Identification and validation of a T cell receptor targeting KRAS G12V in HLA-A*11:01 pancreatic cancer patients
Xiongfei Xu, Shiwei Guo, Haihui Gu, Zhanshan Cha, Xiaohan Shi, Xiaoyi Yin, Huan Wang, Suizhi Gao, Bo Li, Lingyu Zhu, Wei Jing, Kailian Zheng, Zhuo Shao, Peng Cheng, Chunhong Zheng, Yi-Ping Shih, Yunguang Li, Baohua Qian, Dong Gao, Eric Tran, Gang Jin
Xiongfei Xu, Shiwei Guo, Haihui Gu, Zhanshan Cha, Xiaohan Shi, Xiaoyi Yin, Huan Wang, Suizhi Gao, Bo Li, Lingyu Zhu, Wei Jing, Kailian Zheng, Zhuo Shao, Peng Cheng, Chunhong Zheng, Yi-Ping Shih, Yunguang Li, Baohua Qian, Dong Gao, Eric Tran, Gang Jin
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Research Article Immunology Oncology

Identification and validation of a T cell receptor targeting KRAS G12V in HLA-A*11:01 pancreatic cancer patients

Abstract

T cells targeting a KRAS mutation can induce durable tumor regression in some patients with metastatic epithelial cancer. It is unknown whether T cells targeting mutant KRAS that are capable of killing tumor cells can be identified from peripheral blood of patients with pancreatic cancer. We developed an in vitro stimulation approach and identified HLA-A*11:01–restricted KRAS G12V–reactive CD8+ T cells and HLA-DRB1*15:01–restricted KRAS G12V–reactive CD4+ T cells from peripheral blood of 2 out of 6 HLA-A*11:01–positive patients with pancreatic cancer whose tumors expressed KRAS G12V. The HLA-A*11:01–restricted KRAS G12V–reactive T cell receptor (TCR) was isolated and validated to specifically recognize the KRAS G12V8–16 neoepitope. While T cells engineered to express this TCR specifically recognized all 5 tested human HLA-A*11:01+ and KRAS G12V+ pancreatic cancer organoids, the recognition was often modest, and tumor cell killing was observed in only 2 out of 5 organoids. IFN-γ priming of the organoids enhanced the recognition and killing by the TCR-engineered T cells. The TCR-engineered T cells could significantly slow the growth of an established organoid-derived xenograft in immunodeficient mice. Our data suggest that this TCR has potential for use in TCR-gene therapy, but additional strategies that enhance tumor recognition by the TCR-engineered T cells likely will be required to increase clinical activity.

Authors

Xiongfei Xu, Shiwei Guo, Haihui Gu, Zhanshan Cha, Xiaohan Shi, Xiaoyi Yin, Huan Wang, Suizhi Gao, Bo Li, Lingyu Zhu, Wei Jing, Kailian Zheng, Zhuo Shao, Peng Cheng, Chunhong Zheng, Yi-Ping Shih, Yunguang Li, Baohua Qian, Dong Gao, Eric Tran, Gang Jin

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Figure 5

TCR-001–transduced T cells specifically recognized human pancreatic cancer organoids.

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TCR-001–transduced T cells specifically recognized human pancreatic canc...
(A) KRAS mutation and HLA profiles of human pancreatic cancer organoids. (B) TCR-001–transduced allogeneic T cells were cocultured overnight with human pancreatic cancer organoid cells naturally expressing KRAS G12 mutations or HLA-A*11:01. 4-1BB/OX-40 upregulation was assayed by flow cytometry. (C and D) TCR-001–transduced allogeneic T cells were cocultured with human pancreatic cancer organoid cells naturally expressing KRAS G12 mutations or HLA-A*11:01 for 5 hours. CD107a upregulation (C) and IFN-γ/TNF-α secretion (D) were assayed by intracellular cytokine staining. (E) TCR-001–transduced allogeneic T cells were cocultured overnight with human pancreatic cancer organoid cells naturally expressing KRAS G12 mutations or HLA-A*11:01 pulsed with 1 μg/mL KRAS WT or G12V 9-mer peptides. 4-1BB/OX-40 upregulation was assayed by flow cytometry. (F) TCR-001–transduced allogeneic T cells were cocultured overnight with human pancreatic cancer organoid cells naturally expressing KRAS G12 mutations or HLA-A*11:01. 4-1BB/OX-40 upregulation was assayed by flow cytometry. Anti–human HLA-ABC antibody (20 μg/mL) was used in some groups. Error bars represent SEM of at least 3 biological replicates. Dots indicate biological replicates. *P < 0.05; **P < 0.01 vs. “T alone” group or indicated group. Statistical differences were determined by mixed-effects analysis with Tukey’s multiple-comparison test (BD and F) or 1-way ANOVA followed by Tukey’s multiple-comparison test (E).