Omicron BA.2 specifically evades broad sarbecovirus neutralizing antibodies

Yunlong Cao(Peking University), Ayijiang Yisimayi(Peking University), Fanchong Jian(Peking University), Tianhe Xiao(Peking University), Weiliang Song(Peking University), Jing Wang(Peking University), Shuo Du(Peking University), Zhiying Zhang(Peking University), Pulan Liu(Peking University), Xiaohua Hao(Capital Medical University), Qianqian Li(National Institutes for Food and Drug Control), Xiaosu Chen(Nankai University), Lei Wang(Chinese Academy of Sciences), Peng Wang, Ran An(Peking University), Yao Wang(National Institutes for Food and Drug Control), Jing Wang(Peking University), Peng Yang(Chinese Academy of Sciences), Haiyan Sun, Lijuan Zhao, Wen Zhang(Capital Medical University), Dong Zhao(Capital Medical University), Jiang Zheng, Lingling Yu, Can Li, Na Zhang, Rui Wang, Xiao Niu(Peking University), Sijie Yang(Peking University), Xuetao Song, Linlin Zheng, Zhiqiang Li(Peking University), Qingqing Gu, Fei Shao, Weijin Huang(National Institutes for Food and Drug Control), Youchun Wang(National Institutes for Food and Drug Control), Zhongyang Shen(Nankai University), Xiangxi Wang(Chinese Academy of Sciences), Ronghua Jin(Capital Medical University), Junyu Xiao(Peking University), X. Sunney Xie(Peking University)
bioRxiv (Cold Spring Harbor Laboratory)
February 7, 2022
10.1101/2022.02.07.479349
Cited by 14Open Access
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Abstract

Abstract Omicron sub-lineage BA.2 has rapidly surged globally, accounting for over 60% of recent SARS-CoV-2 infections. Newly acquired RBD mutations and high transmission advantage over BA.1 urge the investigation of BA.2’s immune evasion capability. Here, we show that BA.2 causes strong neutralization resistance, comparable to BA.1, in vaccinated individuals’ plasma. However, BA.2 displays more severe antibody evasion in BA.1 convalescents, and most prominently, in vaccinated SARS convalescents’ plasma, suggesting a substantial antigenicity difference between BA.2 and BA.1. To specify, we determined the escaping mutation profiles 1,2 of 714 SARS-CoV-2 RBD neutralizing antibodies, including 241 broad sarbecovirus neutralizing antibodies isolated from SARS convalescents, and measured their neutralization efficacy against BA.1, BA.1.1, BA.2. Importantly, BA.2 specifically induces large-scale escape of BA.1/BA.1.1-effective broad sarbecovirus neutralizing antibodies via novel mutations T376A, D405N, and R408S. These sites were highly conserved across sarbecoviruses, suggesting that Omicron BA.2 arose from immune pressure selection instead of zoonotic spillover. Moreover, BA.2 reduces the efficacy of S309 (Sotrovimab) 3,4 and broad sarbecovirus neutralizing antibodies targeting the similar epitope region, including BD55-5840. Structural comparisons of BD55-5840 in complexes with BA.1 and BA.2 spike suggest that BA.2 could hinder antibody binding through S371F-induced N343-glycan displacement. Intriguingly, the absence of G446S mutation in BA.2 enabled a proportion of 440-449 linear epitope targeting antibodies to retain neutralizing efficacy, including COV2-2130 (Cilgavimab) 5 . Together, we showed that BA.2 exhibits distinct antigenicity compared to BA.1 and provided a comprehensive profile of SARS-CoV-2 antibody escaping mutations. Our study offers critical insights into the humoral immune evading mechanism of current and future variants.

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