结合基因工程T细胞和免疫检查点阻断治疗癌症。

IF 4.1 Q2 IMMUNOLOGY Immunotherapy advances Pub Date : 2022-01-25 eCollection Date: 2022-01-01 DOI:10.1093/immadv/ltac005
Rafaela Rossetti, Heloísa Brand, Sarah Caroline Gomes Lima, Izadora Peter Furtado, Roberta Maraninchi Silveira, Daianne Maciely Carvalho Fantacini, Dimas Tadeu Covas, Lucas Eduardo Botelho de Souza
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引用次数: 7

摘要

使用单克隆抗体阻断免疫检查点(IC)是目前治疗癌症最成功的免疫治疗干预措施之一。通过重新激活抗肿瘤耗尽的T细胞,这种方法可以导致持久的临床反应。然而,大多数患者对IC阻断没有反应或表现出短暂的反应,部分原因是肿瘤微环境中肿瘤特异性T细胞的缺乏。表达嵌合抗原受体(CARs)或工程化T细胞受体(TCRs)的T细胞过继转移提供了必要的肿瘤特异性免疫细胞群来靶向癌细胞。然而,这种疗法对实体瘤相当无效,部分原因是肿瘤微环境中ic介导的免疫抑制作用。这些限制可以通过将基因工程T细胞的过继细胞转移和IC阻断相结合来克服。在这篇全面的综述中,我们强调了临床前和临床尝试在过继性t细胞转移中破坏IC信号的策略和结果。这些策略包括联合使用基因工程T细胞和IC抑制剂,改造T细胞以破坏IC信号传导,以及设计针对IC分子的car。目前的情况表明,基因编辑技术和合成生物学的快速改进以及对IC信号的进一步理解的协同作用,肯定会转化为一种新的、更有效的免疫治疗方法来治疗癌症患者。
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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Combination of genetically engineered T cells and immune checkpoint blockade for the treatment of cancer.

Immune checkpoint (IC) blockade using monoclonal antibodies is currently one of the most successful immunotherapeutic interventions to treat cancer. By reinvigorating antitumor exhausted T cells, this approach can lead to durable clinical responses. However, the majority of patients either do not respond or present a short-lived response to IC blockade, in part due to a scarcity of tumor-specific T cells within the tumor microenvironment. Adoptive transfer of T cells genetically engineered to express chimeric antigen receptors (CARs) or engineered T-cell receptors (TCRs) provide the necessary tumor-specific immune cell population to target cancer cells. However, this therapy has been considerably ineffective against solid tumors in part due to IC-mediated immunosuppressive effects within the tumor microenvironment. These limitations could be overcome by associating adoptive cell transfer of genetically engineered T cells and IC blockade. In this comprehensive review, we highlight the strategies and outcomes of preclinical and clinical attempts to disrupt IC signaling in adoptive T-cell transfer against cancer. These strategies include combined administration of genetically engineered T cells and IC inhibitors, engineered T cells with intrinsic modifications to disrupt IC signaling, and the design of CARs against IC molecules. The current landscape indicates that the synergy of the fast-paced refinements of gene-editing technologies and synthetic biology and the increased comprehension of IC signaling will certainly translate into a novel and more effective immunotherapeutic approaches to treat patients with cancer.

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