cGAS/STING axis mediates a topoisomerase II inhibitor–induced tumor immunogenicity
Zining Wang, … , Liang-ping Xia, Xiaojun Xia
Zining Wang, … , Liang-ping Xia, Xiaojun Xia
Published August 13, 2019
Citation Information: J Clin Invest. 2019;129(11):4850-4862. https://doi.org/10.1172/JCI127471.
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Research Article Immunology Oncology Article has an altmetric score of 5

cGAS/STING axis mediates a topoisomerase II inhibitor–induced tumor immunogenicity

Abstract

Checkpoint blockade antibodies have been approved as immunotherapy for multiple types of cancer, but the response rate and efficacy are still limited. There are few immunogenic cell death–inducing (ICD-inducing) drugs available that can kill cancer cells, enhance tumor immunogenicity, increase in vivo immune infiltration, and thereby boost a tumor response to immunotherapy. So far, the ICD markers have been identified as the few immunostimulating characteristics of dead cells, but whether the presence of such ICD markers on tumor cells translates into enhanced antitumor immunity in vivo is still being investigated. To identify anticancer drugs that could induce tumor cell death and boost T cell response, we performed drug screenings based on both an ICD reporter assay and a T cell activation assay. We showed that teniposide, a DNA topoisomerase II inhibitor, could induce high-mobility group box 1 (HMGB1) release and type I IFN signaling in tumor cells and that teniposide-treated tumor cells could activate antitumor T cell response both in vitro and in vivo. Mechanistically, teniposide induced tumor cell DNA damage and innate immune signaling, including NF-κB activation and stimulator of IFN genes–dependent (STING-dependent) type I IFN signaling, both of which contribute to the activation of dendritic cells and subsequent T cells. Furthermore, teniposide potentiated the antitumor efficacy of anti-PD1 in multiple types of mouse tumor models. Our findings showed that teniposide could trigger tumor immunogenicity and enabled a potential chemoimmunotherapeutic approach to potentiating the therapeutic efficacy of anti-PD1 immunotherapy.

Authors

Zining Wang, Jiemin Chen, Jie Hu, Hongxia Zhang, Feifei Xu, Wenzhuo He, Xiaojuan Wang, Mengyun Li, Wenhua Lu, Gucheng Zeng, Penghui Zhou, Peng Huang, Siyu Chen, Wende Li, Liang-ping Xia, Xiaojun Xia

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Figure 2

Teniposide induced ICD of tumor cells.

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Teniposide induced ICD of tumor cells. (A) MC38 (HMGB1-Gluc) and CT26 (H...
(A) MC38 (HMGB1-Gluc) and CT26 (HMGB1-Gluc) cells were treated with increasing doses of teniposide for 20 hours, and HMGB1-Gluc luciferase activity was measured. (B and C) CT26 cells were treated with teniposide or DMSO for 20 hours, and cell apoptosis (B) and surface expression of CRT(C) were detected by FACS. (D) CT26 tumor cells were pretreated with teniposide, etoposide, or freeze-thawed, followed by subcutaneous inoculation into BALB/c mice as a vaccine (n = 8 for control group with no tumor cell vaccine administered, teniposide group, and freeze-thawed group; n = 5 for etoposide group). After 8 days, mice were rechallenged with live CT26 cells. Shown are the percentages of tumor-free mice 30 days after rechallenge. Data in AC are shown as mean ± SD of 3 independent experiments. **P < 0.01; ***P < 0.001, 1-way ANOVA with Bonferroni’s post test (A), unpaired Student’s t test (B), log-rank (Mantel-Cox) test (D).