Nucleic acid quadruplexes based on 8-halo-9-deazaxanthines: Energetics and non-covalent interactions in quadruplex stems

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Authors

YURENKO Yevgen NOVOTNÝ Jan MITORAJ Mariusz P. SKLENÁŘ Vladimír MICHALAK Artur MAREK Radek

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

Citation
Web DOI: 10.1021/ct5007554
Doi http://dx.doi.org/10.1021/ct5007554
Field Physical chemistry and theoretical chemistry
Keywords nucleic acid; quadruplex; xanthine; halogen; energy of formation; hydrogen bonding; stacking; ion coordination
Attached files
Description Structural and energetic features of artificial DNA quadruplexes consisting of base tetrads and their stacks with Na+/K+ ion(s) inside the central pore and incorporating halogenated derivatives of xanthine: 8-fluoro-9-deazaxanthine (FdaX), 8-chloro-9-deazaxanthine (CldaX), 8-bromo-9-deazaxanthine (BrdaX), or 8-iodo-9-deazaxanthine (IdaX), have been investigated by modern state-of-the-art computational tools. The DNA (or RNA) quadruplex models based on 8-halo-9-deazaxanthines are predicted to be more stable relative to those with natural xanthine due to the increased stabilizing contributions coming from all three main types of weak interactions (H-bonding, stacking, and ion coordination). Methods for analyzing the electron density are used to understand the nature of forces determining the stability of the system and to gain a predictive potential. Quadruplex systems incorporating polarizable halogen atoms (chlorine, bromine, or iodine) benefit significantly from the stabilizing stacking between the individual tetrads due to an increased dispersion contribution as compared to xanthine and guanine, natural references used. Ion coordination induces a significant rearrangement of electron density in the quadruplex stem as visualized by electron deformation density (EDD) and analyzed by ETS-NOCV and Voronoi charges. Na+ induces larger electron polarization from the quadruplex towards the ion, whereas K+ has higher propensity to electron sharing (identified by QTAIM delocalization index). We expect that our results will contribute to the development of novel strategies to further modify and analyze the natural G-quadruplex core.
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