核心概念
Animal sarbecoviruses can infect human cells through ACE2-dependent and ACE2-independent pathways, with the latter pathway reducing susceptibility to antibody-mediated neutralization.
摘要
The study examines the determinants that govern the ability of animal sarbecoviruses to infect human cells and the implications for antibody-mediated neutralization. Key findings include:
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Raccoon dog ACE2 exhibits the broadest receptor activity for diverse animal sarbecoviruses, suggesting raccoon dogs could serve as potential intermediate hosts or reservoirs.
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The receptor binding domain (RBD) is a key determinant controlling whether sarbecovirus entry into human cells is ACE2-dependent or ACE2-independent and trypsin-dependent.
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Several type II transmembrane serine proteases (TTSPs), including TMPRSS11A and TMPRSS11D, can cleave and activate sarbecovirus S proteins for ACE2-independent entry, potentially facilitating viral spread in the respiratory tract.
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Insertion of a multibasic cleavage site into the S protein increases lung cell entry for most sarbecoviruses, but does not enable trypsin-independent entry for the Rs4081 and Rs4237 S proteins.
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Antibodies induced by quadruple COVID-19 vaccination robustly neutralize entry driven by diverse sarbecovirus S proteins. However, usage of the ACE2-independent, trypsin-dependent entry pathway reduces susceptibility to antibody-mediated neutralization.
統計資料
The study reports the following key metrics and figures:
Binding of soluble human ACE2 to cells expressing different sarbecovirus S proteins (Figure 2A)
Receptor activity of ACE2 orthologues from different animal species for entry driven by sarbecovirus S proteins (Figure 2B)
Efficiency of sarbecovirus S protein-driven entry into various human and animal cell lines, with and without trypsin treatment (Figure 3A)
Concentration-dependent cleavage of sarbecovirus S proteins by trypsin (Figure 4A)
Concentration-dependent effects of trypsin on sarbecovirus S protein-driven cell entry (Figure 4B)
Cleavage of sarbecovirus S proteins by different proteases (Figure 5A, 5E)
Effects of protease expression on sarbecovirus S protein-driven cell entry (Figure 5B, 5D, 5F)
Impact of inserting a multibasic cleavage site into sarbecovirus S proteins on entry into 293T-ACE2 and Calu-3-ACE2 cells (Figure 6C)
Cell entry driven by chimeric SARS-1-S and Rs4081 S proteins, with and without trypsin treatment (Figure 7D)
Neutralization of sarbecovirus S protein-driven entry by the pan-sarbecovirus antibody S2H97, with and without trypsin treatment (Figure 8)
Neutralization of sarbecovirus S protein-driven entry by antibodies from COVID-19 convalescent, double-vaccinated, triple-vaccinated, and quadruple-vaccinated individuals (Figure 9A)
Impact of trypsin treatment on neutralization of sarbecovirus S protein-driven entry by antibodies from triple-vaccinated individuals (Figure 9B)
引述
"Raccoon dog ACE2 supported entry driven by all tested clade 1 and 3 sarbecovirus S proteins with at least the same or, for several S proteins, even higher efficiency than human ACE2."
"Several TMPRSS2-related cellular proteases but not the insertion of a multibasic cleavage site into the S protein allowed for ACE2-independent entry in the absence of trypsin and may support viral spread in the respiratory tract."
"Antibodies induced upon quadruple COVID-19 vaccination robustly neutralized entry driven by all S proteins studied and might thus install appreciable protection against zoonotic animal sarbecoviruses."