Targeting intracellular LMP2 with costimulatory signal–armed antibody-like TCR T cells
Jiali Cheng, Xuelian Hu, Zhenyu Dai, Yuhao Zeng, Jin Jin, Wei Mu, Qiaoe Wei, Xiangyin Jia, Jianwei Liu, Meng Xie, Qian Luo, Guang Hu, Gaoxiang Wang, Xiaojian Zhu, Jianfeng Zhou, Min Xiao, Jue Wang, Taochao Tan, Liang Huang
Jiali Cheng, Xuelian Hu, Zhenyu Dai, Yuhao Zeng, Jin Jin, Wei Mu, Qiaoe Wei, Xiangyin Jia, Jianwei Liu, Meng Xie, Qian Luo, Guang Hu, Gaoxiang Wang, Xiaojian Zhu, Jianfeng Zhou, Min Xiao, Jue Wang, Taochao Tan, Liang Huang
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Research Article Infectious disease Therapeutics

Targeting intracellular LMP2 with costimulatory signal–armed antibody-like TCR T cells

Abstract

Expanding the repertoire of CAR therapies to include intracellular antigens holds promise for treating a broad spectrum of malignancies. TCR-like T cells, capable of recognizing intracellular antigen–derived peptides in complex with HLA molecules (pHLA), represent a promising strategy in the field of engineered cellular therapy. This study introduced antibody-like TCR (abTCR) T cells that specifically targeted HLA-A*02:01–restricted LMP2426 peptides, a typical Epstein-Barr virus (EBV) latency II protein, for the treatment of EBV-associated lymphoproliferative diseases (EBV-LPDs). Compared with classic CAR T cells targeting the same epitope, abTCR T cells demonstrated superior efficiency, including increased CD107A expression, enhanced cytotoxicity, and elevated IFN-γ secretion, even when engaging with target cells that naturally present antigens. Moreover, a costimulatory signal–armed abTCR (Co-abTCR), which integrated a costimulatory structure with the abTCR, further enhanced the proliferation and in vivo tumoricidal efficacy of transfected T cells. Collectively, our study developed a potentially novel TCR-like T cell therapy that targets HLA-A*02/LMP2426 for the treatment of EBV-LPDs, providing a potential therapeutic solution for targeting of intracellular antigens in cancer immunotherapy.

Authors

Jiali Cheng, Xuelian Hu, Zhenyu Dai, Yuhao Zeng, Jin Jin, Wei Mu, Qiaoe Wei, Xiangyin Jia, Jianwei Liu, Meng Xie, Qian Luo, Guang Hu, Gaoxiang Wang, Xiaojian Zhu, Jianfeng Zhou, Min Xiao, Jue Wang, Taochao Tan, Liang Huang

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Figure 4

Optimization of abTCR T cells.

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Optimization of abTCR T cells. (A) Schematic diagram of optimized abTCR ...
(A) Schematic diagram of optimized abTCR T cells. A chimeric receptor, composed of CD7-specific VHH, transmembrane domain and costimulatory domain, and CD28 or 4-1BB, is introduced into abTCR T cells, which can provide costimulatory signals, CD28, or 4-1BB upon CD7 stimulation. (B) The accumulative expansion folds of abTCR+, abTCR-28+, and abTCR-BB+ T cells after repeated stimulation of Jeko1-LMP2 cells (A*02/LMP2+CD7+) or SNK6 (A*02/LMP2+CD7). The mean ± SD from 5 independent replicates were presented. One-way ANOVA for matched data design followed by Bonferroni’s correction for multiple comparison was used. The ANOVA test for SNK6 stimulation was significant (P = 0.0258). (C) Representative cytolysis to Jeko1-LMP2 and SNK6 cells of abTCR T cells, abTCR-28 T cells, abTCR-BB T cells, and mock T cells from 1 donor, 3–4 repeats. One-way ANOVA with Bonferroni’s correction for comparison between abTCR-28/abTCR-BB T cells and abTCR T cells was performed. (D) The CD107A expression on CD8+ abTCR+, abTCR-28+, and abTCR-BB+ cells after incubation with the x axis–specified cell lines. The means ± SD from 3 different donors were presented. One-way ANOVA for matched data design with Bonferroni’s correction for comparison between abTCR-28/abTCR-BB group and abTCR group was performed. (E and F) The MFI of the exhaustion markers PD1, LAG3, and TIGIT on abTCR+, abTCR-28+, and abTCR-BB+ cells after repeated stimulation with Jeko1-LMP2 (E) or SNK6 (F). Mean ± SD from 5 or 6 independent experiments were plotted. One-way ANOVA for matched data design with Dunnett’s correction for comparison between abTCR-28/abTCR-BB group and abTCR group was performed. *P < 0.05; **P < 0.01.