Datlinger Paul, Pankevich Eugenia V, Arnold Cosmas D, Pranckevicius Nicole, Lin Jenny, Romanovskaia Daria, Schaefer Moritz, Piras Francesco, Orts Anne-Christine, Nemc Amelie, Biesaga Paulina N, Chan Michelle, Neuwirth Teresa, Artemov Artem V, Li Wentao, Ladstätter Sabrina, Krausgruber Thomas, Bock Christoph
CeMM Research Center for Molecular Medicine of the Austrian Academy of Sciences, Vienna, Austria.
Arc Institute, Palo Alto, CA, USA.
Nature. 2025 Oct;646(8086):963-972. doi: 10.1038/s41586-025-09507-9. Epub 2025 Sep 24.
Chimeric antigen receptor (CAR) T cell therapy has shown remarkable success in treating blood cancers, but CAR T cell dysfunction remains a common cause of treatment failure. Here we present CELLFIE, a CRISPR screening platform for enhancing CAR T cells across multiple clinical objectives. We performed genome-wide screens in human primary CAR T cells, with readouts capturing key aspects of T cell biology, including proliferation, target cell recognition, activation, apoptosis and fratricide, and exhaustion. Screening hits were prioritized using a new in vivo CROP-seq method in a xenograft model of human leukaemia, establishing several gene knockouts that boost CAR T cell efficacy. Most notably, we discovered that RHOG knockout is a potent and unexpected CAR T cell enhancer, both individually and together with FAS knockout, which was validated across multiple in vivo models, CAR designs and sample donors, and in patient-derived cells. Demonstrating the versatility of the CELLFIE platform, we also conducted combinatorial CRISPR screens to identify synergistic gene pairs and saturation base-editing screens to characterize RHOG variants. In summary, we discovered, validated and biologically characterized CRISPR-boosted CAR T cells that outperform standard CAR T cells in widely used benchmarks, establishing a foundational resource for optimizing cell-based immunotherapies.
嵌合抗原受体(CAR)T细胞疗法在治疗血液癌症方面已显示出显著成效,但CAR T细胞功能障碍仍是治疗失败的常见原因。在此,我们展示了CELLFIE,这是一个用于跨多个临床目标增强CAR T细胞的CRISPR筛选平台。我们在人类原代CAR T细胞中进行了全基因组筛选,通过读数捕获T细胞生物学的关键方面,包括增殖、靶细胞识别、激活、凋亡、自相残杀和耗竭。在人类白血病异种移植模型中,使用一种新的体内CROP-seq方法对筛选结果进行排序,确定了几个可提高CAR T细胞疗效的基因敲除。最值得注意的是,我们发现RHOG基因敲除是一种强大且意想不到的CAR T细胞增强剂,无论是单独敲除还是与FAS基因敲除一起,这在多个体内模型、CAR设计和样本供体以及患者来源的细胞中都得到了验证。为证明CELLFIE平台的多功能性,我们还进行了组合CRISPR筛选以识别协同基因对,并进行了饱和碱基编辑筛选以表征RHOG变体。总之,我们发现、验证并从生物学角度表征了经CRISPR增强的CAR T细胞,这些细胞在广泛使用的基准测试中优于标准CAR T细胞,为优化基于细胞的免疫疗法奠定了基础资源。
