DFT study of polymorphism of the DNA double helix at the level of dinucleoside monophosphates

We apply DFT calculations to deoxydinucleoside monophosphates (dDMPs) which represent minimal fragments of the DNA chain to study the molecular basis of stability of the DNA duplex, the origin of its polymorphism and conformational heterogeneity. In this work, we continue our previous studies of dDMPs where we detected internal energy minima corresponding to the “classical” B conformation (BI‐form), which is the dominant form in the crystals of oligonucleotide duplexes. We obtained BI local energy minima for all existing base sequences of dDMPs. In the present study, we extend our analysis to other families of DNA conformations, successfully identifying A, BI, and BII energy minima for all dDMP sequences. These conformations demonstrate distinct differences in sugar ring puckering, but similar sequence‐dependent base arrangements. Internal energies of BI and BII conformers are close to each other for nearly all the base sequences. The dGpdG, dTpdG, and dCpdA dDMPs slightly favor the BII conformation, which agrees with these sequences being more frequently experimentally encountered in the BII form. We have found BII‐like structures of dDMPs for the base sequences both existing in crystals in BII conformation and those not yet encountered in crystals till now. On the other hand, we failed to obtain dDMP energy minima corresponding to the Z family of DNA conformations, thus giving us the ground to conclude that these conformations are stabilized in both crystals and solutions by external factors, presumably by interactions with various components of the media. Overall the accumulated computational data demonstrate that the A, BI, and BII families of DNA conformations originate from the corresponding local energy minimum conformations of dDMPs, thus determining structural stability of a single DNA strand during the processes of unwinding and rewinding of DNA. © 2010 Wiley Periodicals, Inc. Int J Quantum Chem 110:2548–2559, 2010     

Monte Carlo study of three-dimensional organization of water molecules around DNA fragments

Interactions with water molecules are important for the stabilization of three-dimensional structures of nucleic acids and for their functioning. The first hydration shells of macromolecules can be considered as structural parts of nucleic acid. We performed a Monte Carlo study of systems containing a nucleic acid base or base pair with water molecules using improved potential functions. These potential functions enable experimental data on both single base–single water interaction energies and enthalpies of base hydration to be reproduced. Hydration shell structures of base pairs are dependent on the pair geometry. Structural elements of hydration shells can contribute to the pair stability and hence to the probability of mispair formation during nucleic acid biosynthesis. The distribution of water molecules around bases and base pairs is essentially nonhomogeneous.From the Proceedings of the 28th Congreso de Químicos Teóricos de Expresión Latina (QUITEL 2002).     

Caffeine interactions with nucleic acids. Molecular mechanics calculations of model systems for explanation of mechanisms of biological actions

To understand the molecular mechanisms of the influence of caffeine (CAF) on DNA functioning, molecular mechanics calculations of the interaction energy of CAF with nucleic acid bases and base pairs have been performed. The calculations reveal three types of mutual CAF–base (and CAF–base pair) arrangements corresponding to minima of the interaction energy. Besides well-known stacking mutual positions of the molecules, two other types of arrangements are revealed and studied. One of these arrangements corresponds to the nearly in-plane position of CAF and base (or base pair) and the formation of a single hydrogen bond. Another type of minimum corresponds to nearly perpendicular arrangements of the molecular planes and the formation of intermolecular hydrogen bonds. These two arrangements are possible both for individual nucleic acid monomers and for DNA duplexes. The calculations suggest the molecular mechanisms of the influence of CAF on DNA interactions with other biologically active molecules.From the Proceedings of the 28th Congreso de Químicos Teóricos de Expresión Latina (QUITEL 20002).