We are upgrading the repository! A content freeze is in effect until December 6, 2024. New submissions or changes to existing items will not be allowed during this period. All content already published will remain publicly available for searching and downloading. Updates will be posted in the Website Upgrade 2024 FAQ in the sidebar Help menu. Reach out to escholarship@umassmed.edu with any questions.
Hydration Structure and Dynamics of Inhibitor-Bound HIV-1 Protease
Document Type
Journal ArticlePublication Date
2018-05-08Keywords
Amino Acids, Peptides, and ProteinsBiochemistry
Chemical Actions and Uses
Chemistry
Enzymes and Coenzymes
Medicinal Chemistry and Pharmaceutics
Medicinal-Pharmaceutical Chemistry
Molecular Biology
Structural Biology
Metadata
Show full item recordAbstract
Water is essential in many biological processes, and the hydration structure plays a critical role in facilitating protein folding, dynamics, and ligand binding. A variety of biophysical spectroscopic techniques have been used to probe the water solvating proteins, often complemented with molecular dynamics (MD) simulations to resolve the spatial and dynamic features of the hydration shell, but comparing relative water structure is challenging. In this study 1 mus MD simulations were performed to identify and characterize hydration sites around HIV-1 protease bound to an inhibitor, darunavir (DRV). The water density, hydration site occupancy, extent and anisotropy of fluctuations, coordinated water molecules, and hydrogen bonds were characterized and compared to the properties of bulk water. The water density of the principal hydration shell was found to be higher than bulk, dependent on the topology and physiochemical identity of the biomolecular surface. The dynamics of water molecules occupying principal hydration sites was highly dependent on the number of water-water interactions and inversely correlated with hydrogen bonds to the protein-inhibitor complex. While many waters were conserved following the symmetry of homodimeric HIV protease, the asymmetry induced by DRV resulted in asymmetric lower-occupancy hydration sites at the concave surface of the active site. Key interactions between water molecules and the protease, that stabilize the protein in the inhibited form, were altered in a drug resistant variant of the protease indicating that modulation of solvent-solute interactions might play a key role in conveying drug resistance. Our analysis provides insights into the interplay between an enzyme inhibitor complex and the hydration shell and has implications in elucidating water structure in a variety of biological processes and applications including ligand binding, inhibitor design, and resistance.Source
J Chem Theory Comput. 2018 May 8;14(5):2784-2796. doi: 10.1021/acs.jctc.8b00097. Epub 2018 Apr 18. Link to article on publisher's site
DOI
10.1021/acs.jctc.8b00097Permanent Link to this Item
http://hdl.handle.net/20.500.14038/48880PubMed ID
29570286Related Resources
ae974a485f413a2113503eed53cd6c53
10.1021/acs.jctc.8b00097