1. Electronic Structures of LNA Phosphorothioate Oligonucleotides
- Author
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Troels Koch, Cy A. Stein, Henrik Ørum, Henrik Bohr, Henrik Frydenlund Hansen, and Irene Shim
- Subjects
0301 basic medicine ,Materials science ,LNA phosphorothioate ,Electronic structure ,diastereoisomers ,DNA/LNA oligonucleotide ,Diastereoisomers ,03 medical and health sciences ,Computational chemistry ,Drug Discovery ,Molecule ,Physics::Chemical Physics ,Locked nucleic acid ,Quantum ,Hartree-Fock calculations ,Topology (chemistry) ,Quantitative Biology::Biomolecules ,Phosphorothioate Oligonucleotides ,Oligonucleotide ,lcsh:RM1-950 ,iso-potential surface ,Anion chromatograms ,Quantitative Biology::Genomics ,Iso-potential surface ,lcsh:Therapeutics. Pharmacology ,030104 developmental biology ,Molecular Medicine ,Original Article ,Chirality (chemistry) ,anion chromatograms - Abstract
Important oligonucleotides in anti-sense research have been investigated in silico and experimentally. This involves quantum mechanical (QM) calculations and chromatography experiments on locked nucleic acid (LNA) phosphorothioate (PS) oligonucleotides. iso-potential electrostatic surfaces are essential in this study and have been calculated from the wave functions derived from the QM calculations that provide binding information and other properties of these molecules. The QM calculations give details of the electronic structures in terms of e.g., energy and bonding, which make them distinguish or differentiate between the individual PS diastereoisomers determined by the position of sulfur atoms. Rules are derived from the electronic calculations of these molecules and include the effects of the phosphorothioate chirality and formation of electrostatic potential surfaces. Physical and electrochemical descriptors of the PS oligonucleotides are compared to the experiments in which chiral states on these molecules can be distinguished. The calculations demonstrate that electronic structure, electrostatic potential, and topology are highly sensitive to single PS configuration changes and can give a lead to understanding the activity of the molecules., Graphical Abstract
- Published
- 2017
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