posted on 2023-03-29, 17:05authored byPetra Kührová, Vojtěch Mlýnský, Michal Otyepka, Jiří Šponer, Pavel Banáš
RNA molecules play a key role in countless biochemical
processes.
RNA interactions, which are of highly diverse nature, are determined
by the fact that RNA is a highly negatively charged polyelectrolyte,
which leads to intimate interactions with an ion atmosphere. Although
RNA molecules are formally single-stranded, canonical (Watson–Crick)
duplexes are key components of folded RNAs. A double-stranded (ds)
RNA is also important for the design of RNA-based nanostructures and
assemblies. Despite the fact that the description of canonical dsRNA
is considered the least problematic part of RNA modeling, the imperfect
shape and flexibility of dsRNA can lead to imbalances in the simulations
of larger RNAs and RNA-containing assemblies. We present a comprehensive
set of molecular dynamics (MD) simulations of four canonical A-RNA
duplexes. Our focus was directed toward the characterization of the
influence of varying ion concentrations and of the size of the solvation
box. We compared several water models and four RNA force fields. The
simulations showed that the A-RNA shape was most sensitive to the
RNA force field, with some force fields leading to a reduced inclination
of the A-RNA duplexes. The ions and water models played a minor role.
The effect of the box size was negligible, and even boxes with a small
fraction of the bulk solvent outside the RNA hydration sphere were
sufficient for the simulation of the dsRNA.