Molecular insights into the ligand-controlled organization of the SAM-I riboswitch.

S-adenosylmethionine (SAM) riboswitches are widespread in bacteria, and up to five different SAM riboswitch families have been reported, highlighting the relevance of SAM regulation. On the basis of crystallographic and biochemical data, it has been postulated, but never demonstrated, that ligand recognition by SAM riboswitches involves key conformational changes in the RNA architecture. We show here that the aptamer follows a two-step hierarchical folding selectively induced by metal ions and ligand binding, each of them leading to the formation of one of the two helical stacks observed in the crystal structure. Moreover, we find that the anti-antiterminator P1 stem is rotated along its helical axis upon ligand binding, a mechanistic feature that could be common to other riboswitches. We also show that the nonconserved P4 helical domain is used as an auxiliary element to enhance the ligand-binding affinity. This work provides the first comprehensive characterization, to our knowledge, of a ligand-controlled riboswitch folding pathway.

Comparative study between transcriptionally- and translationally-acting adenine riboswitches reveals key differences in riboswitch regulatory mechanisms.

Many bacterial mRNAs are regulated at the transcriptional or translational level by ligand-binding elements called riboswitches. Although they both bind adenine, the adenine riboswitches of Bacillus subtilis and Vibrio vulnificus differ by controlling transcription and translation, respectively. Here, we demonstrate that, beyond the obvious difference in transcriptional and translational modulation, both adenine riboswitches exhibit different ligand binding properties and appear to operate under different regulation regimes (kinetic versus thermodynamic). While the B. subtilis pbuE riboswitch fully depends on co-transcriptional binding of adenine to function, the V. vulnificus add riboswitch can bind to adenine after transcription is completed and still perform translation regulation. Further investigation demonstrates that the rate of transcription is critical for the B. subtilis pbuE riboswitch to perform efficiently, which is in agreement with a co-transcriptional regulation. Our results suggest that the nature of gene regulation control, that is transcription or translation, may have a high importance in riboswitch regulatory mechanisms.

Application of fluorescent measurements for characterization of riboswitch-ligand interactions.

Riboswitches are recently discovered messenger RNA motifs involved in gene regulation. They modulate gene expression at various levels, such as transcription, translation, splicing, and mRNA degradation. Because riboswitches exhibit relatively complex structures, they are able to form highly complex ligand-binding sites, which enable the specific recognition of target metabolites in a complex cellular environment. Practically in all studied cases, riboswitches use ligand-induced conformational changes to control gene expression. To monitor the structural reorganization of riboswitches, we use the local fluorescent reporter 2-aminopurine (2AP), which is a structural analog of adenine. The 2AP fluorescence is strongly quenched when the fluorophore is involved in stacking interactions with surrounding bases, and can, therefore, be used to monitor local structural rearrangements. Here, we show specific examples in which 2AP fluorescence can be used to monitor structural changes in the aptamer domain of the S-adenosyl methionine (SAM) riboswitch and where it can be used as a ligand for the guanine riboswitch.

Folding of the SAM aptamer is determined by the formation of a K-turn-dependent pseudoknot.

The S-adenosylmethionine (SAM) riboswitch is one of the most recurrent riboswitches found in bacteria and has three known different natural aptamers. The Bacillus subtilis yitJ SAM riboswitch aptamer is organized around a four-way junction which is characterized by the presence of a pseudoknot and a K-turn motif. By replacing the adenine involved in a Watson-Crick base pair at position 138 in the core region of the aptamer with the fluorescent analogue 2-aminopurine (2AP), we show that the ligand-induced reorganization of the aptamer strongly attenuates 2AP fluorescence. The fluorescence quenching process is specific to SAM on the basis of the observation that the structural analogue S-adenosylhomocysteine does not promote a similar effect. We find that the pseudoknot is important for the reorganization of the core domain and that the K-turn motif also has a marked influence on the core domain reorganization, most probably through its important role in pseudoknot formation. Finally, we show that SAM riboswitch ligand binding is facilitated by the L7Ae K-turn binding protein, which suggests that K-turn motifs may be protein anchor sites used by riboswitches to promote RNA folding.

Three steps in the thermal unfolding of F-actin: an experimental evidence.

The development of differential scanning calorimetry has resulted in an increased interest in studies of the unfolding process in proteins with the aim of identifying domains and interactions with ligands or other proteins. Several of these studies were done with actin and showed that the thermal unfolding of F-actin occurs in at least three steps; this was interpreted as the denaturation of independent domains. In the present work, we have followed the thermal unfolding of F-actin using differential scanning calorimetry (DSC), CD spectroscopy, and probe fluorescence. We found that the three steps revealed through DSC are not the denaturation of independent domains. These three steps are a change in the environment of cys 374 at 49.5 degrees C; a modification at the nucleotide-binding site at 55 degrees C; and the unfolding of the peptide chain at 64 degrees C. Previous interpretations of the thermograms of F-actin were thus erroneous. Since DSC is now widely used to study proteins, our experimental approach and conclusions may also be relevant in denaturation studies of proteins in general.