Publication date: Sep 08, 2025
The Envelope protein (E protein) of SARS-CoVs 1 and 2 has been implicated in the viral budding process and maintaining the spherical shape of the virus, but direct evidence linking the protein to long-range membrane deformation is still lacking. Computational predictions from molecular simulation have offered conflicting results, some showing long-range E-induced membrane curvature and others showing only local deformations. In the present study, we determine the mechanism driving these deformations by modulating the degree of hydrophobic mismatch between protein and membrane. We observe that certain barostat and restraint settings, common in coarse-grained MD simulations, can prevent equilibration of the membrane area. Our results indicate that the E protein does not induce long-range curvature, but does exhibit severe local deformations that are exacerbated by hydrophobic mismatch. These deformations occur in conjunction with local leaflet thickness asymmetry, suggesting asymmetry and curvature couple to reduce the free energy cost of a deformed membrane.
| Concepts | Keywords |
|---|---|
| Biophys | E protein |
| Couples | Elastic theory |
| Driving | Lipid-protein interactions |
| Spherical | Membrane asymmetry |
| Virus | SARS-coV-1 |
| SARS-coV-2 |
Semantics
| Type | Source | Name |
|---|---|---|
| disease | IDO | protein |
| disease | IDO | process |