Force-tuned avidity of spike variant-ACE2 interactions viewed on the single-molecule level.
Rong ZhuDaniel CanenaMateusz SikoraMiriam KlausbergerHannah SeferovicAhmad Reza MehdipourLisa HainElisabeth LaurentVanessa M MonteilGerald WirnsbergerRalph WienekeRobert TampéNikolaus F KienzlLukas MachAli MirazimiYoo Jin OhJosef M PenningerGerhard HummerPeter HinterdorferPublished in: Nature communications (2022)
Recent waves of COVID-19 correlate with the emergence of the Delta and the Omicron variant. We report that the Spike trimer acts as a highly dynamic molecular caliper, thereby forming up to three tight bonds through its RBDs with ACE2 expressed on the cell surface. The Spike of both Delta and Omicron (B.1.1.529) Variant enhance and markedly prolong viral attachment to the host cell receptor ACE2, as opposed to the early Wuhan-1 isolate. Delta Spike shows rapid binding of all three Spike RBDs to three different ACE2 molecules with considerably increased bond lifetime when compared to the reference strain, thereby significantly amplifying avidity. Intriguingly, Omicron (B.1.1.529) Spike displays less multivalent bindings to ACE2 molecules, yet with a ten time longer bond lifetime than Delta. Delta and Omicron (B.1.1.529) Spike variants enhance and prolong viral attachment to the host, which likely not only increases the rate of viral uptake, but also enhances the resistance of the variants against host-cell detachment by shear forces such as airflow, mucus or blood flow. We uncover distinct binding mechanisms and strategies at single-molecule resolution, employed by circulating SARS-CoV-2 variants to enhance infectivity and viral transmission.
Keyphrases
- single molecule
- sars cov
- angiotensin converting enzyme
- angiotensin ii
- blood flow
- atomic force microscopy
- living cells
- respiratory syndrome coronavirus
- coronavirus disease
- copy number
- cell surface
- cell therapy
- stem cells
- blood brain barrier
- dna methylation
- binding protein
- transcription factor
- transition metal
- quantum dots