The post-SCF quantum chemistry characteristics of inter- and intra-strand stacking interactions in d(CpG) and d(GpC) steps found in B-DNA, A-DNA and Z-DNA crystals.

The energies of intra- and inter-strand stacking interactions in model d(GpC) and d(CpG) two-base-pair steps were estimated by MP2/aug-cc-pVDZ single point calculations corrected for basis superposition errors. The stacked two-nucleobase pairs were constructed using experimental values of base pair and base step parameters taken from Nucleic Acid Database (http://ndbserver.rutgers.edu/). Three distinct polymorphic forms were analysed, namely A-, B- and Z-DNA. The applied methodology enables statistical analysis of structural and energetic diversities. The structural relationships between polymorphic forms are quite complex and depend on the sequence of pairs. The variability of parameters such as shift and tilt is almost the same irrespective of the polymorphic form and sequence of steps analysed. In contrast, shift and twist distributions easily discriminate all three polymorphic forms of DNA. Interestingly, despite significant structural diversities, the energies of the most frequent energy ranges are comparable irrespective of the polymorphic form and base sequence. There was observed compensation of inter- and intra-strand interactions, especially for d(GpC) and d(CpG) steps found in A- and B-DNA. Thus, among many other roles, these pairs act as a kind of energetic buffer, balancing the double helix.