Abstract
The yjdF motif RNA is an orphan riboswitch candidate that almost exclusively associates with the yjdF protein-coding gene in many bacteria. The function of the YjdF protein is unknown, which has made speculation regarding the natural ligand for this putative riboswitch unusually challenging. By using a structure-probing assay for ligand binding, we found that a surprisingly broad diversity of nitrogen-containing aromatic heterocycles, or “azaaromatics,” trigger near-identical changes in the structures adopted by representative yjdF motif RNAs. Regions of the RNA that undergo ligand-induced structural modulation reside primarily in portions of the putative aptamer region that are highly conserved in nucleotide sequence, as is typical for riboswitches. Some azaaromatic molecules are bound by the RNA with nanomolar dissociation constants, and a subset of these ligands activate riboswitch-mediated gene expression in cells. Furthermore, genetic elements most commonly adjacent to the yjdF motif RNA or to the yjdF protein-coding region are homologous to protein regulators implicated in mitigating the toxic effects of diverse phenolic acids or polycyclic compounds. Although the precise type of natural ligand sensed by yjdF motif RNAs remains unknown, our findings suggest that this riboswitch class might serve as part of a genetic response system to toxic or signaling compounds with chemical structures similar to azaaromatics.
Highlights
Over 30 distinct riboswitch classes have been discovered that sense and respond to numerous metabolites and ions (Zhang et al 2010; Breaker 2011; Serganov and Nudler 2013)
Members of each riboswitch class can serve as model systems to reveal, at atomic resolution, how RNAs can form selective receptors for their natural ligands, and how ligand binding is translated into gene regulation events (Garst et al 2011; Serganov and Patel 2012)
YjdF motif RNAs were found only in bacterial species classified as Firmicutes (Weinberg et al 2010)
Summary
Over 30 distinct riboswitch classes have been discovered that sense and respond to numerous metabolites and ions (Zhang et al 2010; Breaker 2011; Serganov and Nudler 2013). Among the most common riboswitch classes are those that respond to ligands serving fundamental roles in the metabolism of all organisms, including numerous coenzymes, amino acids, and nucleotide derivatives. Each of these novel riboswitch classes provides opportunities to establish new pathways for gene regulation. The discovery of fluoride riboswitches in many members of two domains of life (Baker et al 2012) has revealed a large collection of genes whose functions are related to overcoming fluoride toxicity. Without knowledge of this fluoride-binding RNA, the functions of many of these genes would have remained mysterious
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