Suppression of non-muscle myosin II boosts T cell cytotoxicity against tumors

Yingyun Yang; Dahan Wen; Feng Lin; Xiaowei Song; Ruiyang Pang; Weihao Sun; Donglin Yu; Ziyi Zhang; Tao Yu; Jie Kong; Lei Zhang; Xinyuan Cao; Wanying Liao; Dingding Wang; Qianyi Yang; Junbo Liang; Ning Zhang; Kailong Li; Chunyang Xiong; Yuying Liu

doi:10.1126/sciadv.adp0631

Suppression of non-muscle myosin II boosts T cell cytotoxicity against tumors

Yingyun Yang, Dahan Wen, Feng Lin, Xiaowei Song, Ruiyang Pang, Weihao Sun, Donglin Yu, Ziyi Zhang, Tao Yu, Jie Kong, Lei Zhang, Xinyuan Cao, Wanying Liao, Dingding Wang, Qianyi Yang, Junbo Liang, Ning Zhang, Kailong Li (Lead / Corresponding author), Chunyang Xiong (Lead / Corresponding author), Yuying Liu (Lead / Corresponding author)

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Abstract

Increasing evidence highlights the importance of immune mechanoregulation in establishing and sustaining tumor-specific cytotoxicity required for desirable immunotherapeutic outcomes. However, the molecular connections between mechanobiological inputs and outputs and the designated immune activities remain largely unclear. Here, we show that partial inhibition of non-muscle myosin II (NM II) augmented the traction force exerted by T cells and potentiated T cell cytotoxicity against tumors. By using T cells from mice and patients with cancer, we found that NM II is required for the activity of NKX3-2 in maintaining the expression of ADGRB3, which shapes the filamentous actin (F-actin) organization and ultimately attributes to the reduced traction force of T cells in the tumor microenvironment. In animal models, suppressing the NM II–NKX3-2–ADGRB3 pathway in T cells effectively suppressed tumor growth and improved the efficacy of the checkpoint-specific immunotherapy. Overall, this work provides insights into the biomechanical regulation of T cell cytotoxicity that can be exploited to optimize clinical immunotherapies.

Original language	English
Article number	eadp0631
Number of pages	15
Journal	Science Advances
Volume	10
Issue number	44
DOIs	https://doi.org/10.1126/sciadv.adp0631
Publication status	Published - 1 Nov 2024

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title = "Suppression of non-muscle myosin II boosts T cell cytotoxicity against tumors",

abstract = "Increasing evidence highlights the importance of immune mechanoregulation in establishing and sustaining tumor-specific cytotoxicity required for desirable immunotherapeutic outcomes. However, the molecular connections between mechanobiological inputs and outputs and the designated immune activities remain largely unclear. Here, we show that partial inhibition of non-muscle myosin II (NM II) augmented the traction force exerted by T cells and potentiated T cell cytotoxicity against tumors. By using T cells from mice and patients with cancer, we found that NM II is required for the activity of NKX3-2 in maintaining the expression of ADGRB3, which shapes the filamentous actin (F-actin) organization and ultimately attributes to the reduced traction force of T cells in the tumor microenvironment. In animal models, suppressing the NM II–NKX3-2–ADGRB3 pathway in T cells effectively suppressed tumor growth and improved the efficacy of the checkpoint-specific immunotherapy. Overall, this work provides insights into the biomechanical regulation of T cell cytotoxicity that can be exploited to optimize clinical immunotherapies.",

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AU - Yang, Yingyun

AU - Wen, Dahan

AU - Lin, Feng

AU - Song, Xiaowei

AU - Pang, Ruiyang

AU - Sun, Weihao

AU - Yu, Donglin

AU - Zhang, Ziyi

AU - Yu, Tao

AU - Kong, Jie

AU - Zhang, Lei

AU - Cao, Xinyuan

AU - Liao, Wanying

AU - Wang, Dingding

AU - Yang, Qianyi

AU - Liang, Junbo

AU - Zhang, Ning

AU - Li, Kailong

AU - Xiong, Chunyang

AU - Liu, Yuying

PY - 2024/11/1

Y1 - 2024/11/1

N2 - Increasing evidence highlights the importance of immune mechanoregulation in establishing and sustaining tumor-specific cytotoxicity required for desirable immunotherapeutic outcomes. However, the molecular connections between mechanobiological inputs and outputs and the designated immune activities remain largely unclear. Here, we show that partial inhibition of non-muscle myosin II (NM II) augmented the traction force exerted by T cells and potentiated T cell cytotoxicity against tumors. By using T cells from mice and patients with cancer, we found that NM II is required for the activity of NKX3-2 in maintaining the expression of ADGRB3, which shapes the filamentous actin (F-actin) organization and ultimately attributes to the reduced traction force of T cells in the tumor microenvironment. In animal models, suppressing the NM II–NKX3-2–ADGRB3 pathway in T cells effectively suppressed tumor growth and improved the efficacy of the checkpoint-specific immunotherapy. Overall, this work provides insights into the biomechanical regulation of T cell cytotoxicity that can be exploited to optimize clinical immunotherapies.

AB - Increasing evidence highlights the importance of immune mechanoregulation in establishing and sustaining tumor-specific cytotoxicity required for desirable immunotherapeutic outcomes. However, the molecular connections between mechanobiological inputs and outputs and the designated immune activities remain largely unclear. Here, we show that partial inhibition of non-muscle myosin II (NM II) augmented the traction force exerted by T cells and potentiated T cell cytotoxicity against tumors. By using T cells from mice and patients with cancer, we found that NM II is required for the activity of NKX3-2 in maintaining the expression of ADGRB3, which shapes the filamentous actin (F-actin) organization and ultimately attributes to the reduced traction force of T cells in the tumor microenvironment. In animal models, suppressing the NM II–NKX3-2–ADGRB3 pathway in T cells effectively suppressed tumor growth and improved the efficacy of the checkpoint-specific immunotherapy. Overall, this work provides insights into the biomechanical regulation of T cell cytotoxicity that can be exploited to optimize clinical immunotherapies.

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Suppression of non-muscle myosin II boosts T cell cytotoxicity against tumors

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