GARN: Sampling RNA 3D Structure Space with Game Theory and Knowledge-Based Scoring Strategies.

GARN: Sampling RNA 3D Structure Space with Game Theory and Knowledge-Based Scoring Strategies.

Cellular processes involve large numbers of RNA molecules. The functions of these RNA molecules and their binding to molecular machines are highly dependent on their 3D structures. One of the key challenges in RNA structure prediction and modeling is predicting the spatial arrangement of the various...

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Main Authors: Mélanie Boudard, Julie Bernauer, Dominique Barth, Johanne Cohen, Alain Denise
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2015-01-01
Series:PLoS ONE
Online Access:http://europepmc.org/articles/PMC4551674?pdf=render
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spelling doaj-a3bbc53c2dab4653b7a61beefdf163512020-11-24T22:07:57ZengPublic Library of Science (PLoS)PLoS ONE1932-62032015-01-01108e013644410.1371/journal.pone.0136444GARN: Sampling RNA 3D Structure Space with Game Theory and Knowledge-Based Scoring Strategies.Mélanie BoudardJulie BernauerDominique BarthJohanne CohenAlain DeniseCellular processes involve large numbers of RNA molecules. The functions of these RNA molecules and their binding to molecular machines are highly dependent on their 3D structures. One of the key challenges in RNA structure prediction and modeling is predicting the spatial arrangement of the various structural elements of RNA. As RNA folding is generally hierarchical, methods involving coarse-grained models hold great promise for this purpose. We present here a novel coarse-grained method for sampling, based on game theory and knowledge-based potentials. This strategy, GARN (Game Algorithm for RNa sampling), is often much faster than previously described techniques and generates large sets of solutions closely resembling the native structure. GARN is thus a suitable starting point for the molecular modeling of large RNAs, particularly those with experimental constraints. GARN is available from: http://garn.lri.fr/.http://europepmc.org/articles/PMC4551674?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Mélanie Boudard
Julie Bernauer
Dominique Barth
Johanne Cohen
Alain Denise
spellingShingle Mélanie Boudard
Julie Bernauer
Dominique Barth
Johanne Cohen
Alain Denise
GARN: Sampling RNA 3D Structure Space with Game Theory and Knowledge-Based Scoring Strategies.
PLoS ONE
author_facet Mélanie Boudard
Julie Bernauer
Dominique Barth
Johanne Cohen
Alain Denise
author_sort Mélanie Boudard
title GARN: Sampling RNA 3D Structure Space with Game Theory and Knowledge-Based Scoring Strategies.
title_short GARN: Sampling RNA 3D Structure Space with Game Theory and Knowledge-Based Scoring Strategies.
title_full GARN: Sampling RNA 3D Structure Space with Game Theory and Knowledge-Based Scoring Strategies.
title_fullStr GARN: Sampling RNA 3D Structure Space with Game Theory and Knowledge-Based Scoring Strategies.
title_full_unstemmed GARN: Sampling RNA 3D Structure Space with Game Theory and Knowledge-Based Scoring Strategies.
title_sort garn: sampling rna 3d structure space with game theory and knowledge-based scoring strategies.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2015-01-01
description Cellular processes involve large numbers of RNA molecules. The functions of these RNA molecules and their binding to molecular machines are highly dependent on their 3D structures. One of the key challenges in RNA structure prediction and modeling is predicting the spatial arrangement of the various structural elements of RNA. As RNA folding is generally hierarchical, methods involving coarse-grained models hold great promise for this purpose. We present here a novel coarse-grained method for sampling, based on game theory and knowledge-based potentials. This strategy, GARN (Game Algorithm for RNa sampling), is often much faster than previously described techniques and generates large sets of solutions closely resembling the native structure. GARN is thus a suitable starting point for the molecular modeling of large RNAs, particularly those with experimental constraints. GARN is available from: http://garn.lri.fr/.
url http://europepmc.org/articles/PMC4551674?pdf=render
work_keys_str_mv AT melanieboudard garnsamplingrna3dstructurespacewithgametheoryandknowledgebasedscoringstrategies
AT juliebernauer garnsamplingrna3dstructurespacewithgametheoryandknowledgebasedscoringstrategies
AT dominiquebarth garnsamplingrna3dstructurespacewithgametheoryandknowledgebasedscoringstrategies
AT johannecohen garnsamplingrna3dstructurespacewithgametheoryandknowledgebasedscoringstrategies
AT alaindenise garnsamplingrna3dstructurespacewithgametheoryandknowledgebasedscoringstrategies
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