Summary
The untranslated regions (UTRs) of many mRNAs contain sequence and structural motifs that are used to regulate the stability, localization, and translatability of the mRNA. It should be possible to discover previously unidentified RNA regulatory motifs by examining many related nucleotide sequences, which are assumed to contain a common motif. This is a general practice for discovery of DNA-based sequence-based patterns, in which alignment tools are heavily exploited. However, because of the complexity of sequential and structural components of RNA-based motifs, simple-alignment tools are frequently inadequate. The consensus sequences they find frequently have the potential for significant variability at any given position and are only loosely characterized. The development of RNA-motif discovery tools that infer and integrate structural information into motif discovery is both necessary and expedient. Here, we provide a selected list of existing web-accessible algorithms for the discovery of RNA motifs, which, although not exhaustive, represents the current state of the art. To facilitate the development, evaluation, and training of new software programs that identify RNA motifs, we created the UAlbany training UTR (TUTR) database, which is a collection of validated sets of sequences containing experimentally defined regulatory motifs. Presently, eleven training sets have been generated with associated indexes and “answer sets” provided that identify where the previously characterized RNA motif [the iron responsive element (IRE), AU-rich class-2 element (ARE), selenocysteine insertion sequence (SECIS), etc.] resides in each sequence. The UAlbany TUTR collection is a shared resource that is available to researchers for software development and as a research aid.
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Acknowledgments
We acknowledge the helpful input from Timothy Baroni, Jennifer Bean, David Tuck, Georgi Shablovski, and the rest of the Tenenbaum lab. This research was supported by National Institute of Health National Human Genome Research Institute grant R21 HG003679.
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Doyle, F., Zaleski, C., George, A.D., Stenson, E.K., Ricciardi, A., Tenenbaum, S.A. (2008). Bioinformatic Tools for Studying Post-Transcriptional Gene Regulation: The UAlbany TUTR Collection and Other Informatic Resources . In: Wilusz, J. (eds) Post-Transcriptional Gene Regulation. Methods In Molecular Biology™, vol 419. Humana Press. https://doi.org/10.1007/978-1-59745-033-1_3
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DOI: https://doi.org/10.1007/978-1-59745-033-1_3
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