RNA global alignment in the joint sequence–structure space using elastic shape analysis

Laborde, Jose; Robinson, Daniel; Srivastava, Anuj; Klassen, Eric; Zhang, Jinfeng

doi:10.1093/nar/gkt187

Cited by 16 publications

(25 citation statements)

References 30 publications

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“…Recent progress in RNA-based therapeutics 2 including RNA vaccination therapy 3 and successful application of RNA based technologies in plant 4 and animal agriculture 5 have highlighted the importance of developing an overall understanding of the sequence-structure-function relationships in RNA. Despite numerous scientific investigations exploring the sequence-structure [6][7][8][9] and structure-function [10][11][12] spaces for RNA, a comprehensive picture similar to those for protein or DNA is yet to evolve 1,13,14 . RNA achieves the remarkable structural complexity and fascinating functional diversity similar to proteins with only four different building blocks (nucleotides), instead of twenty physicochemically different amino acids as present in proteins.…”

Section: Introductionmentioning

confidence: 99%

Reverse Watson-Crick purine-purine base pairs — the Sharp-turn motif and other structural consequences in functional RNAs

Mittal¹,

Halder²,

Bhattacharya³

et al. 2017

Preprint

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Identification of static and/or dynamic roles of different noncanonical base pairs is essential for a comprehensive understanding of the sequence-structure-function space of RNA. In this context, reverse WatsonCrick purine-purine base pairs (A:A, G:G & A:G W:W Trans) constitute an interesting class of noncanonical base pairs in RNA due to their characteristic C1 -C1 distance (highest among all base pairing geometries) and parallel local strand orientation. Structural alignment of the RNA stretches containing these W:W Trans base pairs with their corresponding homologous sites in a non-redundant set of RNA crystal structures show that, as expected, these base pairs are associated with specific structural folds or functional roles. Detailed analysis of these contexts further revealed a bimodal distribution in the local backbone geometry parameters associated with these base pairs. One mode, populated by both A:A and G:G W:W Trans pairs, manifests itself as a characteristic backbone fold. We call this fold a 'Sharp-turn' motif. The other mode is exclusively associated with A:A W:W Trans pairs involved in mediating higher order interactions. The same trend is also observed in available solution NMR structures. We have also characterized the importance of recurrent hydrogen bonding interactions between adenine and guanine in W:W Trans geometry. Quantum chemical calculations performed at M05-2X/6-31++(2d,2p) level explain how the characteristic electronic properties of these W:W Trans base pairs facilitate their occurrence in such exclusive structural folds that are important for RNA functionalities.

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Section: Introductionmentioning

confidence: 99%

Reverse Watson-Crick purine-purine base pairs — the Sharp-turn motif and other structural consequences in functional RNAs

Mittal¹,

Halder²,

Bhattacharya³

et al. 2017

Preprint

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show abstract

“…The framework allows us to seamlessly incorporate sequence information into 3D structures in the computation of geodesic distances. The detailed description of the ESA method is given in (23) and (25). …”

Section: Methodsmentioning

confidence: 99%

“…With this option users can select a partial structure within a larger RNA molecule for comparison, which can be interesting either structurally or functionally. Since our method is a global alignment method, this option can be especially useful if a user wants to compare a partial structure based on some prior knowledge/information.Lambda: weight for the nucleotide sequence (23). The value of lambda needs to be greater or equal to zero.…”

Section: Web Interface and Usagementioning

confidence: 99%

“…Lambda: weight for the nucleotide sequence (23). The value of lambda needs to be greater or equal to zero.…”

Section: Web Interface and Usagementioning

confidence: 99%

“…In principle, structure alignment methods should utilize sequence information since such information is almost always available. Recently, we have developed a RNA structure alignment method (23,24) that aligns RNAs in the joint sequence-structure space using a framework based on elastic shape analysis (ESA) originally designed for protein structure comparison (25,26). We have shown that the method performed better than using either sequence or structure information alone.…”

Section: Introductionmentioning

confidence: 99%

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RASS: a web server for RNA alignment in the joint sequence-structure space

He¹,

Steppi²,

Laborde³

et al. 2014

Nucleic Acids Research

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Comparison of ribonucleic acid (RNA) molecules is important for revealing their evolutionary relationships, predicting their functions and predicting their structures. Many methods have been developed for comparing RNAs using either sequence or three-dimensional (3D) structure (backbone geometry) information. Sequences and 3D structures contain non-overlapping sets of information that both determine RNA functions. When comparing RNA 3D structures, both types of information need to be taken into account. However, few methods compare RNA structures using both sequence and 3D structure information. Recently, we have developed a new method based on elastic shape analysis (ESA) that compares RNA molecules by combining both sequence and 3D structure information. ESA treats RNA structures as 3D curves with sequence information encoded on additional coordinates so that the alignment can be performed in the joint sequence-structure space. The similarity between two RNA molecules is quantified by a formal distance, geodesic distance. In this study, we implement a web server for the method, called RASS, to make it publicly available to research community. The web server is located at http://cloud.stat.fsu.edu/RASS/.

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Shapes of Curves in Higher Dimensions

Srivastava¹,

Klassen²

2016

Functional and Shape Data Analysis

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RNA global alignment in the joint sequence–structure space using elastic shape analysis

Cited by 16 publications

References 30 publications

Reverse Watson-Crick purine-purine base pairs — the Sharp-turn motif and other structural consequences in functional RNAs

Reverse Watson-Crick purine-purine base pairs — the Sharp-turn motif and other structural consequences in functional RNAs

RASS: a web server for RNA alignment in the joint sequence-structure space

Shapes of Curves in Higher Dimensions

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