Structure and the energy of base pairing in non-natural bases of nucleic acids: the azaguanine–cytosine and azaadenine–thymine base pairs

## Abstract __A complete scan of the potential and free‐energy surfaces of monohydrated and dihydrated guanine⋅⋅⋅cytosine and 9‐methylguanine⋅⋅⋅1‐methylcytosine base pairs was realized by the molecular dynamics/quenching technique using the force field of Cornell et al. implemented in the AMBER7 pr

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Gradient-corrected density functional computations with triplezeta-type basis sets were performed to determine the preferred protonation site and the absolute gas-phase proton affinities of the most stable tautomer of the Ž . Ž . Ž . Ž . DNA bases thymine T , cytosine C , adenine A , and guanine G .

Ab initio quantum chemical studies at the HF and MP2 levels with the 6-31G U basis set were performed for H-bonded isocytosine᎐cytosine standard Ž . Watson᎐Crick base pairs denoted as iCC1 in the gas phase and in a water solution. Full geometry optimizations at the HF level without any constraints o

We compare the electrostatic potential surrounding several natural and synthetic nucleic acid bases calculated using an atom-centered multiple expansion (ACME) derived from integration of the charge distribution with that from potentialderived charges (PDCs) obtained using the CHELPG procedure. When