Li Yuanke, Zhang Haoqi, Wang Ruikun, Wang Yuan, Li Ruonan, Zhu Mingsheng, Zhang Xiangyun, Zhao Zhen, Wan Yajuan, Zhuang Jie, Zhang Hongkai, Huang Xinglu
State Key Laboratory of Medicinal Chemical Biology, Key Laboratory of Bioactive Materials for the Ministry of Education, College of Life Sciences and Frontiers Science Center for Cell Responses, Nankai University, Tianjin, 300071, P. R. China.
Joint Laboratory of Nanozymes, College of Life Sciences, Nankai University, Tianjin, 300071, P. R. China.
Adv Mater. 2023 Mar;35(13):e2208923. doi: 10.1002/adma.202208923. Epub 2023 Feb 15.
Despite the promise in whole-tumor cell vaccines, a key challenge is to overcome the lack of costimulatory signals. Here, agonistic-antibody-boosted tumor cell nanovaccines are reported by genetically engineered antibody-anchored membrane (AAM) technology, capable of effectively activating costimulatory pathways. Specifically, the AAM can be stably constructed following genetic engineering of tumor cell membranes with anti-CD40 single chain variable fragment (scFv), an agonistic antibody to induce costimulatory signals. The nanovaccines are versatilely designed and obtained based on the anti-CD40 scFv-anchored membrane and nanotechnology. Following vaccination, the anti-CD40 scFv-anchored membrane nanovaccine (Nano-AAM/CD40) significantly facilitates dendritic cell maturation in CD40-humanized transgenic mice and subsequent adaptive immune responses. Compared to membrane-based nanovaccines alone, the enhanced antitumor efficacy in both "hot" and "cold" tumor models of the Nano-AAM/CD40 demonstrates the importance of agonistic antibodies in development of tumor-cell-based vaccines. To expand the design of nanovaccines, further incorporation of cell lysates into the Nano-AAM/CD40 to conceptually construct tumor cell-like nanovaccines results in boosted immune responses and improved antitumor efficacy against malignant tumors inoculated into CD40-humanized transgenic mice. Overall, this genetically engineered AAM technology provides a versatile design of nanovaccines by incorporation of tumor-cell-based components and agonistic antibodies of costimulatory immune checkpoints.
尽管全肿瘤细胞疫苗前景广阔,但一个关键挑战是克服共刺激信号的缺乏。在此,通过基因工程抗体锚定膜(AAM)技术报道了激动剂抗体增强的肿瘤细胞纳米疫苗,其能够有效激活共刺激途径。具体而言,通过用抗CD40单链可变片段(scFv)对肿瘤细胞膜进行基因工程改造,可以稳定构建AAM,抗CD40单链可变片段是一种诱导共刺激信号的激动剂抗体。基于抗CD40 scFv锚定膜和纳米技术,对纳米疫苗进行了多样化设计并制备成功。接种疫苗后,抗CD40 scFv锚定膜纳米疫苗(Nano-AAM/CD40)显著促进了CD40人源化转基因小鼠中树突状细胞的成熟以及随后的适应性免疫反应。与单独的基于膜的纳米疫苗相比,Nano-AAM/CD40在“热”和“冷”肿瘤模型中增强的抗肿瘤功效证明了激动剂抗体在基于肿瘤细胞的疫苗开发中的重要性。为了扩展纳米疫苗的设计,将细胞裂解物进一步掺入Nano-AAM/CD40中以概念性地构建肿瘤细胞样纳米疫苗,可增强免疫反应并提高对接种到CD40人源化转基因小鼠中的恶性肿瘤的抗肿瘤功效。总体而言,这种基因工程AAM技术通过整合基于肿瘤细胞的成分和共刺激免疫检查点的激动剂抗体,提供了一种多样化的纳米疫苗设计。
