Abstract
Molecular simulations of large biological systems, such as viral capsids, remains a challenging task in soft matter research. On one hand, coarse-grained (CG) models attempt to make the description of the entire viral capsid disassembly feasible. On the other hand, the permanent development of novel molecular dynamics (MD) simulation approaches, like enhanced sampling methods, attempt to overcome the large time scales required for such simulations. Those methods have a potential for delivering molecular structures and properties of biological systems. Nonetheless, exploring the process on how a viral capsid disassembles by all-atom MD simulations has been rarely attempted. Here, we propose a methodology to analyze the disassembly process of viral capsids from a free energy perspective, through an efficient combination of dynamics using coarse-grained models and Poisson-Boltzmann simulations. In particular, we look at the effect of pH and charge of the genetic material inside the capsid, and compute the free energy of a disassembly trajectory precalculated using CG simulations with the SIRAH force field. We used our multiscale approach on the Triatoma virus (TrV) as a test case, and find that even though an alkaline environment enhances the stability of the capsid, the resulting deprotonation of the genetic material generates a Coulomb-type electrostatic repulsion that triggers disassembly.
Highlights
Numerous virus structures are comprised of smaller proteincoat pieces which form a capsid
There, the authors employ multiscale simulations to obtain a structural changes on the viral capsids triggered by a Grotthuss-like mechanism for proton channeling, which is used as a hypothesis on how to simulate the electrostatic repulsion inside the capsid and deliver CG
We studied the effect of pH and charge of the genetic material, and how free energy changes as the capsid disassembles
Summary
Numerous virus structures are comprised of smaller proteincoat pieces which form a capsid Such macromolecular structures have, at least, two crucial roles to play, namely: the packaging of the viral genome and the transport of such genetic material throughout the human body. Viral capsid disassembly[9] involves the dissociation of protein-coats either for the release of the nucleic acid material during the viral replication process or to regulate protein dissociation by the ionic concentration In this regard, coarse-grained models[10] have been derived from thermodynamic principles, e.g., the SIRAH,[11,12] PRIMO,[13] MARTINI,[14,15] and UNRES force fields.[16] Primarily, those models are designed to allow the description of biological systems by taking into account the typical length and time scales associated with molecular processes in biology
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