计算机科学
计算生物学
工作流程
抗体
单克隆抗体
表位
表位定位
结合亲和力
噬菌体展示
钥匙(锁)
表面等离子共振
可扩展性
肽库
药物发现
抗体库
系统生物学
免疫
血凝素(流感)
作者
Fandi Wu,Yu Zhao,Jiaxiang Wu,Biaobin Jiang,Bing He,Long-Kai Huang,Chenchen Qin,Yang Xiao,Fan Yang,Rubo Wang,Ningqiao Huang,Huaxian Jia,Yuyi Liu,Houtim Lai,Tingyang Xu,Fang Wang,Zihan Wu,Yiran Song,Shaoning Li,Wei Liu
标识
DOI:10.1038/s41467-025-67361-9
摘要
Accurate modeling of antibody-antigen complex structures holds significant potential for advancing biomedical research and the design of therapeutic antibodies. Compared to general proteins, progress in antibody structure prediction and design has been slow, and antibody discovery is still based on time-consuming animal immunization or library screening methods. Here, we present tFold System, a high-throughput computational workflow that integrates antibody structure prediction (tFold-Ab), antibody-antigen complex modeling (tFold-Ag), structure-guided virtual screening, and de novo epitope-specific antibody design. Using this system, we de novo design monoclonal antibodies (mAbs) against four therapeutically relevant antigens: influenza hemagglutinin (Flu A), PD-1, PD-L1, and SARS-CoV-2 RBD (SC2RBD). Experimental validation by surface plasmon resonance (SPR) following high-throughput screening via phage display shows the designed antibodies achieve nanomolar binding affinities and precise epitope targeting, demonstrating the efficiency of the integrated computational-experimental pipeline. Our results demonstrate that tFold System overcomes key limitations of existing methods by enabling rapid, high-throughput antibody discovery against user-defined epitopes.
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