State-dependent motion of a genetically encoded fluorescent biosensor

Publication information:

Paul C. Rosen, Samantha M. Horwitz, Daniel J. Brooks, Erica Kim, Joseph A. Ambari, Lidia Waidmann, Katherine M. Davis, and Gary Yellen. 2025. “State-Dependent Motion of a Genetically Encoded Fluorescent Biosensor”. PNAS, 122, 10. doi:10.1073/pnas.2426324122

Abstract

Genetically encoded biosensors can measure biochemical properties such as small-molecule concentrations with single-cell resolution, even in vivo. Despite their utility, these sensors are “black boxes”: Very little is known about the structures of their low- and high-fluorescence states or what features are required to transition between them. We used LiLac, a lactate biosensor with a quantitative fluorescence-lifetime readout, as a model system to address these questions. X-ray crystal structures and engineered high-affinity metal bridges demonstrate that LiLac exhibits a large interdomain twist motion that pulls the fluorescent protein away from a “sealed,” high-lifetime state in the absence of lactate to a “cracked,” low-lifetime state in its presence. Understanding the structures and dynamics of LiLac will help to think about and engineer other fluorescent biosensors.