Hydration structure and dynamics of B‐ and Z‐DNA in the presence of counterions via molecular dynamics simulations

Following our previous attempts at understanding the structural and dynamical properties of water and counterions hydrating nucleic acids, we have performed molecular dynamics simulations for B‐ and Z‐DNA. In these simulations, the nucleic acids were held rigid. In the case of B‐DNA, one turn of B‐DNA double helix was considered in the presence of 1500 water molecules and 20 counterions (K + ). The simulations were performed for 4.0 ps after equilibrating the system. For Z‐DNA, we considered one turn of the double helix in the presence of 1851 water molecules and 24 counterions (K + ). The simulations were carried out for 3.5 ps after equilibration. The average temperature of these simulations was ∼ 360 K for Z‐DNA and ∼ 345 K for B‐DNA. In these simulations the hydrogen atoms were explicitly taken into account. For both simulations, a fifth‐order predictor‐corrector was used for solving the translational equations of motion. The rotational motion of the water molecules was represented in terms of quaternion algebra and the rotational equations of motion were solved with a second‐order quaternion method using a sixth‐order predictor‐corrector method. A time step of 0.5 · 10 −15 s was used in these simulations. The structural and the dynamical properties of water solvating the counterions, and the phosphate groups of the DNA, were computed to understand the hydration structure. Diffusion coefficients and velocity correlation functions were calculated for both ions and the water molecules. The velocity correlation functions for the ions exhibit a caged behavior. The dipole correlation functions for the water molecules indicate that the water molecules close to the helix retain the memory of their initial orientations for longer periods of time than those away from the helix. During the time period of our simulation (3–4 ps) the ion probability distributions show a well‐defined pattern and suggest limited mobility for the ions, being close to the helix.