Abstract
Proteins accomplish their physiological functions with remarkably organized dynamic transitions among a hierarchical network of conformational substates. Despite the essential contribution of water molecules in shaping functionally important protein dynamics, their exact role is still controversial. Water molecules were reported either as mediators that facilitate or as masters that slave protein dynamics. Since dynamic behaviour of a given protein is ultimately determined by the underlying energy landscape, we systematically analysed protein self energies and protein-water interaction energies obtained from extensive molecular dynamics simulation trajectories of barstar. We found that protein-water interaction energy plays the dominant role when compared with protein self energy, and these two energy terms on average have negative correlation that increases with increasingly longer time scales ranging from 10 femtoseconds to 100 nanoseconds. Water molecules effectively roughen potential energy surface of proteins in the majority part of observed conformational space and smooth in the remaining part. These findings support a scenario wherein water on average slave protein conformational dynamics but facilitate a fraction of transitions among different conformational substates, and reconcile the controversy on the facilitating and slaving roles of water molecules in protein conformational dynamics.
Highlights
Protein dynamics is critical for their functions [1,2,3,4] and evolvability [5], and is to a great extent determined by the roughness of their potential energy surface (PES)
By systematically analysing the time series of relevant energy terms (protein self energy (Ep), protein-water interaction energy (Ep{w) and their sum (Etot)) obtained from molecular dynamics (MD) trajectories, we found that while the negative correlation between Ep and Ep{w in most parts of conformational space provides possibility for PES smoothing, the dominance of sEp{w over sEp (s stands for standard deviation) resulting in a rougher PES on average, especially for picoseconds and longer time scales
Since deciphering roles of water molecules in protein dynamics is the goal of this study, we focus our attention on Ep and protein-water interaction energy (Ep{w)
Summary
Protein dynamics is critical for their functions [1,2,3,4] and evolvability [5], and is to a great extent determined by the roughness of their potential energy surface (PES). Solvents play an indispensable role in shaping dynamic behaviour of proteins through molecular interactions that contribute to protein PES. It is well known that, due to the hierarchical nature of PES [6], conformational dynamics of native proteins is hierarchical and occurs on many different time scales corresponding to different types of molecular motions, including bond stretch and bending motions on femtoseconds, rotations of small groups (e.g. methyl) on picoseconds, side chain and backbone dihedral rotations on subnanoseconds to microseconds, and major domain motions up to multiple milliseconds. It is likely that water molecules play different roles in the above mentioned various type of dynamic processes. Two lines of evidences that have been presented by many experimental [14,15,16,17,18,19,20] and computational [21,22,23,24,25,26,27] reports supporting either mediating or slaving roles of water molecules are briefly summarized below
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