Curated Optogenetic Publication Database

Search precisely and efficiently by using the advantage of the hand-assigned publication tags that allow you to search for papers involving a specific trait, e.g. a particular optogenetic switch or a host organism.

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Showing 26 - 50 of 473 results
26.

Multimodal Key Anti-Oncolytic Therapeutics Are Effective In Cancer Treatment?

blue cyan near-infrared red Cryptochromes Fluorescent proteins LOV domains Phytochromes Review
Int J Nanomedicine, 16 Aug 2025 DOI: 10.2147/ijn.s531849 Link to full text
Abstract: Oncolytic virus (OVs) therapy has emerged as a promising modality in cancer immunotherapy, attracting growing attention for its multifaceted mechanisms of tumor elimination. However, its efficacy as a monotherapy remains constrained by physiological barriers, limited delivery routes, and suboptimal immune activation. Phototherapy, an innovative and rapidly advancing cancer treatment technology, can mitigate these limitations when used in conjunction with OVs, enhancing viral delivery, amplifying tumor destruction, and boosting antitumor immune responses. This review provides the first comprehensive analysis of synergistic integration of OVs with both photodynamic therapy (PDT) and photothermal therapy (PTT). It also explores their applications in optical imaging-guided diagnosis and optogenetically controlled delivery. Furthermore, it discusses emerging strategies involving biomimetic virus or viroid-based vectors in conjunction with phototherapy, and delves into the immunomodulatory mechanisms of this combinatorial approach. While promising in preclinical models, these combined strategies are still largely in early-stage research. Challenges such as limited light penetration, delivery efficiency, and safety concerns remain to be addressed for clinical translation. Consequently, the integration of OV therapy and phototherapy represents a compelling strategy in cancer treatment, offering significant promise for advancing precision oncology and next-generation immunotherapies.
27.

A rapid and efficient red-light-activated Cre recombinase system for genome engineering in mammalian cells and transgenic mice.

red PhyA/FHY1 BHK-21 Hana3A HEK293T HeLa hMSCs mouse in vivo Neuro-2a Nucleic acid editing
Nucleic Acids Res, 11 Aug 2025 DOI: 10.1093/nar/gkaf758 Link to full text
Abstract: The Cre-loxP recombination system enables precise genome engineering; however, existing photoactivatable Cre tools suffer from several limitations, including low DNA recombination efficiency, background activation, slow activation kinetics, and poor tissue penetration. Here, we present REDMAPCre, a red-light-controlled split-Cre system based on the ΔPhyA/FHY1 interaction. REDMAPCre enables rapid activation (1-s illumination) and achieves an 85-fold increase in reporter expression over background levels. We demonstrate its efficient regulation of DNA recombination in mammalian cells and mice, as well as its compatibility with other inducible recombinase systems for Boolean logic-gated DNA recombination. Using a single-vector adeno-associated virus delivery system, we successfully induced REDMAPCre-mediated DNA recombination in mice. Furthermore, we generated a REDMAPCre transgenic mouse line and validated its efficient, light-dependent recombination across multiple organs. To explore its functional applications, REDMAPCre transgenic mice were crossed with isogenic Cre-dependent reporter mice, enabling optogenetic induction of insulin resistance and hepatic lipid accumulation via Cre-dependent overexpression of ubiquitin-like with PHD and RING finger domains 1 (UHRF1), as well as targeted cell ablation through diphtheria toxin fragment A expression. Collectively, REDMAPCre provides a powerful tool for achieving remote control of recombination and facilitating functional genetic studies in living systems.
28.

Optogenetic enzymes: A deep dive into design and impact.

blue cyan near-infrared red BLUF domains Cryptochromes Fluorescent proteins LOV domains Phytochromes Review
Curr Opin Struct Biol, 5 Aug 2025 DOI: 10.1016/j.sbi.2025.103126 Link to full text
Abstract: Optogenetically regulated enzymes offer unprecedented spatiotemporal control over protein activity, intermolecular interactions, and intracellular signaling. Many design strategies have been developed for their fabrication based on the principles of intrinsic allostery, oligomerization or 'split' status, intracellular compartmentalization, and steric hindrance. In addition to employing photosensory domains as part of the traditional optogenetic toolset, the specificity of effector domains has also been leveraged for endogenous applications. Here, we discuss the dynamics of light activation while providing a bird's eye view of the crafting approaches, targets, and impact of optogenetic enzymes in orchestrating cellular functions, as well as the bottlenecks and an outlook into the future.
29.

Opto-CRISPR: new prospects for gene editing and regulation.

blue cyan green red Cryptochromes Fluorescent proteins LOV domains Phytochromes Review
Trends Biotechnol, 17 Jul 2025 DOI: 10.1016/j.tibtech.2025.06.018 Link to full text
Abstract: Clustered regularly interspaced short palindromic repeats (CRISPR) technology represents a landmark advance in the field of gene editing. However, conventional CRISPR/Cas systems are limited by inadequate temporal and spatial control. In recent years, the development of optically controlled CRISPR (Opto-CRISPR) technology has offered a novel solution to this issue. As a combination of optogenetics and the CRISPR technology, the Opto-CRISPR technology enables dynamic space-time-specific gene editing and regulation in cells and organisms. In this review, we concisely introduce the basic principles of Opto-CRISPR, summarize its operational mechanisms, and discuss its applications and recent advances across various research fields. In addition, this review analyzes the limitations of Opto-CRISPR, aiming to provide a reference for the development of this emerging field.
30.

Advances in optogenetically engineered bacteria in disease diagnosis and therapy.

blue green red UV violet BLUF domains Cryptochromes LOV domains Phytochromes UV receptors Review
Biotechnol Adv, 15 Jul 2025 DOI: 10.1016/j.biotechadv.2025.108645 Link to full text
Abstract: Optogenetic bacterial technology is a cutting-edge approach that combines optogenetics and microbiology, offering a transformative strategy for disease diagnosis and therapy. This synergistic merger transcends the limitations of traditional diagnostic and therapeutic methodologies in a highly controllable, accurate and non-invasive manner. In this review, we introduce the optogenetic systems developed for microbial engineering and summarize fundamental in vitro design principles underlying light-responsive signal transduction in bacteria, as well as the optogenetic regulation of bacterial behaviors. We address multidisciplinary solutions to the challenges in the in vivo applications of light-controlled bacteria, such as limited light excitation, suboptimal delivery and targeting, and difficulties in signal tracking and management. Furthermore, we comprehensively highlight the recent progress in photo-responsive bacteria for disease diagnosis and therapy, and discuss how to accelerate translational applications.
31.

Deep-tissue high-sensitivity multimodal imaging and optogenetic manipulation enabled by biliverdin reductase knockout.

red DrBphP iLight HeLa mouse in vivo primary mouse cortical neurons primary mouse endothelial cells primary mouse fibroblasts Transgene expression
Nat Commun, 14 Jul 2025 DOI: 10.1038/s41467-025-61532-4 Link to full text
Abstract: Performance of near-infrared probes and optogenetic tools derived from bacterial phytochromes is limited by availability of their biliverdin chromophore. To address this, we use a biliverdin reductase-A knock-out mouse model (Blvra-/-), which elevates endogenous biliverdin levels. We show that Blvra⁻/⁻ significantly enhances function of bacterial phytochrome-based systems. Light-controlled transcription using iLight optogenetic tool improves ~25-fold in Blvra-/- cells, compared to wild-type controls, and achieves ~100-fold activation in neurons. Light-induced insulin production in Blvra-/- mice reduces blood glucose by ~60% in diabetes model. To overcome depth limitations in imaging, we employ 3D photoacoustic, ultrasound, and two-photon fluorescence microscopy. This enables simultaneous photoacoustic imaging of DrBphP in neurons and super-resolution ultrasound localization microscopy of brain vasculature at depths of ~7 mm through intact scalp and skull. Two-photon microscopy achieves cellular resolution of miRFP720-expressing neurons at ~2.2 mm depth. Overall, Blvra-/- model represents powerful platform for improving efficacy of biliverdin-dependent tools for deep-tissue imaging and optogenetic manipulation.
32.

Traits of Bathy Phytochromes and Application to Bacterial Optogenetics.

red Phytochromes Background
ACS Synth Biol, 11 Jul 2025 DOI: 10.1021/acssynbio.5c00337 Link to full text
Abstract: Phytochromes are photoreceptors sensitive to red and far-red light, found in a wide variety of organisms, including plants, fungi, and bacteria. Bacteriophytochromes (BphPs) can be switched between a red light-sensitive Pr state and a far-red light-sensitive Pfr state by illumination. In so-called prototypical BphPs, the Pr state functions as the thermally favored resting state, whereas Pfr is more stable in bathy BphPs. The prototypical DrBphP from Deinococcus radiodurans has been shown to be compatible with different output module types. Even though red light-regulated optogenetic tools are available, like the pREDusk system based on the DrBphP photosensory module, far-red light-modulated variants are still rare. Here, we study the underlying contributors to bathy over prototypical BphP behavior by way of various chimeric constructs between pREDusk and representative bathy BphPs. We pinpoint shared traits of the otherwise heterogeneous subgroup of bathy BphPs and highlight the importance of the sensor-effector linker in light modulation of histidine kinase activity. Informed by these data, we introduce the far-red light-activated system "pFREDusk", based on a histidine kinase activity governed by a bathy photosensory module. With this tool, we expand the optogenetic toolbox into wavelengths of increased sample and tissue penetration.
33.

Shaping viral immunotherapy towards cancer-targeted immunological cell death.

blue red Cryptochromes LOV domains Phytochromes Review
Front Oncol, 8 Jul 2025 DOI: 10.3389/fonc.2025.1540397 Link to full text
Abstract: Oncolytic viruses (OVs) have the ability to efficiently enter, replicate within, and destroy cancer cells. This capacity to selectively target cancer cells while inducing long-term anti-tumor immune responses, makes OVs a promising tool for next-generation cancer therapy. Immunogenic cell death (ICD) induced by OVs initiates the cancer-immunity cycle (CIC) and plays a critical role in activating and reshaping anti-cancer immunity. Genetic engineering, including arming OVs with cancer cell-specific binders and immunostimulatory molecules, further enhances immune responses at various stages of the CIC, improving the specificity and safety of virotherapy.The aim of this study is to update current knowledge in immunotherapy using OVs and to highlight the remarkable plasticity of viruses in shaping the tumor immune microenvironment, which may facilitate anti-cancer treatment through various approaches.
34.

Optogenetic-Controlled iPSC-Based Vaccines for Prophylactic and Therapeutic Tumor Suppression in Mice.

red FnBphP PnBphP isolated MEFs mouse IPSCs Transgene expression
Adv Sci (Weinh), 6 Jul 2025 DOI: 10.1002/advs.202416115 Link to full text
Abstract: Induced pluripotent stem cells (iPSCs) share similar cellular features and various antigens profiles with cancer cells. Leveraging these characteristics, iPSCs hold great promise for developing wide-spectrum vaccines against cancers. In practice, iPSCs are typically combined with immune adjuvants to enhance antitumor immune responses; however, traditional adjuvants lack controllability and can induce systemic toxicity, which has limited their broad application. Here, a red/far-red light-controlled iPSC-based vaccine (RIVA) based on the chimeric photosensory protein FnBphP and its interaction partner LDB3 is developed; RIVA preserves the intrinsic tumor antigens of iPSCs and enables optogenetic control of an immune adjuvant's (IFN-β) expression under red light illumination. Experiments in multiple mouse tumor models demonstrate that RIVA inhibits tumor growth and improves animal survival in prophylactic and therapeutic settings, including against pulmonary metastatic 4T1 breast cancer. RIVA efficiently stimulates dendritic cell maturation, eliciting innate immune activation effects through NK cells and elicit adaptive immune anti-tumor responses through CD4+ and CD8+ T cells. Moreover, RIVA protects animals against tumor re-challenge by inducing strong immunological memory, with minimal systemic toxicity. This study demonstrates RIVA as an effective optogenetic approach for developing safe multi-antigen vaccines for the prevention and treatment of cancer.
35.

Engineered bacteriophytochrome heterodimers for research and applications.

red Phytochromes Background
J Biol Chem, 4 Jul 2025 DOI: 10.1016/j.jbc.2025.110452 Link to full text
Abstract: Many proteins are dimeric, functioning as complexes of two identical or different subunits. Bacteriophytochromes are homodimeric photoreceptor proteins that sense red/far-red light with a photosensory module (PSM) and convert it to a biological response via an output module, usually a histidine kinase (HK). Here, we generate monomeric bacteriophytochrome PSMs that form stable heterodimers once mixed by modifying two salt bridges at the dimerization interface of the Deinococcus radiodurans phytochrome (DrBphP). We confirm that these heterodimeric PSMs can control output HK module activity in response to red light and reveal that dimerization is required for kinase activity of the model HK FixL, but not necessarily for phosphatase activity of DrBphP. By applying the heterodimeric variants to a red light-regulated gene expression tool, we exemplify the combined control of cellular events using both heterodimerization and light. These results pave the way for new heterodimeric systems, for example, in receptor protein research and optogenetics.
36.

Programmable genome engineering and gene modifications for plant biodesign.

blue red Cryptochromes LOV domains Phytochromes Review
Plant Commun, 24 Jun 2025 DOI: 10.1016/j.xplc.2025.101427 Link to full text
Abstract: Plant science has entered a transformative era as genome editing enables precise DNA modifications to address global challenges such as climate adaptation and food security. These modifications are primarily driven by the integration of three modular components-DNA-targeting modules, effector modules, and control modules-that can be selectively activated or suppressed. The field has evolved from protein-based systems (e.g., zinc finger nucleases and transcription activator-like effector nucleases) to RNA-guided systems (e.g., CRISPR-Cas) that can control both genetic and epigenetic states. Modular pairing of DNA-targeting and effector domains, with or without inducible control, enables precise transcriptional regulation and chromatin remodeling. The present review examines these three modules and highlights strategies for their optimization. It also outlines innovative tools, such as optogenetic and receptor-integrated systems, that enable spatiotemporal control over genome editor expression. These modular approaches bypass traditional limitations and allow scientists to create plants with desirable traits, decipher complex gene networks, and promote sustainable agriculture.
37.

Optogenetics to biomolecular phase separation in neurodegenerative diseases.

blue cyan near-infrared red UV Cryptochromes Fluorescent proteins LOV domains Phytochromes UV receptors Review
Mol Cells, 22 Jun 2025 DOI: 10.1016/j.mocell.2025.100247 Link to full text
Abstract: Neurodegenerative diseases involve toxic protein aggregation. Recent evidence suggests that biomolecular phase separation, a process in which proteins and nucleic acids form dynamic, liquid-like condensates, plays a key role in this aggregation. Optogenetics, originally developed to control neuronal activity with light, has emerged as a powerful tool to investigate phase separation in living systems. This is achieved by fusing disease-associated proteins to light-sensitive oligomerization domains, enabling researchers to induce or reverse condensate formation with precise spatial and temporal control. This review highlights how optogenetic systems such as OptoDroplet are being used to dissect the mechanisms of neurodegenerative disease. We examine how these tools have been applied in models of neurodegenerative diseases, such as amyotrophic lateral sclerosis, Alzheimer's, Parkinson's, and Huntington's disease. These studies implicate small oligomeric aggregates as key drivers of toxicity and highlight new opportunities for therapeutic screening. Finally, we discuss advances in light-controlled dissolution of condensates and future directions for applying optogenetics to combat neurodegeneration. By enabling precise, dynamic control of protein phase behavior in living systems, optogenetic approaches provide a powerful framework for elucidating disease mechanisms and informing the development of targeted therapies.
38.

Improving the Response of Microbial Fuel Cell-Based Biosensing through Optogenetic Enhancement of Electroactive Biofilms.

red BphS S. oneidensis Control of cell-cell / cell-material interactions Immediate control of second messengers
Environ Sci Technol, 16 Jun 2025 DOI: 10.1021/acs.est.5c04805 Link to full text
Abstract: Early detection of pollutants in water discharge is an integral part of environmental monitoring. Electroactive biofilm (EAB)-enabled, microbial fuel cell (MFC)-based biosensors facilitate self-powered online pollutant detection. However, as EABs are highly dynamic, naturally formed EABs as sensing and transducing elements limit the performance of MFC-based biosensors. Here, we report a fast-response and sensitive MFC-based biosensor enabled by enhancing Shewanella oneidensis biofilms on the electrode using an optogenetic approach. We incorporated a near-infrared (NIR) light-responsive synthetic bis(3'-5')-cyclic dimeric guanosine monophosphate (c-di-GMP) module into S. oneidensis to promote biofilm formation on the anode under NIR light. The biosensors with enhanced EABs exhibited a rapid and sensitive response to Cr(VI), reducing the sensing time from approximately 30 min to just 3 min. This improved sensing performance was maintained over three sensing cycles, even with fluctuating Cr(VI) concentrations. Based on the analyses of the electrode biofilms and extracellular polymeric substance matrices, different Cr(VI) response mechanisms for the normal and enhanced EABs were proposed; enhanced EAB's massive dispersal by Cr(VI) was the cause of the improved response of the biosensors. Such improved response still held in the natural water matrix. This proof-of-concept study provides valuable insights into controlling electrode biofilm dynamics for the rapid and robust early detection of pollutants using MFC-based biosensors.
39.

Nanobody-Based Light-Controllable Systems for Investigating Biology.

blue near-infrared red LOV domains Phytochromes Review
Chembiochem, 9 Jun 2025 DOI: 10.1002/cbic.202500311 Link to full text
Abstract: Nanobodies, the camelid-derived single-chain variable domain of heavy-chain-only antibodies, are compact in size and exhibit high binding affinity and specificity to their binding partners. As innovative antibody modalities, nanobodies have garnered significant attention in medicine and biological research. To achieve higher spatiotemporal precision, nanobody-based light-controlled systems-such as photobody, optobody, photoactivatable nanobody conjugate inducers of dimerization, and others-have been developed. These systems enable optical control of biological processes while leveraging the advantages of nanobodies as a binding moiety. This concept, summarizes nanobody-based photoregulated systems for investigating biology through light, highlights their advantages and potential limitations, and discusses future directions in this emerging research area.
40.

Single-cell characterization of bacterial optogenetic Cre recombinases.

blue red Magnets PhyA/FHY1 VVD E. coli Nucleic acid editing
bioRxiv, 7 Jun 2025 DOI: 10.1101/2025.06.06.658346 Link to full text
Abstract: Microbial optogenetic tools can regulate gene expression with high spatial and temporal precision, offering excellent potential for single-cell resolution studies. However, bacterial optogenetic systems have primarily been deployed for population-level experiments. It is not always clear how these tools perform in single cells, where stochastic effects can be substantial. In this study, we focus on optogenetic Cre recombinase and systematically compare the performance of three variants (OptoCre-REDMAP, OptoCre-Vvd, and PA-Cre) for their population-level and single-cell activity. We quantify recombination efficiency, expression variability, and activation dynamics using reporters which produce changes in fluorescence or antibiotic resistance following light-induced Cre activity. Our results indicate that optogenetic recombinase performance can be reporter-dependent, suggesting that this is an important consideration in system design. Further, our single-cell analysis reveals highly heterogeneous activity across cells. Although general trends match expectations for mean levels of light-dependent recombination, we found substantial variation in this behavior across individual cells. In addition, our results show that the timing of recombinase activity is highly variable from cell to cell. These findings suggest critical criteria for selecting appropriate optogenetic recombinase systems and indicate areas for optimization to improve the single-cell capabilities of bacterial optogenetic tools.
41.

Multiplexing light-inducible recombinases to control cell fate, Boolean logic, and cell patterning in mammalian cells.

blue red Magnets MagRed nanoReD PhyA/FHY1 C3H/10T1/2 HEK293FT Nucleic acid editing Multichromatic
Sci Adv, 9 May 2025 DOI: 10.1126/sciadv.adt1971 Link to full text
Abstract: Light-inducible regulatory proteins are powerful tools to interrogate fundamental mechanisms driving cellular behavior. In particular, genetically encoded photosensory domains fused to split proteins can tightly modulate protein activity and gene expression. While light-inducible split protein systems have performed well individually, few multichromatic and orthogonal gene regulation systems exist in mammalian cells. The design space for multichromatic circuits is limited by the small number of orthogonally addressable optogenetic switches and the types of effectors that can be actuated by them. We developed a library of red light-inducible recombinases and directed patterned myogenesis in a mesenchymal fibroblast-like cell line. To address the limited number of light-inducible domains (LIDs) responding to unique excitation spectra, we multiplexed light-inducible recombinases with our "Boolean logic and arithmetic through DNA excision" (BLADE) platform. Multiplexed optogenetic tools will be transformative for understanding the role of multiple interacting genes and their spatial context in endogenous signaling networks.
42.

Optimized Phage Display-Based Selection for the Development of Heterodimerizing Optogenetic Tools.

red FenixS/Ash1 E. coli
ASC Synth Biol, 8 May 2025 DOI: 10.1021/acssynbio.5c00167 Link to full text
Abstract: Multiple display techniques, including phage display, mRNA display, and ribosome display, have been used to expand the optogenetic toolbox beyond what nature provides. These techniques are most often applied to the development of binding partners that selectively recognize different conformational states of photoswitchable proteins. However, for some targets, in particular the spectrally diverse cyanobacteriochrome (CBCR) GAF domain family, the subtle differences between conformational states pose a significant challenge to discovering highly selective binders. We present an optimized phage display-based protocol designed to effectively capture these subtle changes. This optimized protocol applies high selection pressure by changing the elution method and tightening negative selection, leading to the enrichment of selective binders. Through multiple selection campaigns, we demonstrate the utility of this protocol for identifying highly selective binders.
43.

A Robust and Orthogonal Far-Red Light Sensor for Gene Expression Control in Escherichia coli.

red RfpA E. coli S. cerevisiae Transgene expression Benchmarking
ASC Synth Biol, 6 May 2025 DOI: 10.1021/acssynbio.5c00044 Link to full text
Abstract: Optogenetics has emerged as a powerful tool for regulating cellular processes due to its noninvasive nature and precise spatiotemporal control. Far-red light (FRL) has increasingly been used in the optogenetic control of mammalian cells due to its low toxicity and high tissue penetration. However, robust and orthogonal FRL sensors are lacking in bacteria. Here, we established an orthogonal FRL sensor in Escherichia coli with a maximum dynamic range exceeding 230-fold based on the RfpA-RfpC-RfpB (RfpABC) signaling system that regulates the far-red light photoacclimation (FaRLiP) in cyanobacteria. We identified a conserved DNA motif in the promoter sequences of the Chl f synthase gene and other genes in the FaRLiP gene clusters, termed the far-red light-regulatory (FLR) motif, which enables the light-responsive activation of gene expression through its interaction with RfpB. Based on the FLR motif, we simplified the FLR-containing promoters and characterized their activation abilities and dynamic ranges, which can be utilized in different synthetic biology scenarios. Additionally, one or two FLR motifs are present at other loci within the FaRLiP gene cluster, providing further FRL-inducible promoter resources. The FRL sensor exhibits effective activation and suppression under low-intensity FRL and white light, respectively, and remains functional in darkness. In conclusion, this study advances the understanding of the regulatory mechanisms of FaRLiP in cyanobacteria and provides robust and orthogonal FRL sensors for synthetic biology applications.
44.

Engineering plant photoreceptors towards enhancing plant productivity.

blue red UV Cryptochromes LOV domains Phytochromes UV receptors Review
Plant Mol Biol, 6 May 2025 DOI: 10.1007/s11103-025-01591-9 Link to full text
Abstract: Light is a critical environmental factor that governs the growth and development of plants. Plants have specialised photoreceptor proteins, which allow them to sense both quality and quantity of light and drive a wide range of responses critical for optimising growth, resource use and adaptation to changes in environment. Understanding the role of these photoreceptors in plant biology has opened up potential avenues for engineering crops with enhanced productivity by engineering photoreceptor activity and/or action. The ability to manipulate plant genomes through genetic engineering and synthetic biology approaches offers the potential to unlock new agricultural innovations by fine-tuning photoreceptors or photoreceptor pathways that control plant traits of agronomic significance. Additionally, optogenetic tools which allow for precise, light-triggered control of plant responses are emerging as powerful technologies for real-time manipulation of plant cellular responses. As these technologies continue to develop, the integration of photoreceptor engineering and optogenetics into crop breeding programs could potentially revolutionise how plant researchers tackle challenges of plant productivity. Here we provide an overview on the roles of key photoreceptors in regulating agronomically important traits, the current state of plant photoreceptor engineering, the emerging use of optogenetics and synthetic biology, and the practical considerations of applying these approaches to crop improvement. This review seeks to highlight both opportunities and challenges in harnessing photoreceptor engineering approaches for enhancing plant productivity. In this review, we provide an overview on the roles of key photoreceptors in regulating agronomically important traits, the current state of plant photoreceptor engineering, the emerging use of optogenetics and synthetic biology, and the practical considerations of applying these approaches to crop improvement.
45.

Red Light-Activated Reversible Inhibition of Protein Functions by Assembled Trap.

blue red CRY2/CIB1 DrBphP HeLa ovarian somatic cells Cell cycle control Organelle manipulation
ACS Synth Biol, 30 Apr 2025 DOI: 10.1021/acssynbio.4c00585 Link to full text
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.
46.

Empowering bacteria with light: Optogenetically engineered bacteria for light-controlled disease theranostics and regulation.

blue green near-infrared red BLUF domains Cryptochromes LOV domains Phytochromes Review
J Control Release, 29 Apr 2025 DOI: 10.1016/j.jconrel.2025.113787 Link to full text
Abstract: Bacterial therapy has emerged as a promising approach for disease treatment due to its environmental sensitivity, immunogenicity, and modifiability. However, the clinical application of engineered bacteria is limited by differences of expression levels in patients and possible off-targeting. Optogenetics, which combines optics and genetics, offers key advantages such as remote controllability, non-invasiveness, and precise spatiotemporal control. By utilizing optogenetic tools, the behavior of engineered bacteria can be finely regulated, enabling on-demand control of the dosage and location of their therapeutic products. In this review, we highlight the latest advancements in the optogenetic engineering of bacteria for light-controlled disease theranostics and therapeutic regulation. By constructing a three-dimensional analytical framework of “sense-produce-apply”, we begin by discussing the key components of bacterial optogenetic systems, categorizing them based on their photosensitive protein response to blue, green, and red light. Next, we introduce innovative light-producing tools that extend beyond traditional light sources. Then, special emphasis is placed on the biomedical applications of optogenetically engineered bacteria in treating diseases such as cancer, intestinal inflammation and systemic disease regulation. Finally, we address the challenges and future prospects of bacterial optogenetics, outlining potential directions for enhancing the safety and efficacy of light-controlled bacterial therapies. This review aims to provide insights and strategies for researchers working to advance the application of optogenetically engineered bacteria in drug delivery, precision medicine and therapeutic regulation.
47.

Insight into Optogenetics for Diabetes Management.

blue green red BLUF domains Cobalamin-binding domains Cryptochromes LOV domains Phytochromes Review
ACS Synth Biol, 25 Apr 2025 DOI: 10.1021/acssynbio.4c00549 Link to full text
Abstract: Optogenetics is an interdisciplinary field wherein optical and genetic engineering methods are employed together to impart photounresponsive cells (usually of higher animals) the ability to respond to light through expression of light-sensitive proteins sourced generally from algae or bacteria. It enables precise spatiotemporal control of various cellular activities through light stimulation. Recently, emerging as a synthetic biology-based approach for diabetes management, optogenetics can provide user-control of hormonal secretion by photoactivation of a suitably modified cell. For around a decade, studies have been performed on the applicability of various light-sensitive proteins and their incorporation into pancreatic and nonpancreatic cells for photoinduced insulin secretion. Further, in vivo studies demonstrated amelioration of diabetes in mouse models through photoactivation of the implanted engineered cells. Here, we attempt to highlight the various optogenetic approaches explored in terms of influencing the insulin secretion pathway at different points in light of the natural insulin secretion pathway in pancreatic β cells. We also discuss how transgenic cells of both pancreatic as well as nonpancreatic origin are exploited for photoinduced secretion of insulin. Recent advances on integration of “smart” technologies for remote control of light irradiation and thereby insulin secretion from implanted engineered cells in preclinical models are also described. Additionally, the need for further comprehensive studies on irradiation parameters, red-shifted opsins, and host–cell interaction is stressed to realize the full potential of optogenetics as a clinically applicable modality providing user-controlled “on demand” hormonal secretion for better management of diabetes.
48.

Nonlinear optical properties of photosensory core modules of monomeric and dimeric bacterial phytochromes.

red Phytochromes Background
Protein Sci, 18 Apr 2025 DOI: 10.1002/pro.70118 Link to full text
Abstract: Near-infrared (NIR) fluorescent proteins and optogenetic tools derived from bacterial phytochromes' photosensory core modules (PCMs) operate within the first (NIR-I) tissue transparency window under single-photon activation. Leveraging two-photon (2P) light in the second transparency window (NIR-II) for photoswitching bacterial phytochromes between Pr and Pfr absorption states offers significant advantages, including enhanced tissue penetration, spatial resolution, and signal-to-noise ratio. However, 2P photoconversion of bacterial phytochromes remains understudied. Here, we study the non-linear Pr to Pfr photoconversion's dependence on irradiation wavelength (1180–1360 nm) and energy fluence (41–339 mJ/cm2) for the PCM of DrBphP bacterial phytochrome. Our findings reveal substantially higher photoconversion efficiency for the engineered monomeric DrBphP-PCM (73%) compared to the natural dimeric DrBphP-PCM (57%). Molecular mechanical calculations, based on experimentally determined 2P absorption cross-section coefficients for the monomer (167 GM) and dimer (170 GM), further verify these results. We demonstrate both short- (SWE) and long-wavelength excitation (LWE) fluorescence of the Soret band using 405 and 810–890 nm laser sources, respectively. Under LWE, fluorescence emission (724 nm) exhibits saturation at a peak power density of 1.5 GW/cm2. For SWE, we observe linear degradation of fluorescence for both DrBphP-PCMs, decreasing by 32% as the temperature rises from 19 to 38°C. Conversely, under LWE, the monomeric DrBphP-PCM's brightness increases up to 182% (at 37°C), surpassing the dimeric form's fluorescence rise by 39%. These findings establish the monomeric DrBphP-PCM as a promising template for developing NIR imaging and optogenetic probes operating under the determined optimal parameters for its 2P photoconversion and LWE fluorescence.
49.

Emerging roles of transcriptional condensates as temporal signal integrators.

blue red BLUF domains Cryptochromes LOV domains Phytochromes Review
Nat Rev Genet, 16 Apr 2025 DOI: 10.1038/s41576-025-00837-y Link to full text
Abstract: Transcription factors relay information from the external environment to gene regulatory networks that control cell physiology. To confer signalling specificity, robustness and coordination, these signalling networks use temporal communication codes, such as the amplitude, duration or frequency of signals. Although much is known about how temporal information is encoded, a mechanistic understanding of how gene regulatory networks decode signalling dynamics is lacking. Recent advances in our understanding of phase separation of transcriptional condensates provide new biophysical frameworks for both temporal encoding and decoding mechanisms. In this Perspective, we summarize the mechanisms by which transcriptional condensates could enable temporal decoding through signal adaptation, memory and persistence. We further outline methods to probe and manipulate dynamic communication codes of transcription factors and condensates to rationally control gene activation.
50.

Recent Developments in the Optical Control of Adrenergic Signaling.

blue red violet Cryptochromes Fluorescent proteins LOV domains Phytochromes Review
Med Res Rev, 3 Apr 2025 DOI: 10.1002/med.22110 Link to full text
Abstract: Adrenoceptors (ARs) play a vital role in various physiological processes and are key therapeutic targets. The advent of optical control techniques, including optogenetics and photopharmacology, offers the potential to modulate AR signaling with precise temporal and spatial resolution. In this review, we summarize the latest advancements in the optical control of AR signaling, encompassing optogenetics, photocaged compounds, and photoswitchable compounds. We also discuss the limitations of current tools and provide an outlook on the next generation of optogenetic and photopharmacological tools. These emerging optical technologies not only enhance our understanding of AR signaling but also pave the way for potential therapeutic developments.
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