Using RNA secondary structures to guide sequence motif finding towards single-stranded regions

Hiller, Michael; Pudimat, Rainer; Busch, Anke; Backofen, Rolf

doi:10.1093/nar/gkl544

Cited by 154 publications

(158 citation statements)

References 32 publications

(45 reference statements)

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“…Cold Spring Harbor Laboratory Press on May 10, 2018 -Published by rnajournal.cshlp.org Downloaded from (Hiller et al 2006), allowing partial pairing of putative RBP binding sites significantly reduces in vivo predictive accuracy for six RBPs. Five of these RBPs have previously been reported to require their entire binding site to be unpaired, strongly suggesting that the sixth, Khd1p, will have a similar requirement.…”

Section: Discussionmentioning

confidence: 99%

“…The method we employed, as proposed by Hackermuller and coworkers (Hackermuller et al 2005), requires the whole site to be unpaired for the protein to bind. However, other methods, including the EF option of MEMERIS (Hiller et al 2006), and some methods used to predict target site accessibility for miRNAs (Robins et al 2005;Ellis et al 2007;Kertesz et al 2007;Long et al 2007;Geis et al 2008;Tafer et al 2008), allow target sites to be partially paired. To determine which of these approaches most accurately predicts in vivo RBP binding, we compared transcripts scored by #ATS based on the accessibility of the whole target site and those scored by #ATS when target site accessibility was approximated by either the average or the minimum single-base accessibility of all bases in the target site.…”

Section: Improvement Due To Accessibility Is Not Explained By Nucleotmentioning

confidence: 99%

“…A role for accessibility in RBP binding has long been supported by in vitro selection (Levine et al 1993;Gao et al 1994) and measurements of in vitro binding affinity (Hackermuller et al 2005). More recently, motiffinding algorithms have been developed that use measures of RNA single-strandedness to more accurately recover some RBP motifs from in vitro selection binding data (Hiller et al 2006). In all cases, computational models of RNA folding were used to predict RNA secondary structure.…”

Section: Introductionmentioning

confidence: 99%

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Predicting in vivo binding sites of RNA-binding proteins using mRNA secondary structure

Quon

Lipshitz

et al. 2010

RNA

155

171

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While many RNA-binding proteins (RBPs) bind RNA in a sequence-specific manner, their sequence preferences alone do not distinguish known target RNAs from other potential targets that are coexpressed and contain the same sequence motifs. Recently, the mRNA targets of dozens of RNA-binding proteins have been identified, facilitating a systematic study of the features of target transcripts. Using these data, we demonstrate that calculating the predicted structural accessibility of a putative RBP binding site allows one to significantly improve the accuracy of predicting in vivo binding for the majority of sequence-specific RBPs. In our new in silico approach, accessibility is predicted based solely on the mRNA sequence without consideration of the locations of bound trans-factors; as such, our results suggest a greater than previously anticipated role for intrinsic mRNA secondary structure in determining RBP binding target preference. Target site accessibility aids in predicting target transcripts and the binding sites for RBPs with a range of RNA-binding domains and subcellular functions. Based on this work, we introduce a new motif-finding algorithm that identifies accessible sequence-specific RBP motifs from in vivo binding data.

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Section: Discussionmentioning

confidence: 99%

Section: Improvement Due To Accessibility Is Not Explained By Nucleotmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Predicting in vivo binding sites of RNA-binding proteins using mRNA secondary structure

Quon

Lipshitz

et al. 2010

RNA

155

171

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“…Our goal was to try all methods that could be applicable on sets of coregulated nonaligned transcripts (for discussion of limitations, see the Introduction). We considered GPRM (Hu 2003), GeRNAMo (Michal et al 2007), CMfinder (Yao et al 2006), comRNA (Ji et al 2004), MEME (Bailey et al 2006), MEMERIS (Hiller et al 2006), and RNA Sampler (Xu et al 2007). Among these, our computational resources (Linux cluster allowing up to 90 GB of RAM) permitted us to use CMfinder, MEME, and MEMERIS (although we could not use MEMERIS on all possible element lengths due to computation time restrictions) (see Materials and Methods).…”

Section: Performance Of Complementary Methodsmentioning

confidence: 99%

“…MEMERIS (MEME in RNAs including secondary structures) is an extension of MEME. MEMERIS computes the probabilities of unpaired bases and then uses this measure to guide element finding in single-stranded regions (Hiller et al 2006). As methods based only on sequence conservation could be used to search a set of coregulated transcripts, this raises the question of whether currently available TFBS detection methods could accurately and efficiently detect mRNA elements, which are often defined not only by sequence but also by combinations of sequence and structure.…”

Section: Introductionmentioning

confidence: 99%

Regulatory element identification in subsets of transcripts: Comparison and integration of current computational methods

Fan

Bitterman

Larsson

2009

RNA

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Regulatory elements in mRNA play an often pivotal role in post-transcriptional regulation of gene expression. However, a systematic approach to efficiently identify putative regulatory elements from sets of post-transcriptionally coregulated genes is lacking, hampering studies of coregulation mechanisms. Although there are several analytical methods that can be used to detect conserved mRNA regulatory elements in a set of transcripts, there has been no systematic study of how well any of these methods perform individually or as a group. We therefore compared how well three algorithms, each based on a different principle (enumeration, optimization, or structure/sequence profiles), can identify elements in unaligned untranslated sequence regions. Two algorithms were originally designed to detect transcription factor binding sites, Weeder and BioProspector; and one was designed to detect RNA elements conserved in structure, RNAProfile. Three types of elements were examined: (1) elements conserved in both primary sequence and secondary structure; (2) elements conserved only in primary sequence; and (3) microRNA targets. Our results indicate that all methods can uniquely identify certain known RNA elements, and therefore, integrating the output from all algorithms leads to the most complete identification of elements. We therefore developed an approach to integrate results and guide selection of candidate elements from several algorithms presented as a web service (https://dbw.msi.umn.edu:8443/recit). These findings together with the approach for integration can be used to identify candidate elements from genome-wide post-transcriptional profiling data sets.

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Analysis of Pre‐mRNA Secondary Structures and Alternative Splicing

Hiller

2012

Alternative Pre‐mRNA Splicing

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Using RNA secondary structures to guide sequence motif finding towards single-stranded regions

Cited by 154 publications

References 32 publications

Predicting in vivo binding sites of RNA-binding proteins using mRNA secondary structure

Predicting in vivo binding sites of RNA-binding proteins using mRNA secondary structure

Regulatory element identification in subsets of transcripts: Comparison and integration of current computational methods

Analysis of Pre‐mRNA Secondary Structures and Alternative Splicing

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