M Prévost1. 1. Ingénierie Biomoléculaire, Université Libre de Bruxelles, CP 165, Av.F. Roosevelt, B-1050, Bruxelles, Belgium. mprevost@ulb.ac.be
Abstract
BACKGROUND: NMR experiments show that even water molecules that are well ordered in a crystal structure exchange with the external solvent. Despite crucial progress on the understanding of the exchange of crystal-buried water molecules, the detailed pathways followed by a water molecule to escape from or penetrate into the protein interior are unknown. RESULTS: The exchange of a crystal water molecule buried in the low-density lipoprotein receptor-binding domain of human apolipoprotein E with a water molecule from the external solvent was detected and monitored in a molecular dynamics simulation. This simulation shows that the escape of the crystal water molecule from the protein interior and the penetration of the water molecule from the bulk occur by a single-pathway mechanism involving conformational fluctuations of arginine and tryptophan sidechains. Along the pathway the exchanging water molecule interacts specifically with protein atoms by way of a varying pattern of hydrogen bonds. CONCLUSIONS: The exchange pathway revealed by the molecular dynamics trajectory suggests a mechanism by which hydrogen bonds work in relay to permit either the penetration or the expulsion of a water molecule. This result may have important implications not only on the process of water exchange but also to probe ligand binding to proteins.
BACKGROUND: NMR experiments show that even water molecules that are well ordered in a crystal structure exchange with the external solvent. Despite crucial progress on the understanding of the exchange of crystal-buried water molecules, the detailed pathways followed by a water molecule to escape from or penetrate into the protein interior are unknown. RESULTS: The exchange of a crystal water molecule buried in the low-density lipoprotein receptor-binding domain of humanapolipoprotein E with a water molecule from the external solvent was detected and monitored in a molecular dynamics simulation. This simulation shows that the escape of the crystal water molecule from the protein interior and the penetration of the water molecule from the bulk occur by a single-pathway mechanism involving conformational fluctuations of arginine and tryptophan sidechains. Along the pathway the exchanging water molecule interacts specifically with protein atoms by way of a varying pattern of hydrogen bonds. CONCLUSIONS: The exchange pathway revealed by the molecular dynamics trajectory suggests a mechanism by which hydrogen bonds work in relay to permit either the penetration or the expulsion of a water molecule. This result may have important implications not only on the process of water exchange but also to probe ligand binding to proteins.