Curated Optogenetic Publication Database

Abstract: Reversibly photoswitchable fluorescent proteins (rsFPs) represent a unique class of genetically encoded probes that undergo light-driven transitions between non-fluorescent OFF and emissive ON states. Their distinctive switching properties enable repeated, non-destructive control of fluorescence and have become central to advanced bioimaging approaches. In this review, we provide a critical overview of the molecular mechanisms underlying rsFP function, focusing on GFP-like proteins and fluorogen-activating systems that employ external chromophores. We describe switching kinetics, ON/OFF contrast, and fatigue as fundamental performance parameters, and highlight mechanistic insights from spectroscopy, crystallography, and computational studies. The three subclasses of GFP-like rsFPs-negative, positive, and decoupled types-are discussed in detail, alongside external-chromophore systems such as FAST, UnaG, FbFPs, and biliverdin-binding near-infrared proteins. We further survey a wide range of applications, including super-resolution microscopy, functional biosensing, multiplex discrimination, anisotropy-based analyses, diffusion and transport studies, optical data storage, and optogenetic control. Finally, we outline emerging strategies for improving brightness, photostability, spectral diversity, and switching robustness, emphasizing opportunities for rational protein engineering guided by structural and computational approaches. Together, these developments establish rsFPs as versatile, chemically tunable tools that expand the frontiers of fluorescence imaging and quantitative biology.

Abstract: There are several paths when excited molecules return to the ground state. In the case of fluorescent molecules, the dominant path is fluorescence emission that is greatly contributing to bioimaging. Meanwhile, photosensitizers transfer electron or energy from chromophore to the surrounding molecules, including molecular oxygen. Generated reactive oxygen species has potency to attack other molecules by oxidation. In this chapter, we introduce the chromophore-assisted light inactivation (CALI) method using a photosensitizer to inactivate proteins in a spatiotemporal manner and development of CALI tools, which is useful for investigation of protein functions and dynamics, by inactivation of the target molecules. Moreover, photosensitizers with high efficiency make it possible optogenetic control of cell ablation in living organisms and photodynamic therapy. Further development of photosensitizers with different excitation wavelengths will contribute to the investigation of multiple proteins or cell functions through inactivation in the different positions and timings.

Abstract: Genetically encoded biosensors based on the principle of Förster resonance energy transfer comprise two major classes: biosensors based on fluorescence resonance energy transfer (FRET) and those based on bioluminescence energy transfer (BRET). The FRET biosensors visualize signaling-molecule activity in cells or tissues with high resolution. Meanwhile, due to the low background signal, the BRET biosensors are primarily used in drug screening. Here, we report a protocol to transform intramolecular FRET biosensors to BRET-FRET hybrid biosensors called hyBRET biosensors. The hyBRET biosensors retain all properties of the prototype FRET biosensors and also work as BRET biosensors with dynamic ranges comparable to the prototype FRET biosensors. The hyBRET biosensors are compatible with optogenetics, luminescence microplate reader assays, and non-invasive whole-body imaging of xenograft and transgenic mice. This simple protocol will expand the use of FRET biosensors and enable visualization of the multiscale dynamics of cell signaling in live animals.

Abstract: Calcium ion (Ca2+) is an important second messenger implicated in the control of many different cellular processes in living organisms. Ca2+ is typically studied by direct visualization using chemically or genetically encoded indicators. A complementary, and perhaps more useful, approach involves direct manipulation of Ca2+ concentration; tools for this exist but are rather poorly developed compared to the indicators at least. Here, we report a photoactivatable Ca2+-releasing protein, photoactivatable Ca2+ releaser (PACR), made by the insertion of a photosensitive protein domain (LOV2) into a Ca2+ binding protein (calmodulin fused with the M13 peptide). As the PACR is genetically encoded, and unlike conventional optical control tools (e.g., channel rhodopsin) not membrane bound, we are able to restrict expression within the cell, to allow subcellular perturbation of Ca2+ levels. In whole animals, we are able to control the behavior of Caenorhabditis elegans with light by expressing the PACR only in the touch neuron.