Abstract
BackgroundNon-coding RNAs (ncRNAs) have a multitude of roles in the cell, many of which remain to be discovered. However, it is difficult to detect novel ncRNAs in biochemical screens. To advance biological knowledge, computational methods that can accurately detect ncRNAs in sequenced genomes are therefore desirable. The increasing number of genomic sequences provides a rich dataset for computational comparative sequence analysis and detection of novel ncRNAs.ResultsHere, Dynalign, a program for predicting secondary structures common to two RNA sequences on the basis of minimizing folding free energy change, is utilized as a computational ncRNA detection tool. The Dynalign-computed optimal total free energy change, which scores the structural alignment and the free energy change of folding into a common structure for two RNA sequences, is shown to be an effective measure for distinguishing ncRNA from randomized sequences. To make the classification as a ncRNA, the total free energy change of an input sequence pair can either be compared with the total free energy changes of a set of control sequence pairs, or be used in combination with sequence length and nucleotide frequencies as input to a classification support vector machine. The latter method is much faster, but slightly less sensitive at a given specificity. Additionally, the classification support vector machine method is shown to be sensitive and specific on genomic ncRNA screens of two different Escherichia coli and Salmonella typhi genome alignments, in which many ncRNAs are known. The Dynalign computational experiments are also compared with two other ncRNA detection programs, RNAz and QRNA.ConclusionThe Dynalign-based support vector machine method is more sensitive for known ncRNAs in the test genomic screens than RNAz and QRNA. Additionally, both Dynalign-based methods are more sensitive than RNAz and QRNA at low sequence pair identities. Dynalign can be used as a comparable or more accurate tool than RNAz or QRNA in genomic screens, especially for low-identity regions. Dynalign provides a method for discovering ncRNAs in sequenced genomes that other methods may not identify. Significant improvements in Dynalign runtime have also been achieved.
Highlights
IntroductionNon-coding RNAs (ncRNAs) have a multitude of roles in the cell, many of which remain to be discovered
Non-coding RNAs have a multitude of roles in the cell, many of which remain to be discovered
Novel ncRNAs are difficult to detect in conventional biochemical screens [19]: they are frequently short [18,20], often not polyadenylated [19], and might only be expressed under specific cellular conditions [20,21,22]
Summary
Non-coding RNAs (ncRNAs) have a multitude of roles in the cell, many of which remain to be discovered. It is difficult to detect novel ncRNAs in biochemical screens. Computational methods that can accurately detect ncRNAs in sequenced genomes are desirable. The increasing number of genomic sequences provides a rich dataset for computational comparative sequence analysis and detection of novel ncRNAs. RNA plays many important biological roles other than as a transient carrier of amino acid sequence information. It is desirable to develop high-throughput methods for discovery of novel ncRNAs for greater biological understanding and for discovering candidate drug targets. Considering the number of available whole genome sequences [31,32,33,34,35,36,37], this approach can be applied to a large and diverse dataset, and has massive potential for novel ncRNA discovery
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