The inherent flexibility of receptor binding domains in SARS-CoV-2 spike protein.
Hisham M DokainishSuyong ReTakaharu MoriChigusa KobayashiJaewoon JungYuji SugitaPublished in: eLife (2022)
Spike (S) protein is the primary antigenic target for neutralization and vaccine development for the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). It decorates the virus surface and undergoes large motions of its receptor binding domains (RBDs) to enter the host cell. Here, we observe Down, one-Up, one-Open, and two-Up-like structures in enhanced molecular dynamics simulations, and characterize the transition pathways via inter-domain interactions. Transient salt-bridges between RBD A and RBD C and the interaction with glycan at N343 B support RBD A motions from Down to one-Up. Reduced interactions between RBD A and RBD B in one-Up induce RBD B motions toward two-Up. The simulations overall agree with cryo-electron microscopy structure distributions and FRET experiments and provide hidden functional structures, namely, intermediates along Down-to-one-Up transition with druggable cryptic pockets as well as one-Open with a maximum exposed RBD. The inherent flexibility of S-protein thus provides essential information for antiviral drug rational design or vaccine development.
Keyphrases
- sars cov
- respiratory syndrome coronavirus
- molecular dynamics simulations
- binding protein
- electron microscopy
- high resolution
- minimally invasive
- coronavirus disease
- molecular docking
- single molecule
- stem cells
- molecular dynamics
- cell therapy
- dna binding
- mass spectrometry
- electronic health record
- health information
- cerebral ischemia
- social media
- blood brain barrier
- living cells