Optimized Hydrogen Mass Repartitioning Scheme Combined
with Accurate Temperature/Pressure Evaluations for Thermodynamic and
Kinetic Properties of Biological Systems
In recent years, molecular dynamics
(MD) simulations with larger
time steps have been performed with the hydrogen-mass-repartitioning
(HMR) scheme, where the mass of each hydrogen atom is increased to
reduce high-frequency motion while the mass of a non-hydrogen atom
bonded to a hydrogen atom is decreased to keep the total molecular
mass unchanged. Here, we optimize the scaling factors in HMR and combine
them with previously developed accurate temperature/pressure evaluations.
The heterogeneous HMR scaling factors are useful to avoid the structural
instability of amino acid residues having a five- or six-membered
ring in MD simulations with larger time steps. It also reproduces
kinetic properties, namely translational and rotational diffusions,
if the HMR scaling factors are applied to only solute molecules. The
integration scheme is tested for biological systems that include soluble/membrane
proteins and lipid bilayers for about 200 μs MD simulations
in total and give consistent results in MD simulations with both a
small time step of 2.0 fs and a large, multiple time step integration
with time steps of 3.5 fs (for fast motions) and 7.0 fs (for slower
motions). We also confirm that the multiple time step integration
scheme used in this study provides more accurate energy conservations
than the RESPA/C1 and is comparable to the RESPA/C2 in NAMD. In summary,
the current integration scheme combining the optimized HMR with accurate
temperature/pressure evaluations can provide stable and reliable MD
trajectories with a larger time step, which are computationally more
than 2-fold efficient compared to the conventional methods.