Ajani, Gordon B. Mills, Xuetong Shen, Guang Peng
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Research Article Cell biology Immunology

Inhibition of the ATM/Chk2 axis promotes cGAS/STING signaling in ARID1A-deficient tumors

Abstract

ARID1A, a component of the chromatin-remodeling complex SWI/SNF, is one of the most frequently mutated genes in human cancer. We sought to develop rational combination therapy to potentiate the efficacy of immune checkpoint blockade in ARID1A-deficient tumors. In a proteomic analysis of a data set from The Cancer Genomic Atlas, we found enhanced expression of Chk2, a DNA damage checkpoint kinase, in ARID1A-mutated/deficient tumors. Surprisingly, we found that ARID1A targets the nonchromatin substrate Chk2 for ubiquitination. Loss of ARID1A increased the Chk2 level through modulating autoubiquitination of the E3-ligase RNF8 and thereby reducing RNF8-mediated Chk2 degradation. Inhibition of the ATM/Chk2 DNA damage checkpoint axis led to replication stress and accumulation of cytosolic DNA, which subsequently activated the DNA sensor STING-mediated innate immune response in ARID1A-deficient tumors. As expected, tumors with mutation or low expression of both ARID1A and ATM/Chk2 exhibited increased tumor-infiltrating lymphocytes and were associated with longer patient survival. Notably, an ATM inhibitor selectively potentiated the efficacy of immune checkpoint blockade in ARID1A-depleted tumors but not in WT tumors. Together, these results suggest that ARID1A’s targeting of the nonchromatin substrate Chk2 for ubiquitination makes it possible to selectively modulate cancer cell–intrinsic innate immunity to enhance the antitumor activity of immune checkpoint blockade.

Authors

Lulu Wang, Lin Yang, Chen Wang, Wei Zhao, Zhenlin Ju, Wei Zhang, Jianfeng Shen, Yang Peng, Clemens An, Yen T. Luu, Shumei Song, Timothy A. Yap, Jaffer A. Ajani, Gordon B. Mills, Xuetong Shen, Guang Peng

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Figure 6

ATM inhibition enhances the therapeutic efficacy of ICB in ARID1A-deficient tumors.

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ATM inhibition enhances the therapeutic efficacy of ICB in ARID1A-defici...
(A) Schematic of isotype control IgG, KU-60019, and anti–PD-L1 antibody treatment. Treatments were started on day 5 after inoculation and stopped on day 32. (B) Representative images for bioluminescence of mice with i.p. ID8 tumors on day 7 and day 26. Left, parental ID8 tumors. Right, ARID1A-depleted (sgRNA) ID8 i.p. tumors. (C) Endpoint of bioluminescence in mice bearing parental and ARID1A-depleted (sgRNA) ID8 i.p. tumors. Parental: IgG vs. anti–PD-L1, not significant; IgG vs. combination, not significant. sgRNA: IgG vs. anti–PD-L1, P = 0.097; IgG vs. combination, P = 0.014. Data represent mean ± SD (n = 3–5). (D) Survival curves of mice with ID8 i.p. tumors. Top, parental ID8 tumors. Bottom, ARID1A-depleted (sgRNA) ID8 tumors. Parental: anti–PD-L1 vs. combination, not significant; sgRNA: anti–PD-L1 vs. combination, P = 0.0069. (E) Top, CD8 and PD-L1 fluorescence-based IHC staining in parental and ARID1A-depleted ID8 i.p. tumors (n = 3 or 4). Bottom, quantitative analysis represent mean  ±  SD with indicated P value. +, positive. Scale bar: 50 μm. Two-tailed unpaired Student’s t test (C and E); log-rank (Mantel-Cox) test (D).