Abstract
BackgroundStructured noncoding RNAs (ncRNAs) play essential roles in many biological processes such as gene regulation, signaling, RNA processing, and protein synthesis. Among the most common groups of ncRNAs in bacteria are riboswitches. These cis-regulatory, metabolite-binding RNAs are present in many species where they regulate various metabolic and signaling pathways. Collectively, there are likely to be hundreds of novel riboswitch classes that remain hidden in the bacterial genomes that have already been sequenced, and potentially thousands of classes distributed among various other species in the biosphere. The vast majority of these undiscovered classes are proposed to be exceedingly rare, and so current bioinformatics search techniques are reaching their limits for differentiating between true riboswitch candidates and false positives.ResultsHerein, we exploit a computational search pipeline that can efficiently identify intergenic regions most likely to encode structured ncRNAs. Application of this method to five bacterial genomes yielded nearly 70 novel genetic elements including 30 novel candidate ncRNA motifs. Among the riboswitch candidates identified is an RNA motif involved in the regulation of thiamin biosynthesis.ConclusionsAnalysis of other genomes will undoubtedly lead to the discovery of many additional novel structured ncRNAs, and provide insight into the range of riboswitches and other kinds of ncRNAs remaining to be discovered in bacteria and archaea.
Highlights
Structured noncoding RNAs play essential roles in many biological processes such as gene regulation, signaling, RNA processing, and protein synthesis
Ongoing efforts to discover and characterize noncoding RNAs in bacteria and archaea are expanding our understanding of gene regulation and are revealing new aspects of biology
Choosing genomes for complete analysis by the GC-Intergenic Region (IGR) bioinformatics pipeline GC-IGR analyses were initiated by first examining the properties of 2807 bacterial genomes
Summary
Structured noncoding RNAs (ncRNAs) play essential roles in many biological processes such as gene regulation, signaling, RNA processing, and protein synthesis. Computational discovery approaches, along with more traditional bacterial genetics methods, have led to the experimental validation of over 40 distinct riboswitch classes that respond to small metabolite or ion ligands [8]. Data derived from these initial finds has been used to support the prediction that perhaps thousands of additional riboswitch classes await detection [1, 8,9,10]. Numerous guanidine toxicity resistance genes were initially uncovered by establishing the existence of a series of guanidine-sensing riboswitches [13, 20, 21]
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