Abstract
There is significant experimental evidence for bound water in collagen and related polymers. (Pro-Pro-Gly)10, {(PPG)10} is a polymer that forms a collagen-like triple-helical structure in aqueous solution. Like collagen, (PPG)10 adopts a structure in which side chains are mostly exposed to solvent, and the backbone polar groups are limited in their ability to form hydrogen bonds with each other. (PPG)10, like collagen, also has many of its backbone polar groups in positions that inhibit complete solvation in aqueous solution; thus the necessity of bound waters for stabilization of the structure. We have constructed a model for bound waters in (PPG)10, based on an examination of the geometry and steric environment of the backbone polar groups. As will become clear, the number of bound waters is determined by the geometry of the backbone carbonyl groups and the steric crowding surrounding them. In this model, each water forms one hydrogen bond with each of two backbone carbonyls from a glycine and a proline in different monomer chains, thus bridging the two carbonyls. The carbonyls in question are quite sterically crowded by neighboring (PPG)10 atoms and would not be likely to experience complete solvation by bulk solvent in aqueous solution. The bound waters are therefore likely to be present even in solution, since otherwise the unsatisfied hydrogen-bonding potential of the carbonyls would destabilize the structure. Other carbonyls also are sterically crowded and possibly prevented from experiencing full solvation, but are not in a favorable geometry for such bridging hydrogen bonds. The intra- and inter-chain interactions found in a previous computational study of (PPG)10 without bound waters are not disrupted by the addition of waters.
Published Version
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