Mutational analysis of a signaling aptamer suggests a mechanism for ligand-triggered structure-switching.

Structure-switching signaling aptamers are nucleic acids that change shape upon binding to a specific ligand. Previously, we applied a new in vitro selection strategy to isolate structure-switching RNA aptamers responsive to the aminoglycoside antibiotic tobramycin. Here, we report the results of mutational analysis, secondary structure modeling, and ligand-specificity studies that suggest a mechanism for tobramycin-triggered structure switching.

Sensitive and specific detection of ligands using engineered riboswitches.

Riboswitches are RNA elements found in non-coding regions of messenger RNAs that regulate gene expression through a ligand-triggered conformational change. Riboswitches typically bind tightly and specifically to their ligands, so they have the potential to serve as highly effective sensors in vitro. In B. subtilis and other gram-positive bacteria, purine nucleotide synthesis is regulated by riboswitches that bind to guanine. We modified the xpt-pbuX guanine riboswitch for use in a fluorescence quenching assay that allowed us to specifically detect and quantify guanine in vitro. Using this assay, we reproducibly detected as little as 5 nM guanine. We then produced sensors for 2'-deoxyguanosine and cyclic diguanylate (c-diGMP) by appending the P1 stem of the guanine riboswitch to the ligand-binding domains of a 2'-deoxyguanosine riboswitch and a c-diGMP riboswitch. These hybrid sensors could detect 15 nM 2'-deoxyguanosine and 3 nM c-diGMP, respectively. Each sensor retained the ligand specificity of its corresponding natural riboswitch. In order to extend the utility of our approach, we developed a strategy for the in vitro selection of sensors with novel ligand specificity. Here we report a proof-of-principle experiment that demonstrated the feasibility of our selection strategy.

Identification of substrates for adenosine deaminases that act on RNA.

Adenosine deaminases that acts on RNA (ADARs) are RNA-editing enzymes that convert adenosine to inosine in double-stranded RNA. This chapter provides a detailed protocol for identifying inosine-containing RNAs. Candidate ADAR substrates are identified by cleaving poly (A)+ RNA specifically after inosine and using differential display to detect cleaved molecules. To confirm the presence of inosine, each individual candidate substrate is amplified by reverse transcriptase polymerase chain reaction (RT-PCR) and the PCR product is directly sequenced. Sites that contain inosine at the RNA level appear as a mixture of adenosine and guanosine in the cDNA. The relative peak areas provide an estimate of the extent of editing at each site.

Direct selection of RNA beacon aptamers.

A method for the direct selection of RNA molecules that can be easily converted into beacon aptamers is presented. Beacon aptamers are fluorescently labeled nucleic acids that signal the presence of a specific ligand through changes in fluorescence intensity. Typically, ligand binding causes an increase in fluorescence intensity by inducing a conformational change that separates a fluorophore/quencher pair. The method presented here simultaneously selects for ligand binding and induction of an appropriate conformational change. The method was tested by selecting RNA molecules that can detect the aminoglycoside antibiotic tobramycin. After 14 rounds of selection, two sequence families emerged. Upon conversion into beacon aptamers, representatives of the two selected sequence families specifically detected tobramycin, while a negative control RNA that did not survive the selection protocol did not function as a tobramycin beacon aptamer.

RNA hairpins in noncoding regions of human brain and Caenorhabditis elegans mRNA are edited by adenosine deaminases that act on RNA.

Adenosine deaminases that act on RNA (ADARs) constitute a family of RNA-editing enzymes that convert adenosine to inosine within double-stranded regions of RNA. We previously developed a method to identify inosine-containing RNAs and used it to identify five ADAR substrates in Caenorhabditis elegans. Here we use the same method to identify five additional C. elegans substrates, including three mRNAs that encode proteins known to affect neuronal functions. All 10 of the C. elegans substrates are edited in long stem-loop structures located in noncoding regions, and thus contrast with previously identified substrates of other organisms, in which ADARs target codons. To determine whether editing in noncoding regions was a conserved ADAR function, we applied our method to poly(A)+ RNA of human brain and identified 19 previously unknown ADAR substrates. The substrates were strikingly similar to those observed in C. elegans, since editing was confined to 3' untranslated regions, introns, and a noncoding RNA. Also similar to what was found in C. elegans, 15 of the 19 substrates were edited in repetitive elements. The identities of the newly identified ADAR substrates suggest that RNA editing may influence many biologically important processes, and that for many metazoa, A-to-I conversion in coding regions may be the exception rather than the rule.

RNA editing by ADARs is important for normal behavior in Caenorhabditis elegans.

Here we take advantage of the well-characterized and simple nervous system of Caenorhabditis elegans to further our understanding of the functions of RNA editing. We describe the two C.elegans ADAR genes, adr-1 and adr-2, and characterize strains containing homozygous deletions in each, or both, of these genes. We find that adr-1 is expressed in most, if not all, cells of the C.elegans nervous system and also in the developing vulva. Using chemotaxis assays, we show that both ADARs are important for normal behavior. Biochemical, molecular and phenotypic analyses indicate that ADR-1 and ADR-2 have distinct roles in C.elegans, but sometimes act together.