AI Article Synopsis
- This review highlights recent advancements in quantum chemical calculations focused on the base-stacking forces in nucleic acids, emphasizing the complexity of gas-phase base-stacking energies compared to their roles in nucleic acids.
- The authors discuss various methods for studying base stacking, challenges in aligning stacking calculations with gas phase experiments, and the interplay between quantum mechanics and force field descriptions.
- They also analyze recent high-accuracy quantum mechanical calculations and explore future directions for computational studies of base stacking in nucleic acids.
Article Abstract
This review summarises recent advances in quantum chemical calculations of base-stacking forces in nucleic acids. We explain in detail the very complex relationship between the gas-phase base-stacking energies, as revealed by quantum chemical (QM) calculations, and the highly variable roles of these interactions in nucleic acids. This issue is rarely discussed in quantum chemical and physical chemistry literature. We further extensively discuss methods that are available for base-stacking studies, complexity of comparison of stacking calculations with gas phase experiments, balance of forces in stacked complexes of nucleic acid bases, and the relation between QM and force field descriptions. We also review all recent calculations on base-stacking systems, including details analysis of the B-DNA stacking. Specific attention is paid to the highest accuracy QM calculations, to the decomposition of the interactions, and development of dispersion-balanced DFT methods. Future prospects of computational studies of base stacking are discussed.
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| http://dx.doi.org/10.1039/b719370j | DOI Listing |
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