Abstract
Hydrogen bonds have been accredited with a major role historically, in the formation and stabilization of biomolecular structures. The formation of hydrogen bonds at protein-DNA interfaces in aqueous medium involves not only favorable interactions of the donor and acceptor functional groups but also a loss of interactions between these groups with the solvent water. We have investigated the energetics of about 500 potential hydrogen bonds occuring at protein-DNA interfaces incorporating some recent improvements in biomolecular force fields and solvation treatments. We present here results of our assessment of hydrogen bond contributions to the overall standard free energy of formation of protein-DNA complexes obtained with the generalized Born model and finite difference Poisson- Boltzmann methodology for solvation in conjunction with AMBER force field. Our results support the emerging view on the role of electrostatics in general and that of hydrogen bonds in particular which is that hydrogen bonds do not drive protein-DNA complex formation by virtue of the unfavourable cost of the electrostatics of desolvation. They however, act to stabilize the complex once it is formed.
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