Abstract
RNA thermometers (RNATs) are temperature-responsive structures in 5' untranslated regions (UTRs) of bacterial messenger RNA (mRNA) that control translation by modulating ribosome access. The Listeria monocytogenes prfA RNAT represses translation of PrfA (positive regulatory factor A), the master virulence regulator, at ambient temperature and activates it near the human host temperature (~37 °C) by modulating ribosome binding site (RBS) accessibility. However, the prfA RNAT shares no homology with known RNAT classes, and its unfolding mechanism remains unclear. Here, we used analytical ultracentrifugation and single-molecule kinetic analysis of RNA transient structure (SiM-KARTS) to map prfA RNAT unfolding. SiM-KARTS analysis demonstrates that thermal opening occurs predominantly at the RBS, while the upper helix of the RNAT hairpin remains largely folded at 37 °C. The RBS binding kinetics increases with temperature in parallel with translation output, establishing a quantitative link between structural unfolding and function. Mutations in the upper helix impair thermal regulation, indicating that this region tunes switching even as it stays structured at host temperature. Together, these data reveal a hierarchical unfolding pathway in which initial RBS opening triggers activation, whereas the upper helix remotely tunes temperature sensitivity.