Representation, searching and discovery of patterns of bases in complex RNA structures

Harrison, Anne-Marie; South, Darren R.; Willett, Peter; Artymiuk, Peter J.

doi:10.1023/b:jcam.0000004603.15856.32

Cited by 38 publications

(44 citation statements)

References 51 publications

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“…Now we reject some of these partial candidates by applying the subset screening criterion (10) with I = {1, 2, 3}; we reject (p, q, r) triples for which (15) because we can be certain that any m-nucleotide candidate for which (p, q, r) correspond to ( (p 1 ,…, p k , q) for (1, 2,…, k, k + 1) provided that (16) so that all pairwise constraints between the k existing nucleotides and the one new nucleotide are met. We then use the subset screening criterion; we reject those candidates for which: (17) Here S * is the corresponding sum for (p 1 ,…, p k ). Thus, when adding the next nucleotide, k pairwise constraints must be checked, and k additional terms must be summed to apply the subset screening criterion.…”

Section: Building Lists Of Partial Candidates and The Screening Algormentioning

confidence: 99%

“…Harrison and co-workers also apply subgraph isomorphisms to search for motifs in graphs representing RNA 3D structure [17], using methods that were first developed for substructure searching libraries of small molecule structures and then applied to proteins, carbohydrates, and most recently, RNA [4]. For RNA structure searching, each base is represented by two vectors and the whole RNA structure as a labeled graph so the search problem is reduced to finding subgraph isomorphisms representing query motifs in graphs representing RNA 3D structures.…”

Section: Introductionmentioning

confidence: 99%

“…For RNA structure searching, each base is represented by two vectors and the whole RNA structure as a labeled graph so the search problem is reduced to finding subgraph isomorphisms representing query motifs in graphs representing RNA 3D structures. This approach was applied to search for non-Watson-Crick basepairs and other small motifs in RNA structures [17]. As the Ullman algorithm used for subgraph searching scales with n factorial (n!…”

Section: Introductionmentioning

confidence: 99%

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FR3D: finding local and composite recurrent structural motifs in RNA 3D structures

et al. 2007

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New methods are described for finding recurrent three-dimensional (3D) motifs in RNA atomicresolution structures. Recurrent RNA 3D motifs are sets of RNA nucleotides with similar spatial arrangements. They can be local or composite. Local motifs comprise nucleotides that occur in the same hairpin or internal loop. Composite motifs comprise nucleotides belonging to three or more different RNA strand segments or molecules. We use a base-centered approach to construct efficient, yet exhaustive search procedures using geometric, symbolic, or mixed representations of RNA structure that we implement in a suite of MATLAB programs, "Find RNA 3D" (FR3D). The first modules of FR3D preprocess structure files to classify base-pair and -stacking interactions. Each base is represented geometrically by the position of its glycosidic nitrogen in 3D space and by the rotation matrix that describes its orientation with respect to a common frame. Base-pairing and basestacking interactions are calculated from the base geometries and are represented symbolically according to the Leontis/Westhof basepairing classification, extended to include base-stacking. These data are stored and used to organize motif searches. For geometric searches, the user supplies the 3D structure of a query motif which FR3D uses to find and score geometrically similar candidate motifs, without regard to the sequential position of their nucleotides in the RNA chain or the identity of their bases. To score and rank candidate motifs, FR3D calculates a geometric discrepancy by rigidly rotating candidates to align optimally with the query motif and then comparing the relative orientations of the corresponding bases in the query and candidate motifs. Given the growing size of the RNA structure database, it is impossible to explicitly compute the discrepancy for all conceivable candidate motifs, even for motifs with less than ten nucleotides. The screening algorithm that we describe finds all candidate motifs whose geometric discrepancy with respect to the query motif falls below a user-specified cutoff discrepancy. This technique can be applied to NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscript RMSD searches. Candidate motifs identified geometrically may be further screened symbolically to identify those that contain particular basepair types or base-stacking arrangements or that conform to sequence continuity or nucleotide identity constraints. Purely symbolic searches for motifs containing user-defined sequence, continuity and interaction constraints have also been implemented. We demonstrate that FR3D finds all occurrences, both local and composite and with nucleotide substitutions, of sarcin/ricin and kink-turn motifs in the 23S and 5S ribosomal RNA 3D structures of the H. marismortui 50S ribosomal subunit and assigns the lowest discrepancy scores to bona fide examples of these motifs. The search algorithms have been optimized for speed to allow users to search the non-redundant RNA 3D structure database on a personal compute...

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Section: Building Lists Of Partial Candidates and The Screening Algormentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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FR3D: finding local and composite recurrent structural motifs in RNA 3D structures

et al. 2007

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“…Cluster analysis of root-mean-square deviations between pairs of RNA fragments has been used as the basis for cluster analysis of RNA loop structures to group tetraloops into various families (Huang et al 2005). A graph theoretic approach has been used to search for substructure patterns in RNA structures using a vectorial approach (Harrison et al 2003). Finally, the Structural Classification of RNA (SCOR), database has been developed to organize and classify RNA structural motifs (Klosterman et al 2002;Tamura et al 2004).…”

Section: Tools For Identifying and Classifying Elements And Motifsmentioning

confidence: 99%

RNA structural motifs: building blocks of a modular biomolecule

Hendrix

Brenner

Holbrook

2005

Quart. Rev. Biophys.

196

141

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Abstract. RNAs are modular biomolecules, composed largely of conserved structural subunits, or motifs. These structural motifs comprise the secondary structure of RNA and are knit together via tertiary interactions into a compact, functional, three-dimensional structure and are to be distinguished from motifs defined by sequence or function. A relatively small number of structural motifs are found repeatedly in RNA hairpin and internal loops, and are observed to be composed of a limited number of common 'structural elements '. In addition to secondary and tertiary structure motifs, there are functional motifs specific for certain biological roles and binding motifs that serve to complex metals or other ligands. Research is continuing into the identification and classification of RNA structural motifs and is being initiated to predict motifs from sequence, to trace their phylogenetic relationships and to use them as building blocks in RNA engineering.

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“…However, we have also made other contributions, e.g., in the application of chemoinformatics techniques to the representation and searching of biological macromolecules such as protein and RNA structures, [71][72][73][74][75] in the analysis of matched molecular pairs [76] and in charting the historical development of chemoinformatics and of its associated literature. [77][78][79][80] We have also sought to influence the development of the field by means of conferences and educational programmes.…”

Section: Other Contributionsmentioning

confidence: 99%