离体
体内
嵌合抗原受体
癌症研究
免疫疗法
肿瘤微环境
过继性细胞移植
间质细胞
化学
免疫系统
癌症免疫疗法
胰腺癌
胰腺肿瘤
体外
抗原
成纤维细胞
T细胞
信使核糖核酸
肿瘤抗原
免疫学
癌症
生物
分子生物学
肿瘤进展
细胞疗法
抗原提呈细胞
细胞生物学
作者
Khuloud Bajbouj,Zebin Xiao,Leslie Todd,Li Huang,Tyler E. Papp,Faris Halilovic,Jayalakshmi Ramani,Yanjie Bao,Matthew J. Butcher,Adrian Bot,Haig Aghajanian,Carl H. June,Drew Weissman,Hamideh Parhiz,Steven M. Albelda,Ellen Puré
标识
DOI:10.1158/2326-6066.cir-25-0663
摘要
Fibroblast activation protein (FAP), which is highly expressed on cancer-associated fibroblasts (CAF), is a promising therapeutic target to achieve normalization of the tumor microenvironment. We previously established an ex vivo retroviral-transduced FAP-specific chimeric antigen receptor (FAP-CAR) T-cell approach to deplete FAP+ CAFs that resulted in delayed tumor growth associated with disruption of desmoplastic matrix and enhanced immune cell infiltration and reversed immune exclusion and immunosuppression. In this study, we describe an in vivo strategy for generating FAP-CAR T cells using anti-CD5-conjugated targeted lipid nanoparticles (tLNP) encapsulating FAP-CAR mRNA and assessed the efficacy of this approach compared with adoptive transfer of retrovirus-transduced CAR T cells in a preclinical model of pancreatic ductal adenocarcinoma. With transient CAR expression in >45% of splenic, >69% of circulating, and >35% of tumor-infiltrating T cells, the abundance of peripheral and intratumoral FAP-CAR+ T cells detected following a single intravenous dose of FAP-CAR mRNA tLNPs was greater than that detected following administration of 1 × 107ex vivo retrovirally transduced FAP-CAR T cells. Furthermore, in vivo mRNA CAR T-cell engineering resulted in as good or greater inhibition of tumor growth as compared with adoptive transfer of ex vivo retroviral-engineered T cells. Given that in vivo generation of CAR T cells resulted in transient CAR expression and circumvented the need for autologous T-cell isolation, viral vectors, and lymphodepletion, this platform represents a potentially safer, more accessible, and cost-effective method for targeting stromal cells to normalize the tumor microenvironment in desmoplastic tumors and has potential implications for tumor antigen-targeted CAR T cells.
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