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RNAJP: enhanced RNA 3D structure predictions with non-canonical interactions and global topology sampling

Jun Li, Shi‐Jie Chen

2023Nucleic Acids Research43 citationsDOIOpen Access PDF

Abstract

RNA 3D structures are critical for understanding their functions. However, only a limited number of RNA structures have been experimentally solved, so computational prediction methods are highly desirable. Nevertheless, accurate prediction of RNA 3D structures, especially those containing multiway junctions, remains a significant challenge, mainly due to the complicated non-canonical base pairing and stacking interactions in the junction loops and the possible long-range interactions between loop structures. Here we present RNAJP ('RNA Junction Prediction'), a nucleotide- and helix-level coarse-grained model for the prediction of RNA 3D structures, particularly junction structures, from a given 2D structure. Through global sampling of the 3D arrangements of the helices in junctions using molecular dynamics simulations and in explicit consideration of non-canonical base pairing and base stacking interactions as well as long-range loop-loop interactions, the model can provide significantly improved predictions for multibranched junction structures than existing methods. Moreover, integrated with additional restraints from experiments, such as junction topology and long-range interactions, the model may serve as a useful structure generator for various applications.

Topics & Concepts

StackingRNABase pairPairingTopology (electrical circuits)BiologyNucleic acid structureLoop (graph theory)Biological systemHelix (gastropod)Computational biologyComputer sciencePhysicsDNAMathematicsGeneticsGeneCombinatoricsQuantum mechanicsSnailNuclear magnetic resonanceEcologySuperconductivityRNA and protein synthesis mechanismsRNA Research and SplicingRNA modifications and cancer
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