作者Yang, Ying
ProQuest Information and Learning Co
Purdue University. Medicinal Chemistry and Molecular Pharmacology
書名Computational Modeling of (De)-Solvation Effects and Protein Flexibility in Protein-Ligand Binding Using Molecular Dynamics Simulations
出版項2018
說明1 online resource (177 pages)
文字text
無媒介computer
成冊online resource
附註Source: Dissertations Abstracts International, Volume: 81-01, Section: B
Advisor: Lill, Markus A
Thesis (Ph.D.)--Purdue University, 2018
Includes bibliographical references
Water is a crucial participant in virtually all cellular functions. Evidently, water molecules in the binding site contribute significantly to the strength of intermolecular interactions in the aqueous phase by mediating protein-ligand interactions, solvating and de-solvating both ligand and protein upon protein-ligand dissociation and association. Recently many published studies use water distributions in the binding site to retrospectively explain and rationalize unexpected trends in structure-activity relationships (SAR). However, traditional approaches cannot quantitatively predict the thermodynamic properties of water molecules in the binding sites and its associated contribution to the binding free energy of a ligand.We have developed and validated a computational method named WATsite to exploit high-resolution solvation maps and thermodynamic profiles to elucidate the water molecules' potential contribution to protein-ligand and protein-protein binding. We have also demonstrated the utility of the computational method WATsite to help direct medicinal chemistry efforts by using explicit water de-solvation.In addition, protein conformational change is typically involved in the ligand-binding process which may completely change the position and thermodynamic properties of the water molecules in the binding site before or upon ligand binding. We have shown the interplay between protein flexibility and solvent reorganization, and we provide a quantitative estimation of the influence of protein flexibility on de- solvation free energy and, therefore, protein-ligand binding.Different ligands binding to the same target protein can induce different conformational adaptations. In order to apply WATsite to an ensemble of different protein conformations, a more efficient implementation of WATsite based on GPU-acceleration and system truncation has been developed. Lastly, by extending the simulation protocol from pure water to mixed water-organic probes simulations, accurate modeling of halogen atom-protein interactions has been achieved
Electronic reproduction. Ann Arbor, Mich. : ProQuest, 2020
Mode of access: World Wide Web
主題Computational chemistry
Biophysics
Bioinformatics
De-solvation Free Energy
Halogen-bonding
Hydration Site
Molecular Dynamics
Protein Flexibility
WATsite
Electronic books.
0219
0786
0715
ISBN/ISSN9781085560702
QRCode
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