Direct observation of tRNA-chaperoned folding of a dynamic mRNA ensemble

T-box riboswitches are multi-domain noncoding RNAs that surveil individual amino acid availabilities in most Gram-positive bacteria. T-boxes directly bind specific tRNAs, query their aminoacylation status to detect starvation, and feedback control the transcription or translation of downstream amino-acid metabolic genes. Most T-boxes rapidly recruit their cognate tRNA ligands through an intricate three-way stem I-stem II-tRNA interaction, whose establishment is not understood. Using single-molecule FRET, SAXS, and time-resolved fluorescence, we find that the free T-box RNA assumes a broad distribution of open, semi-open, and closed conformations that only slowly interconvert. tRNA directly binds all three conformers with distinct kinetics, triggers nearly instantaneous collapses of the open conformations, and returns the T-box RNA to their pre-binding conformations upon dissociation. This scissors-like dynamic behavior is enabled by a hinge-like pseudoknot domain which poises the T-box for rapid tRNA-induced domain closure. This study reveals tRNA-chaperoned folding of flexible, multi-domain mRNAs through a Venus flytrap-like mechanism. T-box riboswitch RNAs directly bind to specific tRNA and regulate the transcription or translation of downstream genes in bacteria. Using single-molecule FRET and ensemble biophysical analyses, here the authors uncover a Venus flytrap-like mechanism where tRNA binding to a T-box riboswitch mRNA triggers its rapid domain closure.

Automated summary

T-box riboswitch RNAs directly bind to specific tRNA and regulate the transcription or translation of downstream genes in bacteria. Using single-molecule FRET and ensemble biophysical analyses, here the authors uncover a Venus flytrap-like mechanism where tRNA binding to a T-box riboswitch mRNA triggers its rapid domain closure.