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Abstract
Ribonucleic acid (RNA) molecules can adopt a variety of secondary and tertiary structures in solution, with stem-loops being one of the more common motifs. Here we present a systematic analysis of fifteen RNA stem-loop sequences simulated with molecular dynamics simulations in an implicit solvent environment. Analysis of RNA cluster ensembles showed that the stem-loop structures can generally adopt A-form RNA in the stem region. Loop structures are more sensitive and experimental structures could only be reproduced with modification of CH---O interactions in the force field, combined with an implicit solvent nonpolar correction to better model base stacking interactions. Accurately modeling RNA with current atomistic physics-based models remains challenging but the RNA systems studied herein may provide a useful benchmark set for testing other RNA modeling methods in the future.
Supplementary materials
Title
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Description
A description of training data for the implicit solvent base stacking calculations is described, including changes to the Lennard-Jones parameters. RMSD plots for chiOL3 and chiOL3-HR with GBnp simulations, RNA structural analysis for base pairing and sugar puckers shown in Figures 4, 5 and 6.
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