FlexOracle: predicting flexible hinges by identification of stable domains

<p>Abstract</p> <p>Background</p> <p>Protein motions play an essential role in catalysis and protein-ligand interactions, but are difficult to observe directly. A substantial fraction of protein motions involve hinge bending. For these proteins, the accurate identificat...

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Main Authors: Flores Samuel C, Gerstein Mark B
Format: Article
Language:English
Published: BMC 2007-06-01
Series:BMC Bioinformatics
Online Access:http://www.biomedcentral.com/1471-2105/8/215
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spelling doaj-4ba71edd838642859ccdbb6cb71f5a902020-11-25T00:48:54ZengBMCBMC Bioinformatics1471-21052007-06-018121510.1186/1471-2105-8-215FlexOracle: predicting flexible hinges by identification of stable domainsFlores Samuel CGerstein Mark B<p>Abstract</p> <p>Background</p> <p>Protein motions play an essential role in catalysis and protein-ligand interactions, but are difficult to observe directly. A substantial fraction of protein motions involve hinge bending. For these proteins, the accurate identification of flexible hinges connecting rigid domains would provide significant insight into motion. Programs such as GNM and FIRST have made global flexibility predictions available at low computational cost, but are not designed specifically for finding hinge points.</p> <p>Results</p> <p>Here we present the novel FlexOracle hinge prediction approach based on the ideas that energetic interactions are stronger <it>within </it>structural domains than <it>between </it>them, and that fragments generated by cleaving the protein at the hinge site are independently stable. We implement this as a tool within the Database of Macromolecular Motions, MolMovDB.org. For a given structure, we generate pairs of fragments based on scanning all possible cleavage points on the protein chain, compute the energy of the fragments compared with the undivided protein, and predict hinges where this quantity is minimal. We present three specific implementations of this approach. In the first, we consider only pairs of fragments generated by cutting at a <it>single </it>location on the protein chain and then use a standard molecular mechanics force field to calculate the enthalpies of the two fragments. In the second, we generate fragments in the same way but instead compute their free energies using a knowledge based force field. In the third, we generate fragment pairs by cutting at <it>two </it>points on the protein chain and then calculate their free energies.</p> <p>Conclusion</p> <p>Quantitative results demonstrate our method's ability to predict known hinges from the Database of Macromolecular Motions.</p> http://www.biomedcentral.com/1471-2105/8/215
collection DOAJ
language English
format Article
sources DOAJ
author Flores Samuel C
Gerstein Mark B
spellingShingle Flores Samuel C
Gerstein Mark B
FlexOracle: predicting flexible hinges by identification of stable domains
BMC Bioinformatics
author_facet Flores Samuel C
Gerstein Mark B
author_sort Flores Samuel C
title FlexOracle: predicting flexible hinges by identification of stable domains
title_short FlexOracle: predicting flexible hinges by identification of stable domains
title_full FlexOracle: predicting flexible hinges by identification of stable domains
title_fullStr FlexOracle: predicting flexible hinges by identification of stable domains
title_full_unstemmed FlexOracle: predicting flexible hinges by identification of stable domains
title_sort flexoracle: predicting flexible hinges by identification of stable domains
publisher BMC
series BMC Bioinformatics
issn 1471-2105
publishDate 2007-06-01
description <p>Abstract</p> <p>Background</p> <p>Protein motions play an essential role in catalysis and protein-ligand interactions, but are difficult to observe directly. A substantial fraction of protein motions involve hinge bending. For these proteins, the accurate identification of flexible hinges connecting rigid domains would provide significant insight into motion. Programs such as GNM and FIRST have made global flexibility predictions available at low computational cost, but are not designed specifically for finding hinge points.</p> <p>Results</p> <p>Here we present the novel FlexOracle hinge prediction approach based on the ideas that energetic interactions are stronger <it>within </it>structural domains than <it>between </it>them, and that fragments generated by cleaving the protein at the hinge site are independently stable. We implement this as a tool within the Database of Macromolecular Motions, MolMovDB.org. For a given structure, we generate pairs of fragments based on scanning all possible cleavage points on the protein chain, compute the energy of the fragments compared with the undivided protein, and predict hinges where this quantity is minimal. We present three specific implementations of this approach. In the first, we consider only pairs of fragments generated by cutting at a <it>single </it>location on the protein chain and then use a standard molecular mechanics force field to calculate the enthalpies of the two fragments. In the second, we generate fragments in the same way but instead compute their free energies using a knowledge based force field. In the third, we generate fragment pairs by cutting at <it>two </it>points on the protein chain and then calculate their free energies.</p> <p>Conclusion</p> <p>Quantitative results demonstrate our method's ability to predict known hinges from the Database of Macromolecular Motions.</p>
url http://www.biomedcentral.com/1471-2105/8/215
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