Riboswitch regulation in cyanobacteria is independent of their habitat adaptations

Cyanobacteria are one of the ancient bacterial species occupying a variety of habitats with diverse metabolic preferences. RNA regulators like riboswitches play significant role in controlling the gene expression in prokaryotes. The taxonomic distribution of riboswitches suggests that they might be one of the oldest mechanisms of gene control system. In this paper, we analyzed the distribution of different riboswitch families in various cyanobacterial genomes. It was observed that only four riboswitch classes were abundant in cyanobacteria, B₁₂-element (Cob)/AdoCbl/AdoCbl-variant riboswitch being the most abundant. The analysis suggests that riboswitch mode of regulation is present in cyanobacterial species irrespective of their habitat types. A large number of unidentified genes regulated by riboswitches listed in this analysis indicate the wide range of targets for these riboswitch families. The analysis revealed a large number of genes regulated by riboswitches which may assist in elaborating the diversity among the cyanobacterial species.     

Purine sensing by riboswitches.

Structured mRNA elements called riboswitches control gene expression by binding to small metabolites. Over a dozen riboswitch classes have been characterized that target a broad range of molecules and vary widely in size and secondary structure. Four of the known riboswitch classes recognize purines or modified purines. Three of these classes are closely related in conserved sequence and secondary structure, but members of these classes selectively recognize guanine, adenine or 2'-deoxyguanosine. Members of the fourth riboswitch class adopt a distinct structure to form a selective binding pocket for the guanine analogue preQ(1) (7-aminomethyl-7-deazaguanine). All four classes of purine-sensing riboswitches are most likely to recognize their respective metabolites by utilizing a riboswitch residue to make a canonical Watson-Crick base-pair with the ligand. This review will provide a summary of the purine-sensing riboswitches, as well as discuss the complex functions and applications of these RNAs.     

Purine sensing by riboswitches

Structured mRNA elements called riboswitches control gene expression by binding to small metabolites. Over a dozen riboswitch classes have been characterized that target a broad range of molecules and vary widely in size and secondary structure. Four of the known riboswitch classes recognize purines or modified purines. Three of these classes are closely related in conserved sequence and secondary structure, but members of these classes selectively recognize guanine, adenine or 2'-deoxyguanosine. Members of the fourth riboswitch class adopt a distinct structure to form a selective binding pocket for the guanine analogue preQ(1) (7-aminomethyl-7-deazaguanine). All four classes of purine-sensing riboswitches are most likely to recognize their respective metabolites by utilizing a riboswitch residue to make a canonical Watson-Crick base-pair with the ligand. This review will provide a summary of the purine-sensing riboswitches, as well as discuss the complex functions and applications of these RNAs.     

Rational design of artificial riboswitches based on ligand-dependent modulation of internal ribosome entry in wheat germ extract and their applications as label-free biosensors

Riboswitches are RNA elements in mRNA that control gene expression in cis in response to their specific ligands. Because artificial riboswitches make it possible to regulate any gene with an arbitrary molecule, they are expected to function as biosensors, in which the output is easily detectable protein expression. I report herein a fully rational design strategy for artificially constructing novel riboswitches that work in a eukaryotic cell-free translation system (wheat germ extract). In these riboswitches, translation mediated by an internal ribosome entry site (IRES) is promoted only in the presence of a specific ligand (ON), while it is inhibited in the absence of the ligand (OFF). The first rationally designed riboswitch, which is regulated by theophylline, showed a high switching efficiency and dependency on theophylline. In addition, based on the design of the theophylline-dependent riboswitch, other three kinds of riboswitches controlled by FMN, tetracycline, and sulforhodamine B, were constructed only by calculating the ΔG value of one stem-loop structure. The rational design strategy described herein is therefore useful for easily producing various ligand-dependent riboswitches, which are available as biosensors for detecting their ligands.     

Rational design of SAM analogues targeting SAM-II riboswitch aptamer

Riboswitches are noncoding RNA elements embedded in 5′-untranslated region of many bacterial mRNAs regulating gene expression in response to essential metabolites. They are unique from other RNA targets because they have evolved to form specific structural receptors for the purpose of binding small molecular metabolites suggesting that structure-based rational drug design approach may be used in designing metabolite mimics targeting riboswitches. We have developed a fluorescence binding assay for SAM-II riboswitch aptamer and identified an S-adenosylmethionine (SAM) analogue that selectively binds to SAM-II riboswitch aptamer with comparable binding affinity to its native metabolite using structure-based design approach.     

Structural insights into ligand recognition by a sensing domain of the cooperative glycine riboswitch

Glycine riboswitches regulate gene expression by feedback modulation in response to cooperative binding to glycine. Here, we report on crystal structures of the second glycine-sensing domain from the Vibrio cholerae riboswitch in the ligand-bound and unbound states. This domain adopts a three-helical fold that centers on a three-way junction and accommodates glycine within a bulge-containing binding pocket above the junction. Glycine recognition is facilitated by a pair of bound Mg(2+) cations and governed by specific interactions and shape complementarity with the pocket. A conserved adenine extrudes from the binding pocket and intercalates into the junction implying that glycine binding in the context of the complete riboswitch could impact on gene expression by stabilizing the riboswitch junction and regulatory P1 helix. Analysis of riboswitch interactions in the crystal and footprinting experiments indicates that adjacent glycine-sensing modules of the riboswitch could form specific interdomain interactions, thereby potentially contributing to the cooperative response.     

Common themes and differences in SAM recognition among SAM riboswitches

The recent discovery of short cis-acting RNA elements termed riboswitches has caused a paradigm shift in our understanding of genetic regulatory mechanisms. The three distinct superfamilies of S-adenosyl-l-methionine (SAM) riboswitches are the most commonly found riboswitch classes in nature. These RNAs represent three independent evolutionary solutions to achieve specific SAM recognition. This review summarizes research on 1) modes of gene regulatory mechanisms, 2) common themes and differences in ligand recognition, and 3) ligand-induced conformational dynamics among SAM riboswitch families. The body of work on the SAM riboswitch families constitutes a useful primer to the topic of gene regulatory RNAs as a whole.     

Atomistic basis for the on–off signaling mechanism in SAM-II riboswitch

Many bacterial genes are controlled by metabolite sensing motifs known as riboswitches, normally located in the 5′ un-translated region of their mRNAs. Small molecular metabolites bind to the aptamer domain of riboswitches with amazing specificity, modulating gene regulation in a feedback loop as a result of induced conformational changes in the expression platform. Here, we report the results of molecular dynamics simulation studies of the S-adenosylmethionine (SAM)-II riboswitch that is involved in regulating translation in sulfur metabolic pathways in bacteria. We show that the ensemble of conformations of the unbound form of the SAM-II riboswitch is a loose pseudoknot structure that periodically visits conformations similar to the bound form, and the pseudoknot structure is only fully formed upon binding the metabolite, SAM. The rate of forming contacts in the unbound form that are similar to that in the bound form is fast. Ligand binding to SAM-II alters the curvature and base-pairing of the expression platform that could affect the interaction of the latter with the ribosome.     

Structure and mechanism of purine-binding riboswitches

A riboswitch is a non-protein coding sequence capable of directly binding a small molecule effector without the assistance of accessory proteins to regulate expression of the mRNA in which it is embedded. Currently, over 20 different classes of riboswitches have been validated in bacteria with the promise of many more to come, making them an important means of regulating the genome in the bacterial kingdom. Strikingly, half of the known riboswitches recognize effector compounds that contain a purine or related moiety. In the last decade, significant progress has been made to determine how riboswitches specifically recognize these compounds against the background of many other similar cellular metabolites and transduce this signal into a regulatory response. Of the known riboswitches, the purine family containing guanine, adenine and 2'-deoxyguanosine-binding classes are the most extensively studied, serving as a simple and useful paradigm for understanding how these regulatory RNAs function. This review provides a comprehensive summary of the current state of knowledge regarding the structure and mechanism of these riboswitches, as well as insights into how they might be exploited as therapeutic targets and novel biosensors.     

Ligand binding and gene control characteristics of tandem riboswitches in Bacillus anthracis

Most riboswitches are composed of a single metabolite-binding aptamer and a single expression platform that function together to regulate genes in response to changing metabolite concentrations. In rare instances, two aptamers or sometimes two complete riboswitches reside adjacent to each other in untranslated regions (UTRs) of mRNAs. We have examined an example of a tandem riboswitch in the Gram-positive bacterium Bacillus anthracis that includes two complete riboswitches for thiamine pyrophosphate (TPP). Unlike other complex riboswitch systems described recently, tandem TPP riboswitches do not exhibit cooperative ligand binding and do not detect two different types of metabolites. In contrast, both riboswitches respond independently to TPP and are predicted to function in concert to mimic the more "digital" gene control outcome observed when two aptamers bind ligands cooperatively. Our findings further demonstrate that simple gene control elements made only of RNA can be assembled in different architectures to yield more complex gene control outcomes.