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Comparative analysis of RNA secondary structure accuracy on predicted RNA 3D models

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  • Mandar Kulkarni
  • Jayaraman Thangappan
  • Indrajit Deb
  • Sangwook Wu

Abstract

RNA structure is conformationally dynamic, and accurate all-atom tertiary (3D) structure modeling of RNA remains challenging with the prevailing tools. Secondary structure (2D) information is the standard prerequisite for most RNA 3D modeling. Despite several 2D and 3D structure prediction tools proposed in recent years, one of the challenges is to choose the best combination for accurate RNA 3D structure prediction. Here, we benchmarked seven small RNA PDB structures (40 to 90 nucleotides) with different topologies to understand the effects of different 2D structure predictions on the accuracy of 3D modeling. The current study explores the blind challenge of 2D to 3D conversions and highlights the performances of de novo RNA 3D modeling from their predicted 2D structure constraints. Our results show that conformational sampling-based methods such as SimRNA and IsRNA1 depend less on 2D accuracy, whereas motif-based methods account for 2D evidence. Our observations illustrate the disparities in available 3D and 2D prediction methods and may further offer insights into developing topology-specific or family-specific RNA structure prediction pipelines.

Suggested Citation

  • Mandar Kulkarni & Jayaraman Thangappan & Indrajit Deb & Sangwook Wu, 2023. "Comparative analysis of RNA secondary structure accuracy on predicted RNA 3D models," PLOS ONE, Public Library of Science, vol. 18(9), pages 1-33, September.
    • Handle: RePEc:plo:pone00:0290907
    DOI: 10.1371/journal.pone.0290907
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    1. Jaswinder Singh & Jack Hanson & Kuldip Paliwal & Yaoqi Zhou, 2019. "RNA secondary structure prediction using an ensemble of two-dimensional deep neural networks and transfer learning," Nature Communications, Nature, vol. 10(1), pages 1-13, December.
    2. Blake A. Sweeney & David Hoksza & Eric P. Nawrocki & Carlos Eduardo Ribas & Fábio Madeira & Jamie J. Cannone & Robin Gutell & Aparna Maddala & Caeden D. Meade & Loren Dean Williams & Anton S. Petrov &, 2021. "R2DT is a framework for predicting and visualising RNA secondary structure using templates," Nature Communications, Nature, vol. 12(1), pages 1-12, December.
    3. Marc Parisien & François Major, 2008. "The MC-Fold and MC-Sym pipeline infers RNA structure from sequence data," Nature, Nature, vol. 452(7183), pages 51-55, March.
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