体细胞突变
表位
生物
抗体
保守序列
遗传学
体细胞
蛋白质结构域
计算生物学
病毒学
抗体库
表位定位
突变
序列比对
免疫逃逸
亲和力成熟
互补决定区
猴痘
埃博拉病毒
抗原变异
进化生物学
蛋白质结构
否定选择
糖蛋白
作者
Minxiang Xie,Yinong Qiu,Xiaoyu Zhao,Jialu Shi,Yuanchen Liu,Qingsong Zhang,Jiaying He,Jiayan Li,L. Liu,Siyuan Sun,Yuzhen Zhu,Qiyu Mao,Yiming Long,Thiago Y. Oliveira,Zijun Wang,Yunjiao Zhou,Yan Yan,Anqi Xia,Wenjing Zai,Christian T. Mayer
标识
DOI:10.1038/s41467-025-65596-0
摘要
The receptor-binding domain (RBD) of the SARS-CoV-2 spike (S) protein continues to evolve, facilitating antibody evasion. It remains unclear whether any conserved RBD epitopes persist across SARS-CoV-2 variants and whether vaccination and/or breakthrough infection (BTI) can elicit antibodies capable of targeting these conserved regions to counter future variants. Here, using a heterogeneous double-bait single B-cell sorting strategy, we identify a subset of antibodies with broad-spectrum RBD binding, including recognition of SARS-CoV-1 and emerging variants such as EG.5.1, BA.2.86, JN.1, and KP.2/3. These broadly binding antibodies (bbAbs) exhibit elevated levels of somatic hypermutation but are infrequently derived from clonally expanded B lymphocytes. Passive transfer of representative bbAbs reduces viral infection in a male hamster model. Structural analyses reveals that these bbAbs primarily target three distinct, highly conserved RBD epitopes, suggesting potential regions of future mutational pressure and highlighting the presence of conserved and immunogenic RBD conformations that may serve as a foundation for the development of broadly protective vaccines.
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