The post-SCF quantum chemistry characteristics of the guanine–guanine stacking B-DNA

Cysewski, Piotr; Czyżnikowska, Żaneta; Zaleśny, Robert; Czeleń, Przemysław

doi:10.1039/b718635e

Cited by 26 publications

(21 citation statements)

References 45 publications

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“…[47][48][49] This is definitely a viable approach for the highest resolution and carefully refined structures (such as those of B-DNA decamers), provided the experimental nucleobase geometries are overlaid by QM-optimized monomers. 50,51 However, a small experimental error in interbase positions (mainly incorrect values of interbase angles) leading to close interatomic contacts may introduce large errors in energy calculations.…”

Section: Methodsmentioning

confidence: 99%

“…On the other hand, MP2/aug-cc-pVDZ calculations, which give more negative (i.e., more stable) stacking energies than the MP2/6-31G*(0.25) method, can be considered as a reasonable compromise between accuracy and computational demands. 25,47,48 Comment on Comparison with Experiments. The calculations provide intrinsic stacking energies that correspond to the gas phase environment.…”

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confidence: 99%

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Comparison of Intrinsic Stacking Energies of Ten Unique Dinucleotide Steps in A-RNA and B-DNA Duplexes. Can We Determine Correct Order of Stability by Quantum-Chemical Calculations?

Svozil¹,

Hobza²,

Šponer³

2010

J. Phys. Chem. B

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High level ab initio methods have been used to study stacking interactions in ten unique base pair steps both in A-RNA and in B-DNA duplexes. The protocol for selection of geometries based on molecular dynamics (MD) simulations is proposed, and its suitability is demonstrated by comparison with stacking in steps at fiber diffraction geometries. It is shown that fiber diffraction geometries are not sufficiently accurate for interaction energy calculations. In addition, the protocol for selection of geometries based on MD simulations allows for the evaluation of the variability of the intrinsic stacking energies along the MD trajectories. The uncertainty in stacking energies (difference between the most and least stable geometry) due to the dynamical nature of systems can be, in some cases, as large as 3.0 kcal · mol, which is almost 50% of the actual sequence dependence of base stacking energies (the energy difference between the most and least stable sequences). Thus, assessing the relative magnitude of the gas phase stacking energy using a single geometry for each sequence is insufficient to obtain an unambiguous order of gas phase stacking energies in canonical double helices. Though the ordering of ten unique dinucleotide steps cannot be definitive, some general conclusions were drawn. The stacking energies of base pair steps in A-RNA are more evenly separated compared to B-DNA, and their ordering is less sensitive to the dynamics of the system compared to be B-DNA. The most stable step both in B-DNA and A-RNA is the CG/CG step that is well separated from the second most stable step GC/GC. Also the least stable step (the CC/GG step) is well separated from the rest of the structures. The calculations further show that B-DNA stacking is favorable only marginally (on average by 1.14 kcal · mol -1 per base pair step) over A-RNA stacking, and this difference vanishes after subtracting the stabilizing van der Waals effect of the thymine 5-methyl group that is absent in RNA. Basically, no correlation between the sequence dependence of gas phase stacking energies and the sequence dependence of ∆G°3 7 free energies used in nearest-neighbor models was found either for B-DNA or for A-RNA. This reflects the complexity of the balance of forces that are responsible for the sequence dependence of thermodynamics stability of nucleic acids, which masks the effect of the intrinsic interactions between the stacked base pairs.

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Section: Methodsmentioning

confidence: 99%

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confidence: 99%

Comparison of Intrinsic Stacking Energies of Ten Unique Dinucleotide Steps in A-RNA and B-DNA Duplexes. Can We Determine Correct Order of Stability by Quantum-Chemical Calculations?

Svozil¹,

Hobza²,

Šponer³

2010

J. Phys. Chem. B

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“…following sequence-dependent interactions: (a) hydrogenbonding: this can be intra-or inter-base pair and can involve ribose interaction in case of RNA, (b) p-stacking interactions between the base aromatic rings and (c) external effects comprising of metal ion interaction, hydration, etc., which are mostly nonspecific. [15][16][17][18][19][20][21] Earlier, there were attempts to understand how base stacking energy obtained from van der Waals (vdW) and electrostatic interactions correlates with experimental data. Even recent quantum mechanical calculations of optimized structures of base pair steps have tried to focus on the equal contributions of both these interactions.…”

Section: Introductionmentioning

confidence: 99%

Energy hyperspace for stacking interaction in AU/AU dinucleotide step: Dispersion‐corrected density functional theory study

et al. 2013

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Double helical structures of DNA and RNA are mostly determined by base pair stacking interactions, which give them the base sequence-directed features, such as small roll values for the purine-pyrimidine steps. Earlier attempts to characterize stacking interactions were mostly restricted to calculations on fiber diffraction geometries or optimized structure using ab initio calculations lacking variation in geometry to comment on rather unusual large roll values observed in AU/AU base pair step in crystal structures of RNA double helices. We have generated stacking energy hyperspace by modeling geometries with variations along the important degrees of freedom, roll, and slide, which were chosen via statistical analysis as maximally sequence dependent. Corresponding energy contours were constructed by several quantum chemical methods including dispersion corrections. This analysis established the most suitable methods for stacked base pair systems despite the limitation imparted by number of atom in a base pair step to employ very high level of theory. All the methods predict negative roll value and near-zero slide to be most favorable for the purine-pyrimidine steps, in agreement with Calladine's steric clash based rule. Successive base pairs in RNA are always linked by sugar-phosphate backbone with C3'-endo sugars and this demands C1'-C1' distance of about 5.4 Å along the chains. Consideration of an energy penalty term for deviation of C1'-C1' distance from the mean value, to the recent DFT-D functionals, specifically ωB97X-D appears to predict reliable energy contour for AU/AU step. Such distance-based penalty improves energy contours for the other purine-pyrimidine sequences also. © 2013 Wiley Periodicals, Inc. Biopolymers 101: 107-120, 2014.

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“…It is well established that dispersion component is the main source of stabilization of stacked nucleic acid bases. The analysis of the nature of interactions in base pairs, however, has been settled on quantitative ground only quite recently [23][24][25][26][27][28][29][30][31]. Hill and collaborators analyzed the importance of electrostatics for stabilization of DNA bases [24].…”

Section: Accepted M Manuscriptmentioning

confidence: 99%

Theoretical insights into the nature of intermolecular interactions in cytosine dimer

Czyżnikowska¹,

Zaleśny²

2009

Biophysical Chemistry

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In this study we discuss stacking interactions in cytosine dimer in conformations appearing in B-DNA crystals. The variational-perturbational scheme was applied for decomposition of the intermolecular interaction energy at the MP2 level of theory. The significant influence of the mutual orientation of cytosine monomers was observed not only on the total intermolecular interaction energy but also on its components: Different components of intermolecular interaction energy depend in different manner on parameters describing mutual orientation of cytosine monomers.

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The post-SCF quantum chemistry characteristics of the guanine–guanine stacking B-DNA

Cited by 26 publications

References 45 publications

Comparison of Intrinsic Stacking Energies of Ten Unique Dinucleotide Steps in A-RNA and B-DNA Duplexes. Can We Determine Correct Order of Stability by Quantum-Chemical Calculations?

Comparison of Intrinsic Stacking Energies of Ten Unique Dinucleotide Steps in A-RNA and B-DNA Duplexes. Can We Determine Correct Order of Stability by Quantum-Chemical Calculations?

Energy hyperspace for stacking interaction in AU/AU dinucleotide step: Dispersion‐corrected density functional theory study

Theoretical insights into the nature of intermolecular interactions in cytosine dimer

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