Curated Optogenetic Publication Database

Abstract: Red light, characterized by superior tissue penetration and minimal phototoxicity, represents an ideal wavelength for optogenetic applications. However, the existing tools for reversible protein inhibition by red light remain limited. Here, we introduce R-LARIAT (red light-activated reversible inhibition by assembled trap), a novel optogenetic system enabling precise spatiotemporal control of protein function via 660 nm red-light-induced protein clustering. Our system harnesses the rapid and reversible binding of engineered light-dependent binders (LDBs) to the bacterial phytochrome DrBphP, which utilizes the endogenous mammalian biliverdin chromophore for red light absorption. By fusing LDBs with single-domain antibodies targeting epitope-tagged proteins (e.g., GFP), R-LARIAT enables the rapid sequestration of diverse proteins into light-responsive clusters. This approach demonstrates high light sensitivity, clustering efficiency, and sustained stability. As a proof of concept, R-LARIAT-mediated sequestration of tubulin inhibits cell cycle progression in HeLa cells. This system expands the optogenetic toolbox for studying dynamic biological processes with high spatial and temporal resolution and holds the potential for applications in living tissues.

Abstract: Protein dimerization systems controlled by red light with increased tissue penetration depth are a highly needed tool for clinical applications such as cell and gene therapies. However, mammalian applications of existing red light-induced dimerization systems are hampered by limitations of their two components: a photosensory protein (or photoreceptor) which often requires a mammalian exogenous chromophore and a naturally occurring photoreceptor binding protein typically having a complex structure and nonideal binding properties. Here, we introduce an efficient, generalizable method (COMBINES-LID) for creating highly specific, reversible light-induced heterodimerization systems independent of any existing binders to a photoreceptor. It involves a two-step binder screen (phage display and yeast two-hybrid) of a combinatorial nanobody library to obtain binders that selectively engage a light-activated form of a photoswitchable protein or domain not the dark form. Proof-of-principle was provided by engineering nanobody-based, red light-induced dimerization (nanoReD) systems comprising a truncated bacterial phytochrome sensory module using a mammalian endogenous chromophore, biliverdin, and light-form specific nanobodies. Selected nanoReD systems were biochemically characterized, exhibiting low dark activity and high induction specificity, and further demonstrated for the reversible control of protein translocation and activation of gene expression in mice. Overall, COMBINES-LID opens new opportunities for creating genetically encoded actuators for the optical manipulation of biological processes.