A Single‐Chain Light‐Activatable Transcriptional Reporter for Fluorescently Tagging Mammalian Cells In Vitro

Optogenetic tools have revolutionized the control of gene expression with high spatial and temporal resolution. Here we present a Single-chain Light-Activatable Transcriptional Reporter (SLATR), a system capable of fluorescently tagging target cells with minutes of white light stimulation. In its inactive, or dark state, a transcriptional factor is cytosolically bound, preventing nuclear translocation. White light irradiation triggers its release through the protease cleavage of a site that is sterically caged by the circularly permuted Avena sativa LOV2 (cpAsLOV2) domain. We discovered that cpAsLOV2 cages the cleavage site more efficiently than AsLOV2, achieving low background in the SLATR design. We demonstrate that SLATR exhibits a signal-to-background ratio between 3.4 and 36 and achieves reporter activation within 60 min of light stimulation. Furthermore, SLATR outperforms the only other single-chain light-activatable transcriptional reporter, LAUNCHER, with faster kinetics, greater light sensitivity, and markedly lower background under identical stimulation conditions. Our single-chain light-activatable transcriptional system expands the optogenetic toolkit though providing a simpler system for regulating gene expression with precise spatiotemporal control.