A joint project of the Graduate School, Peabody College, and the Jean & Alexander Heard Library

Title page for ETD etd-01132018-113518


Type of Document Dissertation
Author Fischer, Axel Walter
Author's Email Address axel.fischer@vanderbilt.edu
URN etd-01132018-113518
Title In silico prediction of protein structures and ensembles
Degree PhD
Department Chemistry
Advisory Committee
Advisor Name Title
Jens Meiler Committee Chair
Carlos F. Lopez Committee Member
Hassane S. Mchaourab Committee Member
Michael P. Stone Committee Member
Terry P. Lybrand Committee Member
Keywords
  • de novo prediction
  • emre
  • protein modeling
  • epr
  • loop modeling
  • protein ensemble prediction
  • protein structure prediction
Date of Defense 2018-01-10
Availability unrestricted
Abstract
Determination of a protein’s structural equilibrium constitution remains a challenge. Experimental techniques like X-ray crystallography or nuclear magnetic resonance spectroscopy either are only able to determine single snapshots of the protein or are not applicable due to the protein's size or dynamics. Orthogonal techniques like electron paramagnetic resonance (EPR) spectroscopy are able to capture all significant populations of the

protein but the obtainable data are typically too sparse to unambiguously determine a structural ensemble. Computational methods on the other hand, suffer from necessary simplifications of the structure sampling and free energy evaluation. In order to solve these existing problems, I developed a computational prediction pipeline for protein structures and ensembles that supports incorporation of limited experimental data from EPR spectroscopy and chemical cross-linking. The pipeline encompasses coarse-grained Monte Carlo Metropolis sampling using BCL::Fold, high-resolution refinement using Rosetta, and stability evaluations using molecular dynamics simulations. Novel methods were developed to incorporate the experimental data into the pipeline.

Both types of experimental data significantly improved the average accuracy of the sampled models as well as the discrimination between accurate and inaccurate models. In addition, a novel loop sampling algorithm consisting of conformation hashing and cyclic coordinate descent was developed. The algorithm is substantially faster than other available algorithms and samples the conformation of the protein’s major population in 94 % of all cases. The developed methods were applied to determine the structure and dynamics of the Bcl-2-associated X protein (BAX), exotoxin U (ExoU), and the efflux-multidrug resistance protein (EmrE) in conjunction with structural data obtained through EPR spectroscopy.

Files
  Filename       Size       Approximate Download Time (Hours:Minutes:Seconds) 
 
 28.8 Modem   56K Modem   ISDN (64 Kb)   ISDN (128 Kb)   Higher-speed Access 
  fischer.pdf 20.64 Mb 01:35:32 00:49:08 00:42:59 00:21:29 00:01:50

Browse All Available ETDs by ( Author | Department )

If you have more questions or technical problems, please Contact LITS.