Abstract
Crystallography provides unique information about the arrangement of water molecules near protein surfaces. Using a nonredundant set of 2818 protein crystal structures with a resolution of better than 1.8 Å, the extent and structure of the hydration shell of all 20 standard amino-acid residues were analyzed as function of the residue conformation, secondary structure and solvent accessibility. The results show how hydration depends on the amino-acid conformation and the environment in which it occurs. After conformational clustering of individual residues, the density distribution of water molecules was compiled and the preferred hydration sites were determined as maxima in the pseudo-electron-density representation of water distributions. Many hydration sites interact with both main-chain and side-chain amino-acid atoms, and several occurrences of hydration sites with less canonical contacts, such as carbon-donor hydrogen bonds, OH-π interactions and off-plane interactions with aromatic heteroatoms, are also reported. Information about the location and relative importance of the empirically determined preferred hydration sites in proteins has applications in improving the current methods of hydration-site prediction in molecular replacement, ab initio protein structure prediction and the set-up of molecular-dynamics simulations.
Highlights
Proteins function in an aqueous environment and are evolutionarily adapted to it
We investigated the dependence of the hydration of the 20 standard amino-acid residues on their solvent-accessible surface area (SASA), secondary-structure environment and side-chain rotameric state
We describe in greater detail the structure of the first hydration shell of five selected aminoacid residues (Asp, His, Thr, Trp and Tyr), together with the hydration of alanine as a model for the hydration of unhindered main chain
Summary
Water molecules represent an integral part of protein molecules, their structure, dynamics and function, and understanding of the relationship between the water environment and the polypeptide chain is essential. A range of experimental and computational methods have been used to elucidate the structure and dynamics of the water environment around biomolecules (Chalikian, 2008). The hydration layer around proteins has been shown to possess physical properties distinct from the bulk water environment; the exact parameters (such as the layer thickness and dynamic properties and the extent to which it is structured) are disputed and depend on the method applied and the properties observed (Halle, 2004; Zhong et al, 2011).
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