posted on 2022-06-06, 21:04authored byAria Gheeraert, Laurent Vuillon, Laurent Chaloin, Olivier Moncorgé, Thibaut Very, Serge Perez, Vincent Leroux, Isaure Chauvot de Beauchêne, Dominique Mias-Lucquin, Marie-Dominique Devignes, Ivan Rivalta, Bernard Maigret
Emerging SARS-CoV-2
variants raise concerns about our ability to
withstand the Covid-19 pandemic, and therefore, understanding mechanistic
differences of those variants is crucial. In this study, we investigate
disparities between the SARS-CoV-2 wild type and five variants that
emerged in late 2020, focusing on the structure and dynamics of the
spike protein interface with the human angiotensin-converting enzyme
2 (ACE2) receptor, by using crystallographic structures and extended
analysis of microsecond molecular dynamics simulations. Dihedral angle
principal component analysis (PCA) showed the strong similarities
in the spike receptor binding domain (RBD) dynamics of the Alpha,
Beta, Gamma, and Delta variants, in contrast with those of WT and
Epsilon. Dynamical perturbation networks and contact PCA identified
the peculiar interface dynamics of the Delta variant, which cannot
be directly imputable to its specific L452R and T478K mutations since
those residues are not in direct contact with the human ACE2 receptor.
Our outcome shows that in the Delta variant the L452R and T478K mutations
act synergistically on neighboring residues to provoke drastic changes
in the spike/ACE2 interface; thus a singular mechanism of action eventually
explains why it dominated over preceding variants.