Yujie Wu

Flexible simple point-charge water model with improved liquid-state properties

In order to introduce flexibility into the simple point-charge (SPC) water model, the impact of the intramolecular degrees of freedom on liquid properties was systematically studied in this work as a function of many possible parameter sets. It was found that the diffusion constant is extremely sensitive to the equilibrium bond length and that this effect is mainly due to the strength of intermolecular hydrogen bonds. The static dielectric constant was found to be very sensitive to the equilibrium bond angle via the distribution of intermolecular angles in the liquid: A larger bond angle will increase the angle formed by two molecular dipoles, which is particularly significant for the first solvation shell. This result is in agreement with the work of Hochtl et al. [J. Chem. Phys. 109, 4927 (1998)]. A new flexible simple point-charge water model was derived by optimizing bulk diffusion and dielectric constants to the experimental values via the equilibrium bond length and angle. Due to the large sensitivities, the parametrization only slightly perturbs the molecular geometry of the base SPC model. Extensive comparisons of thermodynamic, structural, and kinetic properties indicate that the new model is much improved over the standard SPC model and its overall performance is comparable to or even better than the extended SPC model.

A Computer Simulation Study of the Hydrated Proton in a Synthetic Proton Channel

Classical molecular dynamics simulations using the multistate empirical valence bond model for aqueous proton transport were performed to characterize the hydration structure of an excess proton inside a leucine-serine synthetic ion channel, LS2. For such a nonuniform pore size ion channel, it is found that the Zundel ion (H(5)O(2)(+)) solvation structure is generally more stable in narrow channel regions than in wider channel regions, which is in agreement with a recent study on idealized hydrophobic proton channels. However, considerable diversity in the relative stability of the Zundel to Eigen cation (H(9)O(4)(+)) was observed. Three of the five wide channel regions, one located at the channels center and the other two located near the channel mouths, are found to show extraordinary preference for the Eigen solvation structure. This implies that proton hopping is inhibited in these regions and therefore suggests that these regions may behave as barriers in the proton conducting pathway inside the channel. The proton solvation is also greatly influenced by the local molecular environment of the protein. In particular, the polar side chains of the Ser residues, which are intimately involved in the solvation structure, can greatly influence proton solvation. However, no preference of the influence by the various Ser side chains was found; they can either promote or prevent the formation of certain solvation structures.

Computational studies of proton transport through the M2 channel

The M2 ion channel is an essential component of the influenza A virus. This low‐pH gated channel has a high selectivity for protons. Evidence from various experimental data has indicated that the essential structure responsible for the channel is a parallel homo‐tetrameric α‐helix bundle having a left‐handed twist with each helix tilted with respect to the membrane normal. A backbone structure has been determined by solid state nuclear magnetic resonance (NMR). Though detailed structures for the side chains are not available yet, evidence has indicated that His37 and Trp41 in the α‐helix are implicated in the local molecular structure responsible for the selectivity and channel gate. More definitive conformations for the two residues were recently suggested based on the known backbone structure and recently obtained NMR data. While two competitive proton‐conductance mechanisms have been proposed, the actual proton‐conductance mechanism remains an unsolved problem. Computer simulations of an excess proton in the channel and computational studies of the His37/Trp41 conformations have provided insights into these structural and mechanism issues.