Curated Optogenetic Publication Database

Abstract: Investigating astrocyte-neuron dynamics following ischemic stroke is essential for understanding post-stroke recovery mechanisms. However, current methodologies often fail to capture real-time interactions between neurons and astrocytes in animals executing specific behavioral tasks, limiting our ability to investigate the acute phase of stroke pathology. This protocol presents an integrated method that combines photothrombotic stroke modeling with simultaneous multichannel electrophysiology recording and fiber photometry in awake, behaving mice using a custom-fabricated optrode. The protocol includes focal ischemia induction via photothrombosis followed by simultaneous recording of neuronal spikes and astrocytic calcium transients. The optrode enables concurrent delivery of photothrombosis, calcium signal recording, and optogenetic manipulation without requiring separate surgical procedures. Representative results validate the success in simultaneous recording of astrocytic calcium signal and neuronal spiking. Optogenetic manipulation of astrocytes produces measurable changes in neuronal firing patterns (reduction in firing frequency of pyramidal neurons by 1.55 ± 0.45 Hz and interneuron by 3.64 ± 1.37 Hz compared to pre-optogenetic stimulation, n = 2), confirming that the system is capable of investigating astrocyte-neuron interactions. This integrated approach addresses critical gaps in stroke research methodology by providing real-time, multimodal recordings from the acute to chronic stage of stroke in behaving animals.

Abstract: Cofilin is a key regulator of actin dynamics that, along with a myriad of other actin-binding proteins, controls the balance of F- and G-actin in numerous cell types. While prior structural studies of the cofilin-actin binding interface have delineated many critical interactions between cofilin and actin, the roles of some residues within the cofilin-actin binding interface remain poorly defined. In this study, we investigate the role of cofilin S119 in the cofilin-actin interaction. Despite its unique position within the cofilin-actin interface and its putative role as a phosphorylation site, relatively little direct evidence exists to define whether it plays an important role in cofilin-actin dynamics. Using site-directed mutagenesis, we demonstrate that mutation of S119 to aromatic amino acids (W, F, Y) results in cofilins with strong actin bundling activity in living cells. This activity can be countered by the incorporation of mutants that disfavor actin rod forming activity (R21Q). Mutation of S119 to phospho-mimic (E) and non-phosphorylated (A) residues either strongly inhibits (E) or modestly increases (A) actin bundling activity. Expression of the S119W mutant in neurons reveals its impacts on spine length and size, while FRAP studies show that its mobile fraction is intermediate between that of LifeAct and WT cofilin. Finally, it is shown that the strong actin bundling phenotype associated with S119W inhibits the progression of optogenetically induced apoptosis.

Abstract: Calcium (Ca²+) release from intracellular stores, Ca²+ entry across the plasma membrane and their coordination via store-operated Ca²+ entry (SOCE) are critical for receptor-activated Ca²+ oscillations. However, the precise mechanism of Ca²+ oscillations and whether their control loop resides at the plasma membrane or intracellularly remains unresolved. By examining the dynamics of stromal interaction molecule 1 (STIM1), an endoplasmic reticulum (ER)-localized Ca²+ sensor that activates the Orai1 channel on the plasma membrane for SOCE, in mast cells, we found that a significant proportion of cells exhibited STIM1 oscillations with the same periodicity as Ca²+ oscillations. These cortical oscillations, shared with ER-plasma membrane (ER-PM) contact site proteins, were only detectable using total internal reflection fluorescence microscopy. Notably, STIM1 oscillations could occur independently of Ca²+ oscillations. Simultaneous imaging of cytoplasmic Ca²+ and ER Ca²+ with CEPIA1er revealed that receptor activation does not deplete ER Ca²+, whereas receptor activation without extracellular Ca²+ influx induces cyclic ER Ca²+ depletion. However, under such non-physiological conditions, cyclic ER Ca²+ oscillations lead to sustained STIM1 recruitment, indicating that oscillatory Ca²+ release is neither necessary nor sufficient for STIM1 oscillations. Using optogenetic tools to manipulate ER-PM contact site dynamics, we found that persistent ER-PM contact sites reduced the amplitude of Ca²+ oscillations without alteration of oscillation frequency. Together, these findings suggest an active cortical mechanism governs the rapid dissociation of ER-PM contact sites, thereby controlling amplitude of oscillatory Ca²+ dynamics during receptor-induced Ca²+ oscillations.

Abstract: Mechanoreceptors can be motile and actively amplify their mechanical input.1,2,3,4 We here found that the responses of mechanoreceptor cells can also be shaped actively by contractile supporting cells. Drosophila larvae monitor body movements with pentascolopidial chordotonal (lch5) organs that are stretched out between cuticular attachment sites.5,6,7,8 These proprioceptive organs contain five stretch-receptor neurons each that receive mechanical stimuli from supporting cap cells. The elastic cap cells are surrounded by extracellular matrix and contain actin cables and non-muscle myosin II motors, suggesting that the cells might be motile.9,10 We show that the supporting cap cells are pre-strained at rest to about twice their relaxed length, and that the force they transmit is modulated by myosin II in the cap cells. Cap cells contracted upon optogenetic activation of myosin II. Cap cell-specific knockdown of the regulatory light chain of myosin II relieved tension and converted the spiking responses of the stretch receptors from phasic to more tonic, impairing adaptation to sustained stimuli. Our findings thus illustrate that mechanoreceptor responses can be actively tailored by contractile neighboring cells.

Abstract: Optogenetics holds great potential for diverse biological applications, including fundamental research, tissue engineering, and regenerative medicine, by enabling the precise spatial and temporal control of cellular signaling pathways. Transforming growth factor-beta (TGFβ), a multifunctional cytokine, is a critical regulator of cell proliferation, differentiation, and particularly chondrogenesis. Although TGFβ signaling is necessary for effective chondrogenic differentiation, previous studies have primarily relied on recombinant TGFβ ligand supplementation. In this study, we established an advanced optogenetic platform by knocking-in opto-TGFβ receptors in the AAVS1 locus of human embryonic stem cells (hESCs), enabling precise optogenetic activation of endogenous TGFβ signaling. Blue light illumination specifically activated TGFβ signaling, indicated by enhanced SMAD2 phosphorylation. Employing a three-dimensional pellet culture system, we demonstrated that direct optogenetic activation of TGFβ receptors, without exogenous ligand supplementation, is sufficient for robust chondrogenic differentiation of hESC-derived mesenchymal stem cells. The efficiency of optogenetic differentiation was comparable to conventional recombinant TGFβ protein treatment, evidenced by the expression of chondrogenic markers and deposition of cartilage-specific extracellular matrix components, including aggrecan and type II collagen. Our findings directly confirm the sufficiency and critical role of TGFβ receptor activation itself in chondrogenesis. Furthermore, this optogenetic approach provides a theoretical advantage by enabling noninvasive external modulation of TGFβ signaling post-transplantation, potentially facilitating further maturation and functional integration of transplanted chondrocytes. Thus, our results highlight a promising recombinant-protein-free strategy for use in cartilage tissue engineering and regenerative medicine.

Abstract: The genome folds inside the cell nucleus into hierarchical architectural features, such as chromatin loops and domains. If and how this genome organization influences the regulation of gene expression remains only partially understood. The structure-function relationship of genomes has traditionally been probed by population-wide measurements after mutation of crucial DNA elements or by perturbation of chromatin-associated proteins. To circumvent possible pleiotropic effects of such approaches, we have developed OptoLoop, an optogenetic system that allows direct manipulation of chromatin contacts by light in a controlled fashion. OptoLoop is based on the fusion between a nuclease-dead SpCas9 protein and the light-inducible oligomerizing protein CRY2. We demonstrate that OptoLoop can bring together genomically distant, repetitive DNA loci. As a proof-of-principle application of OptoLoop, we probed the functional role of DNA looping in the regulation of the human telomerase gene TERT. By analyzing the extent of chromatin looping and nascent RNA production at individual alleles, we find evidence for looping-mediated repression of TERT. In sum, OptoLoop represents a novel means for the interrogation of structure-function relationships in the genome.

Abstract: CRISPR-Cas systems enable powerful gene editing and regulation, yet single-modality control often fails to achieve orthogonal, spatiotemporally precise regulation of multiple endogenous genes. We engineered OREC, an orthogonal platform integrating chemogenetic and optogenetic modalities for precise, reversible, multiplex gene control. OREC comprises two components: ORECC regulated by doxycycline (Dox) and ORECo controlled by light. By assembling catalytically dead Cpf1 (dCpf1), gene regulatory elements, and crRNA arrays on single transcripts, OREC enables robust simultaneous manipulation of multiple genes. We demonstrated OREC's therapeutic potential in vitro for osteoblast function modulation and in vivo for osteoporotic fracture repair. OREC effectively activated Bmp2 while inhibiting Dkk1, significantly enhancing bone formation and fracture healing in mouse models. These results establish OREC as a versatile platform for precise multiplex gene regulation, offering significant advancement for CRISPR-based gene therapy applications in complex tissues where coordinated control of multiple therapeutic targets is essential.

Abstract: G protein-coupled receptors (GPCRs) perceive spatially and temporally diverse stimuli and activate G protein heterotrimers comprising α, β, and γ subunits, which broadcast signals through a broad range of effectors at various subcellular compartments. Therefore, understanding endogenous G protein activity dynamics at the subcellular level, thereby recapitulating in vivo signaling paradigms, will facilitate the identification of pathological signaling pathways. However, the lack of sensors for endogenous G proteins has been an obstacle. Here, we demonstrate the engineering of sensors to probe endogenous GαiGTP and GαqGTP. Compared to examining overexpressed and fluorescently tagged Gα, our sensors capture the magnitude and kinetics of endogenous GαGTP dynamics, including their generation, equilibrium signaling, and hydrolysis, with native fidelity. Using the translocation-based GαiGTP sensor, we show that heterotrimer dissociation upon Gi-GPCR activation is Gγ-subtype dependent. Confirming our previous findings, the GαqGTP sensor showed that Gαq expression is low and tightly regulated in most cells. Using optogenetic tools, we demonstrate that our sensors detect GαGTP generation and hydrolysis during asymmetric GPCR-G protein activation, a capability that will be particularly useful in morphologically diverse cells such as neurons. Therefore, our engineered novel GαGTP sensors can be highly beneficial in decoding subcellularly resolved endogenous G protein signaling dynamics.

Abstract: Notch signalling is a critical regulator of multiple developmental processes through its ability to control gene expression and thereby influence cell fate specification and cell proliferation through direct cell-cell communication. Although Notch signalling has been implicated in myogenesis during late embryogenesis, its role in early mesoderm development has been largely unexplored. Endocytosis of the Notch ligand Delta and the Notch receptor extracellular domain, a critical step in Notch pathway activation, has been extensively observed in the ventral mesoderm of the early Drosophila embryo, indicating a potential for Notch signalling activity in this early germ layer. Here, we present evidence that genes critical to mesoderm development require and are responsive to Notch signalling activity. Using a novel light-inducible Optogenetic variant of the Notch intracellular domain (OptoNotch), which affords precise spatial and temporal control over ectopic activation of Notch signalling, in combination with high-resolution fluorescent RNA in situ hybridization and qPCR, we identified a set of mesodermal genes whose expression is directly regulated by Notch signalling. We also provide evidence that Notch signalling indirectly regulates the dorsal-ventral patterning program mediated by the Toll signalling pathway through the Dorsal/Twist/Snail gene network. Our findings demonstrate that Notch signalling regulates ventral mesoderm patterning and is critical for establishing the mesoderm-mesectoderm-ectoderm boundary by regulating gene expression patterns and providing negative feedback on the upstream patterning network.

Abstract: Mitochondrial quality is crucial for maintaining brain homeostasis. BNIP3L/NIX, a mitophagy receptor, has been linked to neurological disorders, yet its specific function in the brain remains unclear. We found BNIP3L highly expressed in basolateral amygdala (BLA) neurons. Selective deletion of bnip3l in BLA glutamatergic neurons (BLAGLU) impaired contextual fear memory, accompanied by reduced neuronal excitation and mitochondrial respiration. Notably, fear conditioning did not invariably activate mitophagy in BLAGLU neurons. Overexpression of both wild-type and a mitophagy-deficient mutant (BNIP3LΔLIR) in BLAGLU neurons was sufficient to rescue the contextual fear memory deficits in bnip3l-/- mice, suggesting a non-mitophagy role. Instead, we detected a prompt mitochondrial fission in BLAGLU neurons after foot-shock conditioning, an effect abolished by bnip3l deletion. Inhibition of Drp1 with Mdivi-1 disrupted memory formation, whereas optogenetic activation of Drp1 restored neuronal excitation and rescued memory deficits in bnip3l-/- mice. These data indicated an essential role of BNIP3L-mediated mitochondrial fission in modulating contextual fear memory. Mechanistically, BNIP3L and Drp1 competitively interact with AMPK, leading to reduced Drp1 phosphorylation and increased Drp1 accumulation on mitochondria, thereby promoting mitochondrial fission. Taken together, the present study revealed a previously uncharacterized, non-mitophagy-dependent role for BNIP3L in contextual fear memory conditioning.

Abstract: Neuronal activity robustly engages the extracellular signal-regulated kinase (ERK) signaling pathway through Ca2+-dependent mechanisms; however, whether ERK can acutely and causally modulates ongoing neuronal activity remains unsolved due to complex upstream regulation and diverse subcellular functions. Here, we directly address this question using an optogenetic ERK activator, opto-miniRaf, that enables selective, rapid, graded, and reversible control of ERK signaling. Combining this AAV-compatible system with calcium imaging and electrophysiology, we interrogate ERK functions across biological scales, from cultured neurons, acute brain slices, and the intact brain. Acute optogenetic activation of ERK enhances synchronized network burst activity in cultured rat cortical neurons and increases calcium activity of cortical pyramidal neurons in awake and moving mice following non-invasive light stimulation. Together, these results establish ERK signaling as an acute modulator of neuronal and network activity, positioning opto-miniRaf as a generalizable platform for precise spatiotemporal control of intracellular kinase signaling in complex biological systems.

Abstract: Cellular lipid metabolism is subject to strong homeostatic regulation, but the players involved in and mechanisms underlying these pathways remain largely uncharacterized. Here we develop a 'feeding-fishing' approach coupling membrane editing using optogenetic lipid-modifying enzymes (feeding) with organelle membrane proteomics through proximity labeling (fishing) to elucidate molecular players and pathways involved in the homeostasis of phosphatidic acid (PA), a multifunctional lipid central to glycerolipid metabolism. This approach identified several PA-metabolizing enzymes and lipid transfer proteins enriched in and depleted from PA-fed membranes. Mechanistic analysis revealed that PA homeostasis in the cytosolic leaflets of the plasma membrane and lysosomes is mediated by both local PA metabolism and the action of lipid transfer proteins that carry out interorganelle lipid transport before subsequent metabolism. More broadly, the interfacing of membrane editing to controllably modify membrane lipid composition with organelle membrane proteomics using proximity labeling represents a strategy for revealing mechanisms governing lipid homeostasis.

Abstract: Biopolymers that separate into condensed and dilute phases in solution also prewet membranes when one or more components couple to membrane lipids. Here we demonstrate that this prewetting transition becomes exquisitely sensitive to lipid composition when membranes have compositions near the boundary of liquid-ordered/liquid-disordered phase coexistence in both simulation and in reconstitution when polyelectrolytes are coupled to model membranes. In cells, we use an optogenetic tool to characterize prewetting at both the plasma membrane (PM) and the endoplasmic reticulum (ER) and find that prewetting is potentiated or inhibited by perturbations of membrane composition. Prewetting can also mediate membrane adhesion, with avidity dependent on membrane composition, as demonstrated in cells through the potentiation or inhibition of ER-PM contact sites. The strong correspondence of results in simulation, reconstitution and cells reveals a new role for membrane lipids in regulating the recruitment and assembly of soluble proteins.

Abstract: Although considerable research has focused on enhancing the apoptotic function of BAX for several decades, inhibition of its functionality remains relatively underexplored, despite intensive BAX activation occurring in various neurodegenerative diseases. Here we present a protein engineering approach to modulate BAX integration into the mitochondrial outer membrane, establishing a tunable strategy for antiapoptosis. Utilizing optogenetic methods that employ cryptochrome 2 and its binding partner cryptochrome-interacting basic helix loop helix 1, we achieved precise spatial control over BAX localization, a critical determinant of its function. Our results demonstrate that the engineered BAX variant is effectively incapacitated in its apoptotic function while also modulating endogenous BAX activity to enhance cellular resistance to apoptosis. These findings not only advance our understanding of BAX regulation but also offer promising prospects for the development of therapeutic strategies against apoptosis-related diseases.

Abstract: Inducible gene expression tools can open novel applications in human health and biotechnology, but current options are often expensive, difficult to reverse, and have undesirable off-target effects. Optogenetic systems use light-responsive proteins to control the activity of regulators such that expression is controlled with the "flip of a switch". This study optimizes a simplified light activated CRISPR effector (2pLACE) system, which provides tunable, reversible, and precise control of mammalian gene expression. The OptoPlate-96 enables high-throughput screening via flow cytometry for single-cell analysis and rapid optimization of 2pLACE. This study demonstrates how to use the 2pLACE system with the OptoPlate-96 in HEK293T cells to identify the optimal component ratios for maximizing dynamic range and to find the blue light intensity response curve. Similar workflows can be developed for other mammalian cells and for other optogenetic systems and wavelengths of light. These advancements enhance the precision, scalability, and adaptability of optogenetic tools for biomanufacturing applications.

Abstract: Microtubules (MTs) form dynamic cytoskeletal scaffolds essential for intracellular transport, organelle positioning, and spatial organization of signaling. Their architecture and function are continuously remodeled through the concerted actions of microtubule-associated proteins (MAPs), post-translational modifications (PTMs), and molecular motors. To precisely interrogate these processes in living systems, we developed a genetically encoded optogenetic toolkit for spatiotemporal control of MT organization and dynamics. By replacing native multimerization motifs with a blue light-responsive oligoermization domain, we have engineered single-component probes, OptoMT and OptoTIP, that reversibly label MT polymers or track plus-ends with tunable kinetics from seconds to minutes. When coupled to enzymatic effectors, these modules enable localized tubulin acetylation or detyrosination, directly linking PTMs to MT stability. We further engineered OptoMotor, a light-activatable kinesin platform that reconstitutes tail-dependent cargo transport along MTs, and OptoSAW, a light-triggered severing actuator for controlled MT disassembly. Using these tools, we reveal how local MT integrity governs lysosomal trafficking and ER-associated signaling dynamics. Collectively, this versatile single-component toolkit bridges molecular design with cytoskeletal function, offering new avenues to illuminate how dynamic cytoskeletal architectures coordinate intracellular organization, transport, and signaling.

Abstract: The response of cell populations to external stimuli plays a central role in biological mechanical processes such as epithelial wound healing and developmental morphogenesis. Wave-like propagation of a signal of ERK MAP kinase has been shown to direct collective migration in one direction; however, the mechanism based on continuum mechanics under a traveling wave is not fully understood. To elucidate how the traveling wave of the ERK kinase signal directs collective migration, we constructed the mechanical model of the epithelial cell monolayer by considering the signal-dependent coordination of contractile stress and cellular orientation. The proposed model was studied by using an optogenetically controlled cell system where we found that local signal activation induces changes in cell density and orientation with the direction of propagation. The net motion of the cell population occurred relative to the wave, and the migration velocity showed a maximum in resonance with the velocity of the ERK signal wave. The presented mechanical model was further validated in an in vitro wound healing process.

Abstract: In adherent cells, actomyosin contractility is regulated mainly by the RhoA signaling pathway, which can be controlled by optogenetics. To model the mechanochemical coupling in such systems, we introduce a finite element framework based on the discontinuous Galerkin method, which allows us to treat cell doublets, chains of cells, and monolayers within the same conceptual framework. While the adherent cell layer is modeled as an actively contracting viscoelastic solid on an elastic foundation, different models are considered for the Rho pathway, starting with a simple linear chain that can be solved analytically and later including direct feedback that can be solved only numerically. Our model predicts signal propagation as a function of coupling strength and viscoelastic timescales and identifies the conditions for optimal cell responses and wave propagation. In general, it provides a systematic understanding of how biochemistry and mechanics simultaneously contribute to the communication of adherent cells.

Abstract: During development, epithelia function as malleable sheets that undergo extensive remodeling to shape developing embryos. Optogenetic control of Rho signaling provides an avenue to investigate mechanisms of epithelial morphogenesis, but transgenic optogenetic tools can be limited by variability in expression levels and deleterious effects of transgenic overexpression on development. Here, we use CRISPR/Cas9 to tag Drosophila RhoGEF2 and Cysts/Dp114RhoGEF with components of the iLID/SspB optogenetic heterodimer, permitting light-dependent control over endogenous protein activities. Using quantitative optogenetic perturbations, we uncover a dose-dependence of tissue furrow depth and bending behavior on RhoGEF recruitment, revealing mechanisms by which developing embryos can shape tissues into particular morphologies. We show that at the onset of gastrulation, furrows formed by cell lateral contraction are oriented and size-constrained by basal actomyosin. Our findings demonstrate the use of quantitative, 3D-patterned perturbations of cell contractility to precisely shape tissue structures and interrogate developmental mechanics.

Abstract: Methods for monitoring physiological changes in cellular Ca2+ levels have been in high demand for their utility in monitoring neuronal signaling. Recently, we introduced SCANR (Split-Tobacco Etch Virus (TEV) protease Calcium-regulated Neuron Recorder), which reports on Ca2+ changes in cells through the binding of calmodulin and M13 to reconstitute an active TEV protease. First-generation SCANR marked all of the Ca2+ spikes that occur throughout the lifetime of the cell, but it did not have a mechanism for controlling the time window in which recording of physiological changes in Ca2+ occurred. Here, we explore both chemical and light-based strategies for controlling the time and place in which Ca2+ recording occurs. We describe the adaptation of six popular chemo- and opto-genetics methods for controlling protein activity and subcellular localization to the SCANR system. We report two successful strategies, one that leverages the LOV-Jα optogenetics system for sterically controlling protein interactions and another that employs chemogenetic manipulation of subcellular protein distribution using the FKBP/FRB rapamycin binding pair.

Abstract: p53 protein, a crucial transcription factor in cellular responses to a wide variety of stress, regulates multiple target genes involved in tumor suppression, senescence induction, and metabolic functions. To characterize the context-dependent roles of p53, it is still needed to develop an experimental system that enables selective activation of p53 in cells and tissues. In this study, we developed an optogenetic tool, Opto-p53, to control p53 signaling by light. Opto-p53 was designed to trigger p53 signaling by reconstituting p53 N-terminal and C-terminal fragments with a light-inducible dimerization (LID) system. Upon light exposure, cells expressing Opto-p53 demonstrated p53 transcriptional activation, resulting in cell death and cell cycle arrest. We further enhanced the efficacy of light-induced p53 activation by introducing specific mutations into Opto-p53 fragments. Our findings unveil the capability of Opto-p53 to serve as a powerful tool for dissecting the complex roles of p53 in cellular processes, thereby contributing to the field of synthetic biology and providing general design principles for optogenetic tools using endogenous transcription factors.Key words: synthetic biology, transcriptional factor, p53, optogenetics.

Abstract: Optogenetic systems use light-responsive proteins to control gene expression, ion channels, protein localization, and signaling with the "flip of a switch". One such tool is the light activated CRISPR effector (LACE) system. Its ability to regulate gene expression in a tunable, reversible, and spatially resolved manner makes it attractive for many applications. However, LACE relies on delivery of four separate components on individual plasmids, which can limit its use. Here, we optimize LACE to reduce the number of plasmids needed to deliver all four components.

Abstract: Lipid droplets (LDs) are dynamic organelles crucial for lipid storage and homeostasis. Despite extensive documentation of their importance, the causal relationship between LD localization and function in health and disease remains inadequately understood. Here, we developed optogenetics-based tools, termed "Opto-LDs," which facilitate the interaction between LDs and motor proteins in a light-dependent manner, enabling precise control of LD localization within cells. Utilizing these optogenetic modules, we demonstrated that light-induced relocation of LDs to the periphery of hepatocytes results in elevated very-low-density lipoprotein (VLDL) secretion, recapturing the beneficial effect of insulin in vitro. Furthermore, our studies in transgenic Drosophila revealed that proper LD localization is critical for embryonic development, with mistargeting of LDs significantly affecting egg hatching success. In summary, our work underscores the great importance of LD localization in lipid metabolism and development, and our developed tools offer valuable insights into the functions of LDs in health and disease.

Abstract: Membrane receptors, particularly G protein-coupled receptors (GPCRs), are integral to numerous physiological processes. Precise control of the receptor endocytosis is essential for understanding cellular signaling pathways. In this study, we present the development of a broadly applicable optogenetic tool for light-inducible receptor internalization. This system, named E-fragment, leverages the CRY2-CIB photodimerization pair to enable blue-light-dependent recruitment of β-arrestin and subsequent receptor internalization. We showed that the E-fragment system is applicable across diverse membrane proteins, including multiple GPCRs. Furthermore, we investigated its impact on intracellular cAMP signaling in cells expressing dopamine receptor D1 and α2-adrenergic receptor. Quantitative analyses revealed that light-induced internalization led to reduced surface receptor expression and attenuated ligand-evoked cAMP responses. These findings demonstrate the versatility of the E-fragment system as a platform for studying membrane receptor function and suggest potential applications in therapeutic strategies targeting receptor trafficking and signaling modulation.

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.