Abstract
The response of B12N12-nanocages towards DNA-nucleobases (adenine, guanine, cytosine, and thymine) is investigated using MP2 and DFT (M06-2X) levels of theory with the 6-311+G** basis set. Multiple BN-cage-nucleobase structures for each nucleobase emerged depending on the number of Lewis base centers of nucleobases. The main source of stability of these complexes is the N/O→B dative bond, where the N or O atom of nucleobases donates the lone-pair electron to one of the boron atoms of the nanocage. Nitrogen atoms of the BN-cage, adjacent to the B-site forming dative bond, act as a proton acceptor to form multiple (N-HN and N-HC) hydrogen bonds, where proton-donors NH and CH are part of nucleobases. MP2/6-311+G** adsorption energies are -43.1, -43.4 and -45.3 kcal mol-1 (B12N12-adenine), -37.1, -41.9 and -43.3 kcal mol-1 (B12N12-guanine), -41.3 and -43.4 (B12N12-cytosine), and -29.3 and -31.3 (B12N12-thymine). Similar adsorption energies were recorded for larger BN-fullerenes-nucleobases, namely B16N16 and B24N24. Changes in adsorption energies and structures of these nano-bio-hybrid materials in aqueous media are also discussed. Computationally cost-effective MP2 single point calculations at the M06-2X optimized geometries were found to be reliable in predicting adsorption energies. The effect of the BN-network and H-bonds on the adsorption process is assessed by comparing the results with simple BH3-nucleobase models. BSSE correction to the adsorption energy is not recommended.
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