ST2 as checkpoint target for colorectal cancer immunotherapy
Kevin Van der Jeught, Yifan Sun, Yuanzhang Fang, Zhuolong Zhou, Hua Jiang, Tao Yu, Jinfeng Yang, Malgorzata M. Kamocka, Ka Man So, Yujing Li, Haniyeh Eyvani, George E. Sandusky, Michael Frieden, Harald Braun, Rudi Beyaert, Xiaoming He, Xinna Zhang, Chi Zhang, Sophie Paczesny, Xiongbin Lu
Kevin Van der Jeught, Yifan Sun, Yuanzhang Fang, Zhuolong Zhou, Hua Jiang, Tao Yu, Jinfeng Yang, Malgorzata M. Kamocka, Ka Man So, Yujing Li, Haniyeh Eyvani, George E. Sandusky, Michael Frieden, Harald Braun, Rudi Beyaert, Xiaoming He, Xinna Zhang, Chi Zhang, Sophie Paczesny, Xiongbin Lu
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Research Article Immunology Inflammation

ST2 as checkpoint target for colorectal cancer immunotherapy

Abstract

Immune checkpoint blockade immunotherapy delivers promising clinical results in colorectal cancer (CRC). However, only a fraction of cancer patients develop durable responses. The tumor microenvironment (TME) negatively impacts tumor immunity and subsequently clinical outcomes. Therefore, there is a need to identify other checkpoint targets associated with the TME. Early-onset factors secreted by stromal cells as well as tumor cells often help recruit immune cells to the TME, among which are alarmins such as IL-33. The only known receptor for IL-33 is stimulation 2 (ST2). Here we demonstrated that high ST2 expression is associated with poor survival and is correlated with low CD8+ T cell cytotoxicity in CRC patients. ST2 is particularly expressed in tumor-associated macrophages (TAMs). In preclinical models of CRC, we demonstrated that ST2-expressing TAMs (ST2+ TAMs) were recruited into the tumor via CXCR3 expression and exacerbated the immunosuppressive TME; and that combination of ST2 depletion using ST2-KO mice with anti–programmed death 1 treatment resulted in profound growth inhibition of CRC. Finally, using the IL-33trap fusion protein, we suppressed CRC tumor growth and decreased tumor-infiltrating ST2+ TAMs. Together, our findings suggest that ST2 could serve as a potential checkpoint target for CRC immunotherapy.

Authors

Kevin Van der Jeught, Yifan Sun, Yuanzhang Fang, Zhuolong Zhou, Hua Jiang, Tao Yu, Jinfeng Yang, Malgorzata M. Kamocka, Ka Man So, Yujing Li, Haniyeh Eyvani, George E. Sandusky, Michael Frieden, Harald Braun, Rudi Beyaert, Xiaoming He, Xinna Zhang, Chi Zhang, Sophie Paczesny, Xiongbin Lu

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Figure 4

ST2+ TAM characterization.

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ST2+ TAM characterization. (A) CyTOF analysis of M2 phenotype of ST2+ TA...
(A) CyTOF analysis of M2 phenotype of ST2+ TAMs and ST2 TAMs from MC38 tumors. Representative CyTOF overlay histograms; and quantification (n = 5; data displayed as mean + SD). (B) Flow cytometry analysis of ST2+ TAMs and ST2 TAMs from MC38 tumors. Representative histogram overlays of ST2+ TAMs and ST2 TAMs for the indicated surface markers; and quantification (n = 5; data displayed as mean + SD). (C) Expression levels of CXCR3 on ST2+ TAMs during tumor development. Representative histogram of CXCR3 expression and quantification (n = 5; data displayed as mean + SD). (D) Macrophage suppression assay of MC38-enriched macrophages from WT and ST2–/– mice. Representative flow cytometry histograms of CD8+ T cell proliferation (CFSE) upon distinct coculture conditions; and quantification of CD8+ T cell proliferation upon TAM coculture (n = 6; data displayed as mean + SEM). (E) Quantification of T cell IFN-γ secretion on supernatants upon TAM coculture (n = 6; data displayed as mean + SEM). Growth (F) and weight (G) of MC38 tumors upon macrophage depletion using anti-CSF1R antibodies (WT isotype, n = 4; ST2–/– isotype, n = 5; WT anti-CSF1R, n = 6; ST2–/– anti-CSF1R, n = 6) (F, data displayed as mean + SEM; G, mean + SD) Scale bar: 1 cm. *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001. Significance was determined by 2-tailed unpaired t test (AE) and 2-way ANOVA (F).