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Literature DB >> 26687716

SimRNA: a coarse-grained method for RNA folding simulations and 3D structure prediction.

Michal J Boniecki¹, Grzegorz Lach², Wayne K Dawson², Konrad Tomala², Pawel Lukasz², Tomasz Soltysinski², Kristian M Rother², Janusz M Bujnicki³.

Abstract

RNA molecules play fundamental roles in cellular processes. Their function and interactions with other biomolecules are dependent on the ability to form complex three-dimensional (3D) structures. However, experimental determination of RNA 3D structures is laborious and challenging, and therefore, the majority of known RNAs remain structurally uncharacterized. Here, we present SimRNA: a new method for computational RNA 3D structure prediction, which uses a coarse-grained representation, relies on the Monte Carlo method for sampling the conformational space, and employs a statistical potential to approximate the energy and identify conformations that correspond to biologically relevant structures. SimRNA can fold RNA molecules using only sequence information, and, on established test sequences, it recapitulates secondary structure with high accuracy, including correct prediction of pseudoknots. For modeling of complex 3D structures, it can use additional restraints, derived from experimental or computational analyses, including information about secondary structure and/or long-range contacts. SimRNA also can be used to analyze conformational landscapes and identify potential alternative structures.

Entities: Chemical Disease Gene Species

Mesh：

Substances：
RNA

Year: 2015 PMID： 26687716 PMCID： PMC4838351 DOI： 10.1093/nar/gkv1479

Source DB: PubMed Journal: Nucleic Acids Res ISSN： 0305-1048 Impact factor: 16.971

52 in total

SimRNA: a coarse-grained method for RNA folding simulations and 3D structure prediction.

1. The MC-Fold and MC-Sym pipeline infers RNA structure from sequence data.

2. Automated de novo prediction of native-like RNA tertiary structures.

3. iFoldRNA: three-dimensional RNA structure prediction and folding.

4. New metrics for comparing and assessing discrepancies between RNA 3D structures and models.

5. Ab initio RNA folding by discrete molecular dynamics: from structure prediction to folding mechanisms.

6. Predicting RNA structure by multiple template homology modeling.

7. Coarse-grained modeling of large RNA molecules with knowledge-based potentials and structural filters.

8. Identifying novel sequence variants of RNA 3D motifs.

9. Classification and energetics of the base-phosphate interactions in RNA.

10. LocalMove: computing on-lattice fits for biopolymers.

1. VfoldLA: A web server for loop assembly-based prediction of putative 3D RNA structures.

2. Sequence-dependent RNA helix conformational preferences predictably impact tertiary structure formation.

3. Coarse-grained dynamic RNA titration simulations.

4. HNADOCK: a nucleic acid docking server for modeling RNA/DNA-RNA/DNA 3D complex structures.

5. Predicting RNA Scaffolds with a Hybrid Method of Vfold3D and VfoldLA.

6. Opportunities and Challenges in RNA Structural Modeling and Design.

7. Martini Coarse-Grained Force Field: Extension to RNA.

8. Modeling Structure, Stability, and Flexibility of Double-Stranded RNAs in Salt Solutions.

9. IsRNA1: De Novo Prediction and Blind Screening of RNA 3D Structures.

10. A nucleobase-centered coarse-grained representation for structure prediction of RNA motifs.