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dc.contributor.advisorVoelz, Vincent
dc.creatorZhang, Si
dc.date.accessioned2022-05-26T18:20:32Z
dc.date.available2022-05-26T18:20:32Z
dc.date.issued2022
dc.identifier.urihttp://hdl.handle.net/20.500.12613/7745
dc.description.abstractThe cellular function of proteins, and their targeting by drug applications, are both governed by biomolecular thermodynamics and kinetics. In order to make meaningful and efficient predictions of these mechanisms, molecular simulations must be able to estimate the binding affinity and rates of association and dissociation of a protein-ligand complex, or the populations and rates of exchange between distinct conformational states (i.e. folding and unfolding, binding and unbinding). The above studies are typically done using different, but complementary approaches. Alchemical methods, including free energy perturbation (FEP) and thermodynamic integration (TI), have become the dominant method for computing high-quality estimates of protein-ligand binding free energies. In particular, the widely-used approach of relative binding free energy calculation can deliver accuracies within 1 kcal mol−1. However, detailed physical pathways and kinetics are missing from these calculations. In principle, all-atom molecular dynamics (MD) simulation, with the help of Markov State Models (MSMs), can be used to obtain this information, yet finite sampling error still limits MSM approaches from making accurate predictions for very slow unfolding or unbinding processes. To overcome these issues, a new approach called multiensemble Markov models (MEMMs) have been developed, in which sampling from biased thermodynamic ensembles can be used to infer states populations and transition rates in unbiased ensembles. In this dissertation, two distinct biophysical problems are investigated. In the first part, we apply expanded ensemble (EE) methods to accurately predict relative binding free energies for a series of protein-ligand systems. Moreover, we propose a simple optimization scheme for choosing alchemical intermediates in free energy simulations. In the second part, we employ MEMMs to estimate the free energies and kinetics of protein folding and ligand binding, to achieve greatly improved predictions. Finally, we combine the above EE method and a maximum-caliber algorithm to study how sequence mutations perturb protein stability and folding kinetics. In summary, this work comprises a wide range of current methodology in biophysical simulation, complementing and improving upon existing approaches.
dc.format.extent203 pages
dc.language.isoeng
dc.publisherTemple University. Libraries
dc.relation.ispartofTheses and Dissertations
dc.rightsIN COPYRIGHT- This Rights Statement can be used for an Item that is in copyright. Using this statement implies that the organization making this Item available has determined that the Item is in copyright and either is the rights-holder, has obtained permission from the rights-holder(s) to make their Work(s) available, or makes the Item available under an exception or limitation to copyright (including Fair Use) that entitles it to make the Item available.
dc.rights.urihttp://rightsstatements.org/vocab/InC/1.0/
dc.subjectComputational chemistry
dc.titleCOMPUTATIONAL APPROACHES FOR PROTEIN FOLDING AND LIGAND BINDING: FROM THERMODYNAMICS TO KINETICS
dc.typeText
dc.type.genreThesis/Dissertation
dc.contributor.committeememberCarnevale, Vincenzo
dc.contributor.committeememberWang, Rongsheng
dc.contributor.committeememberSharp, Kim A.
dc.description.departmentChemistry
dc.relation.doihttp://dx.doi.org/10.34944/dspace/7717
dc.ada.noteFor Americans with Disabilities Act (ADA) accommodation, including help with reading this content, please contact scholarshare@temple.edu
dc.description.degreePh.D.
dc.identifier.proqst14865
dc.creator.orcid0000-0002-1164-2020
dc.date.updated2022-05-11T16:11:11Z
dc.embargo.lift05/11/2023
dc.identifier.filenameZhang_temple_0225E_14865.pdf


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