A unique mechanism explaining the outstanding performance of a newly discovered doxycycline riboswitch

Synthetic riboswitches offer a versatile and protein-independent solution for conditional gene regulation. They consist of a regulatory domain and an aptamer domain that binds a specific ligand, with their performance largely depending on the ability of the aptamer to control the regulatory domain. Expanding the range of synthetic riboswitches therefore requires the discovery and characterization of new regulatory aptamers. In the present study, we identified a doxycycline-binding aptamer with outstanding regulatory properties in both yeast and human cells which are based on a unique structural dynamic upon ligand binding. Single-molecule force spectroscopy revealed that doxycycline binding strongly stabilizes an intermediate aptamer conformation offering mechanistic insights into its function. The identification of the aptamer through a combination of parallel SELEX and subsequent in vivo screening in yeast, also provided valuable insights into selection dynamics and the first proof for the effectiveness of RNA Capture-SELEX in aptamer selection. Together, the presented data deepen our understanding of regulatory aptamer selection and functionality while adding a high-performing doxycycline-responsive aptamer to the synthetic biology toolbox.