A new method to predict the consensus secondary structure of a set of unaligned RNA sequences

Thermodynamic processes with free energy parameters are often used in algorithms that solve the free energy minimization problem to predict secondary structures of single RNA sequences. While results from these algorithms are promising, an observation is that single sequence-based methods have moderate accuracy and more information is needed to improve on RNA secondary structure prediction, such as covariance scores obtained from multiple sequence alignments. We present in this paper a new approach to predicting the consensus secondary structure of a set of aligned RNA sequences via pseudo-energy minimization. Our tool, called RSpredict, takes into account sequence covariation and employs effective heuristics for accuracy improvement. RSpredict accepts, as input data, a multiple sequence alignment in FASTA or ClustalW format and outputs the consensus secondary structure of the input sequences in both the Vienna style Dot Bracket format and the Connectivity Table format. Our method was compared with some widely used tools including KNetFold, Pfold and RNAalifold. A comprehensive test on different datasets including Rfam sequence alignments and a multiple sequence alignment obtained from our study on the Drosophila X chromosome reveals that RSpredict is competitive with the existing tools on the tested datasets. RSpredict is freely available online as a web server and also as a jar file for download at http://datalab.njit.edu/biology/RSpredict .

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A weighted sampling algorithm for the design of RNA sequences with targeted secondary structure and nucleotide distribution

Bioinformatics ◽

10.1093/bioinformatics/btt217 ◽

2013 ◽

Vol 29 (13) ◽

pp. i308-i315 ◽

Cited By ~ 27

Author(s):

Vladimir Reinharz ◽

Yann Ponty ◽

Jérôme Waldispühl

Keyword(s):

Secondary Structure ◽

Rna Sequences ◽

Sampling Algorithm

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Partial characterization of an RNA component that copurifies with Saccharomyces cerevisiae RNase P

Molecular and Cellular Biology ◽

10.1128/mcb.9.6.2536-2543.1989 ◽

1989 ◽

Vol 9 (6) ◽

pp. 2536-2543

Author(s):

J Y Lee ◽

D R Engelke

Keyword(s):

Saccharomyces Cerevisiae ◽

Secondary Structure ◽

Schizosaccharomyces Pombe ◽

Rnase P ◽

Partial Characterization ◽

Rna Sequences ◽

Extensive Sequence ◽

Sequence Similarities

Saccharomyces cerevisiae cellular RNase P is composed of both protein and RNA components that are essential for activity. The isolated holoenzyme contains a highly structured RNA of 369 nucleotides that has extensive sequence similarities to the 286-nucleotide RNA associated with Schizosaccharomyces pombe RNase P but bears little resemblance to the analogous RNA sequences in procaryotes or S. cerevisiae mitochondria. Even so, the predicted secondary structure of S. cerevisiae RNA is strikingly similar to the bacterial phylogenetic consensus rather than to previously predicted structures of other eucaryotic RNase P RNAs.

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Modified S-transform as a tool to identify secondary structure elements in RNA

Bio-Algorithms and Med-Systems ◽

10.1515/bams-2017-0023 ◽

2017 ◽

Vol 13 (4) ◽

Author(s):

Nancy Singh ◽

Sunil Datt Sharma ◽

Ragothaman M. Yennamalli

Keyword(s):

Signal Processing ◽

Secondary Structure ◽

Dna Sequences ◽

Tertiary Structure ◽

Processing Method ◽

Rna Sequences ◽

Signal Processing Method ◽

S Transform ◽

Highly Correlated ◽

Signal Processing Methods

AbstractIn this article, we describe the applicability of a signal processing method, specifically the modified S-transform (MST) method, on RNA sequences to identify periodicities between 2 and 11. MicroRNAs (miRNA) are associated with gene regulation and gene silencing and thus have wide applications in biological sciences. Also, the functionality of miRNA is highly associated with its secondary structures (stem, bulge and loop). Signal processing methods have been previously applied on genomic data to reveal the periodicities that determine a wide variety of biological functions, ranging from exon detection to microsatellite identification in DNA sequences. However, there has been less focus on RNA-based signal processing. Here, we show that the signal processing method can be successfully applied to miRNA sequences. We observed that these periodicities are highly correlated with the secondary structure of miRNA and such methods could possibly be used as indicators of secondary and tertiary structure formation.

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TOPAS: network-based structural alignment of RNA sequences

Bioinformatics ◽

10.1093/bioinformatics/btz001 ◽

2019 ◽

Vol 35 (17) ◽

pp. 2941-2948 ◽

Cited By ~ 2

Author(s):

Chun-Chi Chen ◽

Hyundoo Jeong ◽

Xiaoning Qian ◽

Byung-Jun Yoon

Keyword(s):

Computational Complexity ◽

Secondary Structure ◽

Large Scale ◽

Structural Alignment ◽

Programming Approach ◽

Rna Sequences ◽

Optimal Sequence ◽

Dynamic Programming Approach ◽

Probabilistic Network ◽

Rna Structural Alignment

Abstract Motivation For many RNA families, the secondary structure is known to be better conserved among the member RNAs compared to the primary sequence. For this reason, it is important to consider the underlying folding structures when aligning RNA sequences, especially for those with relatively low sequence identity. Given a set of RNAs with unknown structures, simultaneous RNA alignment and folding algorithms aim to accurately align the RNAs by jointly predicting their consensus secondary structure and the optimal sequence alignment. Despite the improved accuracy of the resulting alignment, the computational complexity of simultaneous alignment and folding for a pair of RNAs is O(N6), which is too costly to be used for large-scale analysis. Results In order to address this shortcoming, in this work, we propose a novel network-based scheme for pairwise structural alignment of RNAs. The proposed algorithm, TOPAS, builds on the concept of topological networks that provide structural maps of the RNAs to be aligned. For each RNA sequence, TOPAS first constructs a topological network based on the predicted folding structure, which consists of sequential edges and structural edges weighted by the base-pairing probabilities. The obtained networks can then be efficiently aligned by using probabilistic network alignment techniques, thereby yielding the structural alignment of the RNAs. The computational complexity of our proposed method is significantly lower than that of the Sankoff-style dynamic programming approach, while yielding favorable alignment results. Furthermore, another important advantage of the proposed algorithm is its capability of handling RNAs with pseudoknots while predicting the RNA structural alignment. We demonstrate that TOPAS generally outperforms previous RNA structural alignment methods on RNA benchmarks in terms of both speed and accuracy. Availability and implementation Source code of TOPAS and the benchmark data used in this paper are available at https://github.com/bjyoontamu/TOPAS.

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Predicting RNA Secondary Structure Using a Improved BPSO Based on Stem Combination

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.325-326.1551 ◽

2013 ◽

Vol 325-326 ◽

pp. 1551-1554

Author(s):

Yi Qi

Keyword(s):

Secondary Structure ◽

Sensitivity And Specificity ◽

Rna Structure ◽

Structure Prediction ◽

Rna Secondary Structure ◽

Experimental Results ◽

New Method ◽

Rna Structure Prediction ◽

New Strategies

In this paper, we present an improved BPSO to predict RNA secondary structure to improve the performance with two new strategies. First one is to reduce the searching space of PSO through super stem set construction. Second is to modify the general BPSO updating process to settle stem permutation and combination problems. The experimental results show that the new method is effective for RNA structure prediction in terms of sensitivity and specificity by different sequence datasets including simple pseudoknot.

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Using small samples to estimate neutral component size and robustness in the genotype–phenotype map of RNA secondary structure

Journal of The Royal Society Interface ◽

10.1098/rsif.2019.0784 ◽

2020 ◽

Vol 17 (166) ◽

pp. 20190784 ◽

Cited By ~ 1

Author(s):

Marcel Weiß ◽

Sebastian E. Ahnert

Keyword(s):

Secondary Structure ◽

Rna Secondary Structure ◽

Point Mutations ◽

Local Environment ◽

Small Samples ◽

Sequence Length ◽

Rna Sequences ◽

Component Size ◽

Naturally Occurring ◽

Non Coding Rna

In genotype–phenotype (GP) maps, the genotypes that map to the same phenotype are usually not randomly distributed across the space of genotypes, but instead are predominantly connected through one-point mutations, forming network components that are commonly referred to as neutral components (NCs). Because of their impact on evolutionary processes, the characteristics of these NCs, like their size or robustness, have been studied extensively. Here, we introduce a framework that allows the estimation of NC size and robustness in the GP map of RNA secondary structure. The advantage of this framework is that it only requires small samples of genotypes and their local environment, which also allows experimental realizations. We verify our framework by applying it to the exhaustively analysable GP map of RNA sequence length L = 15, and benchmark it against an existing method by applying it to longer, naturally occurring functional non-coding RNA sequences. Although it is specific to the RNA secondary structure GP map in the first place, our framework can probably be transferred and adapted to other sequence-to-structure GP maps.

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AMINOACRIDINE DYES AND THE SECONDARY STRUCTURE OF DNA IN SITU

Journal of Histochemistry & Cytochemistry ◽

10.1177/19.12.761 ◽

1971 ◽

Vol 19 (12) ◽

pp. 761-765 ◽

Cited By ~ 2

Author(s):

MANUEL DIAZ ◽

JOSE HIERRO ◽

GRACIELA DEMICHELI DE DIAZ

Keyword(s):

Secondary Structure ◽

Acid Solution ◽

Nitrous Acid ◽

Deoxyribonucleic Acid ◽

New Method ◽

Green Fluorescence ◽

Double Stranded Dna

A new method is proposed to study the secondary structure of deoxyribonucleic acid (DNA) in situ in fixed chromatin. It is based on acriflavine staining and on differentiation with a nitrous acid solution of the fixed cytologic preparation. The presence of green fluorescence after this treatment is regarded as indicative of double stranded DNA. Experiments are described with DNA-acriflavine mixtures in solution, DNA-agar models and cytologic preparations submitted to different pretreatments. The feasibility and limitations of the method are discussed in the light of the results reported upon.

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A New Method to Predict RNA Secondary Structure Based on RNA Folding Simulation

IEEE/ACM Transactions on Computational Biology and Bioinformatics ◽

10.1109/tcbb.2015.2496347 ◽

2016 ◽

Vol 13 (5) ◽

pp. 990-995 ◽

Cited By ~ 4

Author(s):

Yuanning Liu ◽

Qi Zhao ◽

Hao Zhang ◽

Rui Xu ◽

Yang Li ◽

...

Keyword(s):

Secondary Structure ◽

Rna Secondary Structure ◽

Rna Folding ◽

New Method ◽

Folding Simulation

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CSSP(Consensus Secondary Structure Prediction): a web-based server for structural biologists

Journal of Applied Crystallography ◽

10.1107/s0021889808043847 ◽

2009 ◽

Vol 42 (2) ◽

pp. 336-338 ◽

Cited By ~ 6

Author(s):

Ankit Gupta ◽

Avnish Deshpande ◽

Janardhan Kumar Amburi ◽

Radhakrishnan Sabarinathan ◽

Ramaswamy Senthilkumar ◽

...

Keyword(s):

Secondary Structure ◽

Structure Prediction ◽

Secondary Structure Prediction ◽

Three Dimensional ◽

Web Server ◽

Dimensional Structure ◽

Structural Elements ◽

Web Based ◽

Consensus Secondary Structure ◽

Helical Wheel

Sequence–structure correlation studies are important in deciphering the relationships between various structural aspects, which may shed light on the protein-folding problem. The first step of this process is the prediction of secondary structure for a protein sequence of unknown three-dimensional structure. To this end, a web server has been created to predict the consensus secondary structure using well known algorithms from the literature. Furthermore, the server allows users to see the occurrence of predicted secondary structural elements in other structure and sequence databases and to visualize predicted helices as a helical wheel plot. The web server is accessible at http://bioserver1.physics.iisc.ernet.in/cssp/.

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