Reconstruction of Natural RNA Sequences from RNA Shape, Thermodynamic Stability, Mutational Robustness, and Linguistic Complexity by Evolutionary Computation

Dromi, Nir; Avihoo, A.; Barash, Danny

doi:10.1080/07391102.2008.10507231

Cited by 16 publications

(17 citation statements)

References 26 publications

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“…The comparison depicted in Figure 4 was performed for an miR-146 example test case taken from [15], after it was verified in [9] by taking a collection of miRNAs from the microRNA registry [16] that miRNA precursors are significantly more thermodynamically stable and mutationally robust than random RNAs. Therefore, even though from an initial inspection of the structure drawings in Figure 4 it may appear that the RNAinverse result is in better agreement to the wild-type than the RNAexinv result, it should be noted that the values of the thermodynamic stability and mutational robustness of miR-146 are not taken into account when designing sequences with RNAinverse.…”

Section: Resultsmentioning

confidence: 99%

“…To incorporate the physical measures listed above as constraints in the inverse RNA folding problem, the problem must first be relaxed from secondary structure to shape, as our previous simulations showed that such constraints can yield no solution [9]. Thus, instead of the RNA secondary structure, we used the simplified coarse-grained representation [13,14] as its shape.…”

Section: Methodsmentioning

confidence: 99%

“…It should be noted that both RNAinverse [5] and INFO-RNA [7] contain a p-mode option, where the objective function is including the probability that the target structure forms, thus considering thermodynamic stability. Recently, inspired by the physical aspects of RNA secondary structure [8], an extended inverse RNA folding problem was suggested [9], which adds several non-structural constraints to the desired output in conjunction such as thermodynamic stability and mutational robustness. This extension may help incorporate some important properties of natural RNAs to the design problem.…”

Section: Introductionmentioning

confidence: 99%

“…Unlike the method in [9] that utilizes parallel evolutionary computation and is relatively expensive, the method described here is closer in type to [5-7] and significantly reduces the computation time relative to [9]. It comprises two phases, the first of which is to identify a good initial candidate whose folding closely resembles that of the desired structure.…”

Section: Introductionmentioning

confidence: 99%

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RNAexinv: An extended inverse RNA folding from shape and physical attributes to sequences

2011

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BackgroundRNAexinv is an interactive java application that performs RNA sequence design, constrained to yield a specific RNA shape and physical attributes. It is an extended inverse RNA folding program with the rationale behind that the generated sequences should not only fold into a desired structure, but they should also exhibit favorable attributes such as thermodynamic stability and mutational robustness. RNAexinv considers not only the secondary structure in order to design sequences, but also the mutational robustness and the minimum free energy. The sequences that are generated may not fully conform with the given RNA secondary structure, but they will strictly conform with the RNA shape of the given secondary structure and thereby take into consideration the recommended values of thermodynamic stability and mutational robustness that are provided.ResultsThe output consists of designed sequences that are generated by the proposed method. Selecting a sequence displays the secondary structure drawings of the target and the predicted fold of the sequence, including some basic information about the desired and achieved thermodynamic stability and mutational robustness. RNAexinv can be used successfully without prior experience, simply specifying an initial RNA secondary structure in dot-bracket notation and numerical values for the desired neutrality and minimum free energy. The package runs under LINUX operating system. Secondary structure predictions are performed using the Vienna RNA package.ConclusionsRNAexinv is a user friendly tool that can be used for RNA sequence design. It is especially useful in cases where a functional stem-loop structure of a natural sequence should be strictly kept in the designed sequences but a distant motif in the rest of the structure may contain one more or less nucleotide at the expense of another, as long as the global shape is preserved. This allows the insertion of physical observables as constraints. RNAexinv is available at http://www.cs.bgu.ac.il/~RNAexinv.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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RNAexinv: An extended inverse RNA folding from shape and physical attributes to sequences

2011

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“…In particular, in many viruses it is RNA that contains genetic information of virus such as HIV and therefore regulates the functions of such virus. RNA has recently become the center of much attention because of its catalytic properties, leading to an increased interest in obtaining structural information (1)(2)(3)(4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14)(15)(16)(17)(18). Although more and more RNA secondary structures have been accumulated, we know little about their functions.…”

Section: Introductionmentioning

confidence: 99%

A Complexity-based Method to Compare RNA Secondary Structures and its Application

Zhang

Wang

2010

Journal of Biomolecular Structure and Dynamics

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With the rapid emergence of RNA structure databases recently, efficient methods for RNA structure comparison are in demand for function prediction and evolutionary analysis. In this paper, we transform the complex secondary structure into the linear characteristic sequence which contains the information on primary sequence and the base pairing, and introduce the linear characteristic sequences into similarity analysis and phylogenetic analysis by using conditional LZ complexity. The results obtained from the two sets of real data have shown that our proposed method is effectual and feasible.

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Data mining of functional RNA structures in genomic sequences

Shapiro

2011

WIREs Data Min & Knowl

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The normal functions of genomes depend on the precise expression of messenger RNAs and noncoding RNAs (ncRNAs) such as transfer RNAs and microRNAs in eukaryotes. These ncRNAs and functional RNA structures (FRSs) act as regulators or response elements for cellular factors and participate in transcription, posttranscriptional processing, and translation. Knowledge discovery of these FRSs in huge DNA/RNA sequence databases is a very important step to reach our goal of going from genomic sequence data to biological knowledge for understanding RNA‐based regulation. Analyses of a large number of FRSs have indicated that the FRS can be well characterized by some quantitative measures such as significance and well‐ordered scores of the local segment. Various data mining tools have been developed and successfully applied to FRS discovery in genomic sequence databases. Here, we summarize our efforts in the computational discovery of structured features of ncRNAs and FRSs within complex genomes by EDscan and SigED. © 2011 John Wiley & Sons, Inc. WIREs Data Mining Knowl Discov 2011 1 88–95 DOI: 10.1002/widm.13 This article is categorized under: Algorithmic Development > Biological Data Mining Algorithmic Development > Spatial and Temporal Data Mining Application Areas > Health Care Technologies > Structure Discovery and Clustering

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Reconstruction of Natural RNA Sequences from RNA Shape, Thermodynamic Stability, Mutational Robustness, and Linguistic Complexity by Evolutionary Computation

Cited by 16 publications

References 26 publications

RNAexinv: An extended inverse RNA folding from shape and physical attributes to sequences

RNAexinv: An extended inverse RNA folding from shape and physical attributes to sequences

A Complexity-based Method to Compare RNA Secondary Structures and its Application

Data mining of functional RNA structures in genomic sequences

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