Abstract
RNA naturally regulates many cellular processes, yet the engineering of RNA for use in synthetic cellular control schemes lags behind protein-based systems. Recent advancements in synthetic biology, investment in RNA therapeutics, and a better understanding of RNA structural dynamics have driven the development of novel RNA sensors and actuators. The genetic information encoded within RNA enables facile sensing and interactions with other nucleic acids, while its dynamic structure facilitates binding to a broad array of small-molecule and protein ligands. RNA can be engineered to sense these diverse inputs and transduce signals to regulate cellular activity on the transcriptional, translational, and post-translational levels to enhance microbial biosynthesis and create targeted gene therapies.