T细胞
调节器
嵌合抗原受体
化学
信号转导
细胞生物学
效应器
细胞
突变
生物
突变体
T细胞受体
功能(生物学)
细胞生长
点突变
机制(生物学)
重编程
计算生物学
受体
抗原
细胞信号
共刺激
效力
调节性T细胞
细胞代谢
记忆T细胞
遗传学
作者
Philip Bucher,Nadine Brückner,Jule Kortendieck,Melanie Grimm,Jan Schleicher,Karlotta Bartels,Steffen Hardy,Martina Rausch,Hannah Wurzer,Meike Thiemann,Celina May,Mara Mitstorfer,Dennis Letzgus,Julia Quach,Carolin Schneider,Denis Andrei Ispan,Irene González-Menéndez,Nayan Jain,Yu-Jui Ho,Jiangqing Chen
出处
期刊:Nature cancer
[Nature Portfolio]
日期:2026-01-06
卷期号:7 (2): 368-383
被引量:1
标识
DOI:10.1038/s43018-025-01099-7
摘要
Insufficient functional T cell persistence impedes therapeutic success of chimeric antigen receptor (CAR) therapies. Here we performed a CAR-adapted base-editing screen of PIK3CD, a key regulator of T cell function, metabolism and fate. We identified point mutations that beneficially modulate CAR T cell profiles in 4-1BBz and 28z CAR T cells, respectively. We found that point mutations with differing effects on phosphatidylinositol-3-kinase delta (PI3Kδ) signaling activity were advantageous in distinct CAR contexts: The PI3Kδ-activating substitution E81K enhanced proliferation, metabolic fitness and effector function of 4-1BBz CARs, promoting long-term functional persistence and enhanced therapeutic efficacy in vivo. Conversely, the PI3Kδ-attenuating substitution L32P improved T cell memory formation and functionality of 28z CAR T cells. Together, our approach of rational optimization of activation-dependent signaling through targeted allelic reprogramming (ROADSTAR) illustrates the importance of CAR design-specific fine-tuning of intrinsic T cell signaling and demonstrates the potential of base editing for next-generation cellular therapies.
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