Base Pair Fraying in Molecular Dynamics Simulations of DNA and RNA

• Authors: ZGARBOVÁ Marie; OTYEPKA Michal; ŠPONER Jiří; LANKAŠ Filip; JUREČKA Petr
• Year of publication: 2014
• Type: Article in Periodical
• Magazine / Source: Journal of Chemical Theory and Computation
• MU Faculty or unit: Central European Institute of Technology
• Web: http://pubs.acs.org/doi/abs/10.1021/ct500120v
• Doi: http://dx.doi.org/10.1021/ct500120v
• Field: Physical chemistry and theoretical chemistry
• Keywords: QUANTUM-CHEMICAL COMPUTATIONS; NUCLEIC-ACID STRUCTURES; AMBER FORCE-FIELD; B-DNA; THERMODYNAMIC PARAMETERS; PROTON-EXCHANGE; QUADRUPLEX DNA; IMINO PROTON; DODECAMER; SEQUENCE
• Description: Terminal base pairs of DNA and RNA molecules in solution are known to undergo frequent transient opening events (fraying). Accurate modeling of this process is important because of its involvement in nucleic acid end recognition and enzymatic catalysis. In this article, we describe fraying in molecular dynamics simulations with the ff99bsc0, ff99bsc0 chi(OL3), and ff99bsc0 chi(OL4) force fields, both for DNA and RNA molecules. Comparison with the experiment showed that while some features of fraying are consistent with the available data, others indicate potential problems with the force field description. In particular, multiple noncanonical structures are formed at the ends of the DNA and RNA duplexes. Among them are tWC/sugar edge pair, C-H edge/Watson-Crick pair, and stacked geometries, in which the terminal bases are stacked above each other. These structures usually appear within the first tens to hundreds of nanoseconds and substantially limit the usefulness of the remaining part of the simulation due to geometry distortions that are transferred to several neighboring base pairs ("end effects"). We show that stability of the noncanonical structures in ff99bsc0 may be partly linked to inaccurate glycosidic (chi) torsion potentials that overstabilize the syn region and allow for rapid anti to syn transitions. The RNA refined glycosidic torsion potential chi(OL3) provides an improved description and substantially more stable MD simulations of RNA molecules. In the case of DNA, the chi(OL4) correction gives only partial improvement. None of the tested force fields provide a satisfactory description of the terminal regions, indicating that further improvement is needed to achieve realistic modeling of fraying in DNA and RNA molecules.