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Cellular processes are controlled by the thermodynamics of the underlying biomolecular interactions. Frequently, structural investigations use one monomeric binding partner, while ensemble measurements of binding affinities generally yield one affinity representative of a 1:1 interaction, despite the majority of the proteome consisting of oligomeric proteins. For example, viral entry and inhibition in SARS-CoV-2 involve a trimeric spike surface protein, a dimeric ACE2 cell surface receptor and dimeric antibodies. Here, we reveal that cooperativity correlates with infectivity and inhibition as opposed to 1:1 binding strength. We find that ACE2 oligomerises spike more strongly for more infectious variants, while exhibiting weaker 1:1 affinity. Furthermore, we find that antibodies use induced-oligomerisation both as a primary inhibition mechanism and to enhance the effects of receptor-site blocking. Our results reveal that naive affinity measurements are poor predictors of potency, and introduce a novel antibody-based inhibition mechanism for oligomeric targets. More generally, they point towards a much broader role of induced oligomerisation in controlling biomolecular interactions.

Type

Journal article

Journal

Proceedings of the National Academy of Sciences of the United States of America

Publisher

National Academy of Sciences

Publication Date

20/08/2024

Keywords

receptor oligomerisation, SARS-CoV-2, mass photometry, label-free single-molecule tracking, avidity-based neutralisation potency