A transient intermediate RNA structure underlies the regulatory function of the E. coli thiB TPP translational riboswitch

• Published in: RNA (Cambridge) Vol. 29; no. 11; pp. 1658 - 1672
• Main Authors: Berman, Katherine E, Steans, Russell, Hertz, Laura M, Lucks, Julius B
• Format: Journal Article
• Language: English
• Published: United States Cold Spring Harbor Laboratory Press 01.11.2023
• Subjects: Aptamers; Complementarity; Escherichia coli - metabolism; Gene expression; Intermediates; Ligands; Mutagenesis; Nucleic Acid Conformation; Protein structure; Ribonucleic acid; Riboswitch - genetics; Riboswitches; RNA; RNA Folding; RNA, Bacterial - metabolism; Secondary structure; Thiamine diphosphate; Thiamine Pyrophosphate - genetics; Thiamine Pyrophosphate - metabolism; Transcription elongation; Translation; RNA folding; translation regulation; riboswitches; SHAPE-Seq
• ISSN: 1355-8382; 1469-9001; 1469-9001
• DOI: 10.1261/rna.079427.122

Riboswitches are -regulatory RNA elements that regulate gene expression in response to ligand binding through the coordinated action of a ligand-binding aptamer domain (AD) and a downstream expression platform (EP). Previous studies of transcriptional riboswitches have uncovered diverse examples that utilize structural intermediates that compete with the AD and EP folds to mediate the switching mechanism on the timescale of transcription. Here we investigate whether similar intermediates are important for riboswitches that control translation by studying the thiamin pyrophosphate (TPP) riboswitch. Using cellular gene expression assays, we first confirmed that the riboswitch acts at the level of translational regulation. Deletion mutagenesis showed the importance of the AD-EP linker sequence for riboswitch function. Sequence complementarity between the linker region and the AD P1 stem suggested the possibility of an intermediate nascent RNA structure called the antisequestering stem that could mediate the switching mechanism. Experimentally informed secondary structure models of the folding pathway generated from chemical probing of nascent structures in stalled transcription elongation complexes confirmed the presence of the antisequestering stem, and showed it may form cotranscriptionally. Additional mutational analysis showed that mutations to the antisequestering stem break or bias function according to whether the antisequestering stem or P1 is favored. This work provides an important example of intermediate structures that compete with AD and EP folds to implement riboswitch mechanisms.