A comprehensive survey of long-range tertiary interactions and motifs in non-coding RNA structures

Bohdan, Davyd R; Voronina, Valeria V; Bujnicki, Janusz; Baulin, Eugene F.

doi:10.1093/nar/gkad605

Cited by 3 publications

(14 citation statements)

References 64 publications

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“…To identify the optimal alignment, we developed the ARTEMIS algorithm (using ARTEM [20] to I nfer S equence alignment), which operates under the assumption that the ideal superposition involves at least one pair of matched residues exhibiting a near-zero RMSD.…”

Section: Methodsmentioning

confidence: 99%

“…ARTEMIS superimposes the query structure Y on the reference X across all possible residue pairs between the structures (Supplementary Figure S1, lines [20][21][22][23][24][25][26][27][28][29][30][31][32]. Each superposition is computed using the Kabsch algorithm [21], employing a 3-atom representation of the residues.…”

Section: Artemis Algorithmmentioning

confidence: 99%

“…The TM1-Score RNA and TM2-Score RNA yielding the maximum sum are then assigned to the candidate alignment. Similar to ARTEM [20], the theoretical time complexity of ARTEMIS is O(N 2 * M 2 ), given that ARTEMIS computes N*M pairwise distances to determine the set of mutually closest residues for each of the N*M single-residue seed superpositions (Supplementary Figure S1, lines 20-30).…”

Section: å (Supplementary Figure S1 Lines 26-29)mentioning

confidence: 99%

“…In this work, we present ARTEMIS, an application of ARTEM methodology to address the global RNA 3D structure alignment problem. The heuristic behind ARTEMIS operates in polynomial time and ensures the optimal solution, provided it includes at least one residue-residue match with a near-zero RMSD, a condition commonly met in RNA structures due to their characteristic recurrent interactions [20]. ARTEMIS significantly outperforms state-of-the-art tools in both sequentially-ordered and topology-independent RNA 3D structure superposition.…”

Section: Introductionmentioning

confidence: 99%

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ARTEMIS - a method for topology-independent superposition of RNA 3D structures and structure-based sequence alignment

Bohdan,

Bujnicki,

Baulin

2024

Preprint

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Non-coding RNAs play a major role in diverse processes in living cells with their sequence and spatial structure serving as the principal determinants of their function. Superposition of RNA 3D structures is the most accurate method for comparative analysis of RNA molecules and for inferring sequence alignments. Topology-independent superposition is particularly relevant, as evidenced by structurally similar RNAs with sequence permutations such as tRNA and Y RNA. To date, state-of-the-art methods for RNA 3D structure superposition rely on intricate heuristics, and the potential for topology-independent superposition has not been exhausted. Recently, we introduced the ARTEM method for unrestrained pairwise superposition of RNA 3D modules and now we developed it further to solve the global RNA 3D structure alignment problem. Our new tool ARTEMIS significantly outperforms state-of-the-art tools in both sequentially-ordered and topology-independent RNA 3D structure superposition. Using ARTEMIS we discovered a helical packing motif to be preserved within different backbone topology contexts across various non-coding RNAs, including multiple ribozymes and riboswitches. We anticipate that ARTEMIS will be essential for elucidating the landscape of RNA 3D folds and motifs featuring sequence permutations that thus far remained unexplored due to limitations in previous computational approaches.

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Section: Methodsmentioning

confidence: 99%

Section: Artemis Algorithmmentioning

confidence: 99%

Section: å (Supplementary Figure S1 Lines 26-29)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

ARTEMIS - a method for topology-independent superposition of RNA 3D structures and structure-based sequence alignment

Bohdan,

Bujnicki,

Baulin

2024

Preprint

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“…The SQUARNA approach is rooted in the ARTEM algorithm, designed for the superposition of two arbitrary RNA 3D structure fragments without prior knowledge of nucleotide matchings between the fragments [42]. The two core ideas of ARTEM are the formulation of the problem as the partial assignment problem and the utilization of dependencies in the data.…”

Section: Theoretical Backgroundmentioning

confidence: 99%

SQUARNA - an RNA secondary structure prediction method based on a greedy stem formation model

Bohdan,

Nikolaev,

Bujnicki

et al. 2023

Preprint

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Non-coding RNAs play a great variety of roles in many cellular processes with their spatial structure known to dictate the functioning. RNA secondary structure largely determines the molecule’s global fold, which together with the paucity of experimentally determined RNA 3D structures makes its knowledge crucial for determining the function of the molecule. Currently, there is no one good solution for de novo RNA secondary structure prediction, with the existing methods getting more and more complicated without substantial progress in accuracy and being subject to drastic limitations such as ignoring pseudoknots. In this work, we present SQUARNA, a new approach for de novo RNA secondary structure prediction based on a straightforward greedy stem formation model overcoming many limitations of the existing tools. The benchmarks show that SQUARNA is on par with state-of-the-art methods for a single sequence input and significantly outperforms existing tools for a sequence alignment input.

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ARTEM: a method for RNA tertiary motif identification with backbone permutations, and its example application to kink-turn-like motifs

Baulin,

Bohdan,

Kowalski

et al. 2024

Preprint

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The functions of non-coding RNAs are largely defined by their three-dimensional structures. RNA 3D structure is organized hierarchically and consists of recurrent building blocks called tertiary motifs. The computational problem of RNA tertiary motif search remains largely unsolved, as standard approaches are restrained by sequence, interaction network, or backbone topology. We developed the ARTEM superposition algorithm, which is free from these limitations. Here, we present a version of ARTEM that allows automated searches of RNA structure databases to identify 3D structure motifs. We exemplify it by a search of motifs isosteric to the kink-turn motif. This widespread motif plays a role in many aspects of RNA function, and its mutations are known to cause several human syndromes. With ARTEM, we discovered two new kink-turn topologies, multiple no-kink variants of the motif, and showed that a ribosomal junction in bacteria forms either a kink or a no-kink variant depending on the species. Additionally, we identified kink-turns in the catalytic core of group II introns, whose structures have not previously been characterized as containing kink-turns. ARTEM opens a fundamentally new way to study RNA 3D folds and motifs and analyze their correlations and variations.

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A comprehensive survey of long-range tertiary interactions and motifs in non-coding RNA structures

Cited by 3 publications

References 64 publications

ARTEMIS - a method for topology-independent superposition of RNA 3D structures and structure-based sequence alignment

ARTEMIS - a method for topology-independent superposition of RNA 3D structures and structure-based sequence alignment

SQUARNA - an RNA secondary structure prediction method based on a greedy stem formation model

ARTEM: a method for RNA tertiary motif identification with backbone permutations, and its example application to kink-turn-like motifs

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