Preclinical model for evaluating human TCRs against chimeric syngeneic tumors.

IF 10.3 1区医学 Q1 IMMUNOLOGY Journal for Immunotherapy of Cancer Pub Date : 2024-12-22 DOI:10.1136/jitc-2024-009504

Aikaterini Semilietof, Evangelos Stefanidis, Elise Gray-Gaillard, Julien Pujol, Alessia D'Esposito, Patrick Reichenbach, Philippe Guillaume, Vincent Zoete, Melita Irving, Olivier Michielin

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Abstract

Background: The adoptive cell transfer (ACT) of T cell receptor (TCR)-engineered T cells targeting the HLA-A2-restricted epitope NY-ESO-1_157-165 (A2/NY) has yielded important clinical responses against several cancers. A variety of approaches are being taken to augment tumor control by ACT including TCR affinity-optimization and T-cell coengineering strategies to address the suppressive tumor microenvironment (TME). Most TCRs of clinical interest are evaluated in immunocompromised mice to enable human T-cell engraftment and do not recapitulate the dynamic interplay that occurs with endogenous immunity in a treated patient. A variety of humanized mouse models have been described but they have limitations in immune reconstitution and are technically challenging to implement. Here, we have developed a chimeric syngeneic tumor model in which A2Kb transgenic C57BL/6 mice are engrafted with B16 expressing A2Kb:NY as a single chain trimer (SCT) and treated by ACT with murine T cells expressing A2/NY TCRs comprising human variable fused to mouse constant regions.

Methods: We compared the function of a supraphysiological affinity A2/NY TCR (wtc51m), a computationally designed TCR in an optimal affinity range (DMβ), and a near non-binding TCR (V49I), engineered in both primary human and murine T cells by lentiviral and retroviral transduction, respectively. We evaluated a variety of strategies to stably express A2Kb:NY on the surface of mouse tumor cell lines including B16 melanoma, ultimately achieving success with an SCT comprising human β2m fused by GS linkers to both the NY-peptide and to α1 of the HLA complex. ACT studies were performed in B16-A2Kb:NY tumor-bearing, non-preconditioned immune-competent HLA-A*0201/H-2Kb (A2Kb) transgenic C57BL/6 mice and tumors characterized post-transfer.

Results: We observed significantly improved function of DMβ-T cells as well as superior infiltration and tumor control upon ACT as compared to the control TCR-T cells. Moreover, with our chimeric syngeneic tumor model, we were able to track dynamic and favorable changes in the TME upon DMβ-T cell transfer.

Conclusions: We have developed a robust, simple, and inexpensive preclinical strategy for evaluating human TCRs in the context of a fully competent murine immune system that can aid in the development of coengineered TCR-T cells and combination treatments translated to the clinic.

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评估人tcr抗嵌合同基因肿瘤的临床前模型。

背景：T细胞受体（TCR）工程T细胞靶向hla -A2限制性表位NY- eso -1157-165 （A2/NY）的过继细胞转移（ACT）已经对几种癌症产生了重要的临床反应。人们正在采取多种方法来增强ACT对肿瘤的控制，包括TCR亲和优化和t细胞协同工程策略，以解决抑制性肿瘤微环境（TME）。大多数具有临床意义的tcr都是在免疫功能低下的小鼠中进行评估，以使人类t细胞植入，并且不能重现治疗患者体内与内源性免疫发生的动态相互作用。各种各样的人源化小鼠模型已经被描述，但它们在免疫重建方面有局限性，并且在技术上具有挑战性。在这里，我们建立了一个嵌合的同基因肿瘤模型，将A2Kb转基因C57BL/6小鼠植入表达A2Kb:NY的B16作为单链三聚体（SCT），并用ACT处理表达A2/NY TCRs的小鼠T细胞，其中包含人类变量融合到小鼠恒定区域。方法：我们比较了A2/NY TCR （wtc51m）、计算设计的最佳亲和力范围TCR （DMβ）和近非结合TCR （V49I）的功能，它们分别通过慢病毒和逆转录病毒转导在人和小鼠原代T细胞中进行工程设计。我们评估了多种在小鼠肿瘤细胞系（包括B16黑色素瘤）表面稳定表达A2Kb:NY的策略，最终成功地将人β2m通过GS连接体融合到NY肽和HLA复合物的α1上。ACT研究在B16-A2Kb:NY荷瘤、非预处理免疫活性HLA-A*0201/H-2Kb （A2Kb）转基因C57BL/6小鼠和转移后的肿瘤中进行。结果：与对照TCR-T细胞相比，ACT对DMβ-T细胞的功能有明显改善，浸润和肿瘤控制也有明显改善。此外，利用我们的嵌合同基因肿瘤模型，我们能够跟踪DMβ-T细胞转移时TME的动态和有利变化。结论：我们已经开发出一种强大、简单、廉价的临床前策略，用于在完全胜任的小鼠免疫系统背景下评估人类tcr，可以帮助开发协同工程TCR-T细胞和转化为临床的联合治疗。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal for Immunotherapy of Cancer Biochemistry, Genetics and Molecular Biology-Molecular Medicine

CiteScore

17.70

自引率

4.60%

发文量

522

审稿时长

18 weeks

期刊介绍： The Journal for ImmunoTherapy of Cancer (JITC) is a peer-reviewed publication that promotes scientific exchange and deepens knowledge in the constantly evolving fields of tumor immunology and cancer immunotherapy. With an open access format, JITC encourages widespread access to its findings. The journal covers a wide range of topics, spanning from basic science to translational and clinical research. Key areas of interest include tumor-host interactions, the intricate tumor microenvironment, animal models, the identification of predictive and prognostic immune biomarkers, groundbreaking pharmaceutical and cellular therapies, innovative vaccines, combination immune-based treatments, and the study of immune-related toxicity.