SARS-CoV-2 simulations go exascale to predict dramatic spike opening and cryptic pockets across the proteome.
Maxwell I ZimmermanJustin R PorterMichael D WardSukrit SinghNeha VithaniArtur MellerUpasana L MallimadugulaCatherine E KuhnJonathan H BorowskyRafal P WiewioraMatthew F D HurleyAoife M HarbisonCarl A FogartyJoseph E CofflandElisa FaddaVincent A VoelzJohn D ChoderaGregory R BowmanPublished in: Nature chemistry (2021)
SARS-CoV-2 has intricate mechanisms for initiating infection, immune evasion/suppression and replication that depend on the structure and dynamics of its constituent proteins. Many protein structures have been solved, but far less is known about their relevant conformational changes. To address this challenge, over a million citizen scientists banded together through the Folding@home distributed computing project to create the first exascale computer and simulate 0.1 seconds of the viral proteome. Our adaptive sampling simulations predict dramatic opening of the apo spike complex, far beyond that seen experimentally, explaining and predicting the existence of 'cryptic' epitopes. Different spike variants modulate the probabilities of open versus closed structures, balancing receptor binding and immune evasion. We also discover dramatic conformational changes across the proteome, which reveal over 50 'cryptic' pockets that expand targeting options for the design of antivirals. All data and models are freely available online, providing a quantitative structural atlas.
Keyphrases
- sars cov
- molecular dynamics
- single molecule
- molecular dynamics simulations
- high resolution
- respiratory syndrome coronavirus
- single cell
- binding protein
- healthcare
- minimally invasive
- copy number
- genome wide
- health information
- social media
- quality improvement
- deep learning
- big data
- dna methylation
- protein protein
- gene expression
- mass spectrometry