The Role of Mutations in Protein Structural Dynamics and Function: A Multi-scale Computational Approach

abstract: Proteins are a fundamental unit in biology. Although proteins have been extensively studied, there is still much to investigate. The mechanism by which proteins fold into their native state, how evolution shapes structural dynamics, and the dynamic mechanisms of many diseases are not well...

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Other Authors: Glembo, Tyler (Author)
Format: Doctoral Thesis
Language:English
Published: 2011
Subjects:
Online Access:http://hdl.handle.net/2286/R.I.9515
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spelling ndltd-asu.edu-item-95152018-06-22T03:02:11Z The Role of Mutations in Protein Structural Dynamics and Function: A Multi-scale Computational Approach abstract: Proteins are a fundamental unit in biology. Although proteins have been extensively studied, there is still much to investigate. The mechanism by which proteins fold into their native state, how evolution shapes structural dynamics, and the dynamic mechanisms of many diseases are not well understood. In this thesis, protein folding is explored using a multi-scale modeling method including (i) geometric constraint based simulations that efficiently search for native like topologies and (ii) reservoir replica exchange molecular dynamics, which identify the low free energy structures and refines these structures toward the native conformation. A test set of eight proteins and three ancestral steroid receptor proteins are folded to 2.7Å all-atom RMSD from their experimental crystal structures. Protein evolution and disease associated mutations (DAMs) are most commonly studied by in silico multiple sequence alignment methods. Here, however, the structural dynamics are incorporated to give insight into the evolution of three ancestral proteins and the mechanism of several diseases in human ferritin protein. The differences in conformational dynamics of these evolutionary related, functionally diverged ancestral steroid receptor proteins are investigated by obtaining the most collective motion through essential dynamics. Strikingly, this analysis shows that evolutionary diverged proteins of the same family do not share the same dynamic subspace. Rather, those sharing the same function are simultaneously clustered together and distant from those functionally diverged homologs. This dynamics analysis also identifies 77% of mutations (functional and permissive) necessary to evolve new function. In silico methods for prediction of DAMs rely on differences in evolution rate due to purifying selection and therefore the accuracy of DAM prediction decreases at fast and slow evolvable sites. Here, we investigate structural dynamics through computing the contribution of each residue to the biologically relevant fluctuations and from this define a metric: the dynamic stability index (DSI). Using DSI we study the mechanism for three diseases observed in the human ferritin protein. The T30I and R40G DAMs show a loss of dynamic stability at the C-terminus helix and nearby regulatory loop, agreeing with experimental results implicating the same regulatory loop as a cause in cataracts syndrome. Dissertation/Thesis Glembo, Tyler (Author) Ozkan, Sefika B (Advisor) Thorpe, Michael F (Committee member) Ros, Robert (Committee member) Kumar, Sudhir (Committee member) Shumway, John (Committee member) Arizona State University (Publisher) Biophysics dynamics evolution function mutation protein structure eng 190 pages Ph.D. Physics 2011 Doctoral Dissertation http://hdl.handle.net/2286/R.I.9515 http://rightsstatements.org/vocab/InC/1.0/ All Rights Reserved 2011
collection NDLTD
language English
format Doctoral Thesis
sources NDLTD
topic Biophysics
dynamics
evolution
function
mutation
protein
structure
spellingShingle Biophysics
dynamics
evolution
function
mutation
protein
structure
The Role of Mutations in Protein Structural Dynamics and Function: A Multi-scale Computational Approach
description abstract: Proteins are a fundamental unit in biology. Although proteins have been extensively studied, there is still much to investigate. The mechanism by which proteins fold into their native state, how evolution shapes structural dynamics, and the dynamic mechanisms of many diseases are not well understood. In this thesis, protein folding is explored using a multi-scale modeling method including (i) geometric constraint based simulations that efficiently search for native like topologies and (ii) reservoir replica exchange molecular dynamics, which identify the low free energy structures and refines these structures toward the native conformation. A test set of eight proteins and three ancestral steroid receptor proteins are folded to 2.7Å all-atom RMSD from their experimental crystal structures. Protein evolution and disease associated mutations (DAMs) are most commonly studied by in silico multiple sequence alignment methods. Here, however, the structural dynamics are incorporated to give insight into the evolution of three ancestral proteins and the mechanism of several diseases in human ferritin protein. The differences in conformational dynamics of these evolutionary related, functionally diverged ancestral steroid receptor proteins are investigated by obtaining the most collective motion through essential dynamics. Strikingly, this analysis shows that evolutionary diverged proteins of the same family do not share the same dynamic subspace. Rather, those sharing the same function are simultaneously clustered together and distant from those functionally diverged homologs. This dynamics analysis also identifies 77% of mutations (functional and permissive) necessary to evolve new function. In silico methods for prediction of DAMs rely on differences in evolution rate due to purifying selection and therefore the accuracy of DAM prediction decreases at fast and slow evolvable sites. Here, we investigate structural dynamics through computing the contribution of each residue to the biologically relevant fluctuations and from this define a metric: the dynamic stability index (DSI). Using DSI we study the mechanism for three diseases observed in the human ferritin protein. The T30I and R40G DAMs show a loss of dynamic stability at the C-terminus helix and nearby regulatory loop, agreeing with experimental results implicating the same regulatory loop as a cause in cataracts syndrome. === Dissertation/Thesis === Ph.D. Physics 2011
author2 Glembo, Tyler (Author)
author_facet Glembo, Tyler (Author)
title The Role of Mutations in Protein Structural Dynamics and Function: A Multi-scale Computational Approach
title_short The Role of Mutations in Protein Structural Dynamics and Function: A Multi-scale Computational Approach
title_full The Role of Mutations in Protein Structural Dynamics and Function: A Multi-scale Computational Approach
title_fullStr The Role of Mutations in Protein Structural Dynamics and Function: A Multi-scale Computational Approach
title_full_unstemmed The Role of Mutations in Protein Structural Dynamics and Function: A Multi-scale Computational Approach
title_sort role of mutations in protein structural dynamics and function: a multi-scale computational approach
publishDate 2011
url http://hdl.handle.net/2286/R.I.9515
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