car工程淋巴细胞持久性由FAS配体-FAS自动调节回路控制。

IF 28.5 1区医学 Q1 ONCOLOGY

Nature cancer Pub Date : 2025-07-22 DOI:10.1038/s43018-025-01009-x

Fei Yi, Tal Cohen, Natalie Zimmerman, Friederike Dündar, Paul Zumbo, Razan Eltilib, Erica J Brophy, Hannah Arkin, Judith Feucht, Michael V Gormally, Christopher S Hackett, Korbinian N Kropp, Inaki Etxeberria, Smita S Chandran, Zeguo Zhao, Winson Cai, Anthony F Daniyan, Jae H Park, Caleb A Lareau, Katharine C Hsu, Michel Sadelain, Doron Betel, Christopher A Klebanoff

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引用次数: 0

摘要

嵌合抗原受体修饰淋巴细胞治疗B细胞恶性肿瘤然而，有限的持久性可能会限制这种方法的全部治疗潜力。FAS配体(FAS- l)/FAS相互作用控制淋巴细胞稳态。关于癌症患者中哪些细胞表达FAS-L以及这些来源是否会损害CAR的持久性的知识仍然不完整。在这里，我们构建了不同癌症的单细胞图谱，以鉴定表达FASLG（编码FAS-L的基因）的细胞亚群。我们发现FASLG的表达主要局限于内源性T细胞、自然杀伤（NK）细胞和CAR-T细胞，而肿瘤和基质细胞的表达则很少。为了确定CAR-T和CAR-NK细胞的存活是否受到FAS-L的调节，我们使用fas -显性阴性受体（ΔFAS）修饰的淋巴细胞进行了竞争适应度测定。转移后，ΔFAS-expressing CAR-T/CAR-NK细胞变得富集，这一现象通过敲除FASLG在机制上得到恢复。相比之下，FASLG对于car介导的肿瘤杀伤是必不可少的。在多种雌性小鼠模型中，ΔFAS共表达增强了抗肿瘤效果。总之，这些发现揭示了car工程淋巴细胞的持久性是由FAS- l /FAS自动调节回路控制的。

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CAR-engineered lymphocyte persistence is governed by a FAS ligand-FAS autoregulatory circuit.

Chimeric antigen receptor (CAR)-engineered lymphocytes treat B cell malignancies; however, limited persistence can restrain the full therapeutic potential of this approach. FAS ligand (FAS-L)/FAS interactions govern lymphocyte homeostasis. Knowledge of which cells express FAS-L in patients with cancer and whether these sources compromise CAR persistence remains incomplete. Here, we constructed a single-cell atlas of diverse cancers to identify cellular subsets expressing FASLG, the gene encoding FAS-L. We discovered that FASLG expression is limited primarily to endogenous T cells, natural killer (NK) cells and CAR-T cells, while tumor and stromal cell expression is minimal. To establish whether CAR-T and CAR-NK cell survival is FAS-L regulated, we performed competitive fitness assays using FAS-dominant negative receptor (ΔFAS)-modified lymphocytes. Following transfer, ΔFAS-expressing CAR-T/CAR-NK cells became enriched, a phenomenon that mechanistically was reverted through FASLG knockout. By contrast, FASLG was dispensable for CAR-mediated tumor killing. In multiple models in female mice, ΔFAS coexpression enhanced antitumor efficacy. Together, these findings reveal that CAR-engineered lymphocyte persistence is governed by a FAS-L/FAS autoregulatory circuit.

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来源期刊

Nature cancer Medicine-Oncology

CiteScore

31.10

自引率

1.80%

发文量

129

期刊介绍： Cancer is a devastating disease responsible for millions of deaths worldwide. However, many of these deaths could be prevented with improved prevention and treatment strategies. To achieve this, it is crucial to focus on accurate diagnosis, effective treatment methods, and understanding the socioeconomic factors that influence cancer rates. Nature Cancer aims to serve as a unique platform for sharing the latest advancements in cancer research across various scientific fields, encompassing life sciences, physical sciences, applied sciences, and social sciences. The journal is particularly interested in fundamental research that enhances our understanding of tumor development and progression, as well as research that translates this knowledge into clinical applications through innovative diagnostic and therapeutic approaches. Additionally, Nature Cancer welcomes clinical studies that inform cancer diagnosis, treatment, and prevention, along with contributions exploring the societal impact of cancer on a global scale. In addition to publishing original research, Nature Cancer will feature Comments, Reviews, News & Views, Features, and Correspondence that hold significant value for the diverse field of cancer research.