Computational Protein Design with Ensembles, Flexibility and Mathematical Guarantees, and its Application to Drug Resistance Prediction, and Antibody Design

Computational Protein Design with Ensembles, Flexibility and Mathematical Guarantees, and its Application to Drug Resistance Prediction, and Antibody Design

<p>Proteins are involved in all of life's processes and are also responsible for many diseases. Thus, engineering proteins to perform new tasks could revolutionize many areas of biomedical research. One promising technique for protein engineering is computational structure-based protein...

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Bibliographic Details
Main Author: Gainza Cirauqui, Pablo
Other Authors: Donald, Bruce R.
Published: Jan
Subjects:
Computer science
Biophysics
Biochemistry
A* algorithm
antibody design
ensemble-based design
protein design
resistance prediction
simianization
Online Access:http://hdl.handle.net/10161/10468
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spelling ndltd-DUKE-oai-dukespace.lib.duke.edu-10161-104682015-09-03T03:45:33ZComputational Protein Design with Ensembles, Flexibility and Mathematical Guarantees, and its Application to Drug Resistance Prediction, and Antibody DesignGainza Cirauqui, PabloComputer scienceBiophysicsBiochemistryA* algorithmantibody designensemble-based designprotein designresistance predictionsimianization<p>Proteins are involved in all of life's processes and are also responsible for many diseases. Thus, engineering proteins to perform new tasks could revolutionize many areas of biomedical research. One promising technique for protein engineering is computational structure-based protein design (CSPD). CSPD algorithms search large protein conformational spaces to approximate biophysical quantities. In this dissertation we present new algorithms to realistically and accurately model how amino acid mutations change protein structure. These algorithms model continuous flexibility, protein ensembles and positive/negative design, while providing guarantees on the output. Using these algorithms and the OSPREY protein design program we design and apply protocols for three biomedically-relevant problems: (i) prediction of new drug resistance mutations in bacteria to a new preclinical antibiotic, (ii) the redesign of llama antibodies to potentially reduce their immunogenicity for use in preclinical monkey studies, and (iii) scaffold-based anti-HIV antibody design. Experimental validation performed by our collaborators confirmed the importance of the algorithms and protocols.</p>DissertationDonald, Bruce R.Jan 1 2015Dissertationhttp://hdl.handle.net/10161/10468
collection NDLTD
sources NDLTD
topic Computer science
Biophysics
Biochemistry
A* algorithm
antibody design
ensemble-based design
protein design
resistance prediction
simianization
spellingShingle Computer science
Biophysics
Biochemistry
A* algorithm
antibody design
ensemble-based design
protein design
resistance prediction
simianization
Gainza Cirauqui, Pablo
Computational Protein Design with Ensembles, Flexibility and Mathematical Guarantees, and its Application to Drug Resistance Prediction, and Antibody Design
description <p>Proteins are involved in all of life's processes and are also responsible for many diseases. Thus, engineering proteins to perform new tasks could revolutionize many areas of biomedical research. One promising technique for protein engineering is computational structure-based protein design (CSPD). CSPD algorithms search large protein conformational spaces to approximate biophysical quantities. In this dissertation we present new algorithms to realistically and accurately model how amino acid mutations change protein structure. These algorithms model continuous flexibility, protein ensembles and positive/negative design, while providing guarantees on the output. Using these algorithms and the OSPREY protein design program we design and apply protocols for three biomedically-relevant problems: (i) prediction of new drug resistance mutations in bacteria to a new preclinical antibiotic, (ii) the redesign of llama antibodies to potentially reduce their immunogenicity for use in preclinical monkey studies, and (iii) scaffold-based anti-HIV antibody design. Experimental validation performed by our collaborators confirmed the importance of the algorithms and protocols.</p> === Dissertation
author2 Donald, Bruce R.
author_facet Donald, Bruce R.
Gainza Cirauqui, Pablo
author Gainza Cirauqui, Pablo
author_sort Gainza Cirauqui, Pablo
title Computational Protein Design with Ensembles, Flexibility and Mathematical Guarantees, and its Application to Drug Resistance Prediction, and Antibody Design
title_short Computational Protein Design with Ensembles, Flexibility and Mathematical Guarantees, and its Application to Drug Resistance Prediction, and Antibody Design
title_full Computational Protein Design with Ensembles, Flexibility and Mathematical Guarantees, and its Application to Drug Resistance Prediction, and Antibody Design
title_fullStr Computational Protein Design with Ensembles, Flexibility and Mathematical Guarantees, and its Application to Drug Resistance Prediction, and Antibody Design
title_full_unstemmed Computational Protein Design with Ensembles, Flexibility and Mathematical Guarantees, and its Application to Drug Resistance Prediction, and Antibody Design
title_sort computational protein design with ensembles, flexibility and mathematical guarantees, and its application to drug resistance prediction, and antibody design
publishDate Jan
url http://hdl.handle.net/10161/10468
work_keys_str_mv AT gainzacirauquipablo computationalproteindesignwithensemblesflexibilityandmathematicalguaranteesanditsapplicationtodrugresistancepredictionandantibodydesign
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