Qr: switch:"AsLOV"
Showing 1 - 25 of 480 results
1.
Gene expression in synthetic biology: Going with the light.
Abstract:
Inducible expression of endogenous and foreign genes has been a pivotal driving force behind a lot many seminal breakthroughs in biotechnology. Synthetic biology, a very promising field, largely relies on transgene expression platforms which facilitate convenient and conditional regulation. Optogenetic approaches that exploit light to steer biological events, e.g., gene expression, with excellent spatiotemporal control, are often more precise compared to chemical induction. Light being an omnipresent environmental stimulus, serves as the ideal cue, and enables high spatiotemporal accuracy with respect to gene expression. In this review, we focus on different elements relevant to light-inducible gene expression - light-responsive promoters, light-regulated transcription factors, and photocaged inducers. Using light as a binary input function, we explore the essence of logic gates towards the development of gene expression circuits - thereby understanding the entanglement between optogenetics and synthetic biology. We primarily focus on prokaryotes, but also draw comparisons with analogous eukaryotic gene expression systems.
2.
Advanced strategies to enhance the safety, persistence, and efficacy of CAR-T cells in solid tumors.
Abstract:
Chimeric antigen receptor (CAR) T-cell therapy has revolutionized the treatment of hematologic cancers but encounters challenges, including severe treatment-related toxicities, a highly suppressive tumor microenvironment (TME), limited long-term persistence, and poor trafficking/infiltration into solid tumors. This review outlines recent genetic engineering strategies to address these issues and enhance the safety, durability, and efficacy of CAR-T cell therapy. To reduce cytokine release syndrome and neurotoxicity, methods such as affinity-tuned and humanized scFvs, hinge/TM optimization, and ITAM calibration have been developed, along with programmable "switch-off" and "switch-on" systems that include suicide genes, antibody-bridging switches, and optogenetic or hypoxia-gated circuits. TME remodeling strategies utilize nanomaterials for targeted cytokine delivery, cell-surface "backpack" systems, and engineered oncolytic viruses that release cytokines or checkpoint-blocking agents. For durability and resistance to exhaustion, precise genome engineering techniques, including CRISPR-based editing and multiplexed shRNA platforms, were employed to target inhibitory receptors and exhaustion-driving transcriptional programs. Additionally, chemokine-receptor engineering and local biomaterial-based delivery systems are discussed as ways to enhance CAR-T trafficking and intratumoral persistence. These innovations collectively point toward integrated, patient-specific CAR-T platforms that incorporate safety controls, metabolic and transcriptional flexibility, and enhanced trafficking through the TME to broaden clinical use.
3.
Optimized optogenetic anti-CRISPR for endogenous gene regulation in Drosophila.
Abstract:
Optogenetic tools-light-responsive proteins that enable to regulate specific cellular activities, study biological processes, and develop new therapies-are attractive approaches for achieving endogenous gene regulation under minimally invasive conditions. Our first step in constructing an optogenetic system to regulate endogenous Drosophila gene expression was to identify inhibitory anti-CRISPR (Acr) proteins that block CRISPRa-mediated activation. Next, we inserted optogenetic protein LOV2 into these Acrs, tested for their ability to optogenetically modulate endogenous gene upregulation through the CRISPRa-based flySAM system in Drosophila, and found that the photoswitchability of these prototypes was weak. We therefore engineered an optimized Acr-LOV2 fusion module by refining length of intrinsically disordered and ordered regions (IDR and IOR) of Acrs. This optimization yielded a variant with significantly greater sensitivity to blue-light-induced endogenous gene upregulation than the prototypes, leading to new in vivo discoveries. In addition, this work provides insights for in vivo functional characterization of the IDR and the IOR of these small-sized proteins. Together, these findings establish a robust optogenetic toolbox for precise, light-controlled endogenous gene regulation in Drosophila.
4.
Illuminating cancer therapy: The translational path of optogenetics.
Abstract:
Tumor recurrence, metastasis, and therapeutic resistance remain major challenges in oncology, driving the need for advanced therapeutic strategies with improved precision and controllability. Optogenetics, which enables light-mediated regulation of cellular functions, has emerged as a promising modality for cancer therapy by offering unparalleled spatiotemporal precision. This capability allows dynamic control of intracellular signaling and transgene expression, enabling selective targeting of malignant cells while minimizing damage to surrounding tissues. However, clinical translation is hindered by key challenges, including inefficient in vivo delivery of optogenetic components, limited tissue penetration of activating light, and suboptimal performance of existing tools. Addressing these barriers requires a convergence of molecular engineering and materials science, wherein advanced biomaterials play a critical role in enabling gene delivery and overcoming tissue-penetration limitations in complex tumor environments. In this review, we provide a comprehensive oriented overview of optogenetics in oncology. We first analyze the molecular mechanisms and engineering principles of representative optogenetic tools, with a focus on LOV- and CRY2-based systems. We then highlight recent advances in biomaterial-assisted optogene delivery and light delivery strategies, emphasizing their material-dependent mechanisms that enable precise spatiotemporal control in vivo. Furthermore, we summarize emerging preclinical applications in cancer immunotherapy, gene regulation, and intracellular signaling control. Finally, we discuss key challenges in biosafety, kinetic optimization, and clinical scalability, and outline future directions that integrate optogenetics with functional materials and intelligent design to realize clinically viable platforms. This review aims to provide a framework for the development of clinically viable optogenetic platforms for next-generation cancer therapy.
5.
Phage-assisted evolution of allosteric protein switches.
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Southern, NT
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von Bachmann, A
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Hovsepyan, A
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Griebl, M
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Wolf, B
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Lemmen, N
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Kroell, AS
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Westermann, S
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Mathony, J
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Niopek, D
Abstract:
Allostery, the transmission of locally induced conformational changes to distant functional sites, is a key mechanism for protein regulation. Artificial allosteric effectors enable remote manipulation of cell function; their engineering, however, is hampered by our limited understanding of allosteric residue networks. Here, we introduce a phage-assisted evolution platform for in vivo optimization of allosteric proteins. It applies opposing selection pressures to enhance activity and switchability of phage-encoded effectors and leverages retron-based recombineering to broadly explore fitness landscapes, introducing point mutations, insertions, and deletions. Applying this framework to the transcription factor AraC yielded near-binary optogenetic switches, with light-controlled activity spanning ~1000-fold dynamic range. Long-read sequencing across selection cycles enabled high-resolution tracking of evolving variant pools, revealing adaptive trajectories and context-dependent residue interactions. Mechanistically, we find that linker mutations promoting α-helix extension at the sensor-effector junction enhance conformational coupling between LOV2 and AraC. These variants emerge consistently across independently evolved pools, underscoring their functional relevance. Together, we develop a framework for the directed evolution of programmable allosteric switches in vivo. By coupling dynamic selection with deep mutational scanning and temporal sequencing, it enables both functional optimization and mechanistic insight into allosteric networks.
6.
Optogenetic Tools for Spatiotemporal Interrogation of Cytoskeletal Dynamics.
Abstract:
The cytoskeleton is a dynamic intracellular network that governs cell shape, migration, division, and mechanotransduction. Precise spatiotemporal control of cytoskeletal regulation is essential for understanding how these processes are coordinated in physiology and disease, yet conventional pharmacological and genetic approaches often lack sufficient resolution or reversibility. Optogenetic technologies provide a powerful alternative by enabling light-controlled, noninvasive manipulation of cytoskeletal regulators with high temporal precision and subcellular specificity. This review summarizes recent advances in genetically encoded optogenetic tools for interrogating cytoskeletal dynamics. We discuss core design strategies, including allosteric regulation, light-induced oligomerization, heterodimerization, and dissociation, and highlight representative applications targeting actin filaments, microtubules, and upstream signaling pathways such as Rho family GTPases. We conclude by outlining current limitations and emerging directions, including improved tissue penetration, reduced phototoxicity, and multiplexed optical control, which are expected to further expand the utility of optogenetics in cytoskeleton research.
7.
OptoTAT reveals microtubule acetylation as a rapid trigger for GEF-H1-mediated cell migration.
Abstract:
Microtubule acetylation is implicated in regulating cell motility, yet its physiological role in directional migration and the underlying molecular mechanisms have remained unclear. This knowledge gap has persisted primarily due to a lack of tools capable of rapidly manipulating microtubule acetylation in actively migrating cells. To overcome this limitation and elucidate the causal relationship between microtubule acetylation and cell migration, we developed a novel optogenetic actuator, optoTAT, which enables precise induction of microtubule acetylation within minutes in live cells. Implementing optoTAT in migration assays, we observed striking and rapid responses at both molecular and cellular levels. First, microtubule acetylation triggers release of the RhoA activator GEF-H1 from sequestration on microtubules. This release subsequently enhances actomyosin contractility and drives focal adhesion maturation. These subcellular processes collectively promote sustained directional migration. Our findings position GEF-H1 as a critical molecular responder to microtubule acetylation, enabling a dynamic crosstalk between the actin and microtubule cytoskeletal networks in the coordination of cellular motility.
8.
Zebrafish as a Model for Cardiovascular Disease Using Nanotechnology and Emerging Optogenetic Tools.
Abstract:
Recent advances in experimental model systems have improved our ability to study cardiovascular development, function, and disease with high spatial and temporal resolution. The zebrafish (Danio rerio) has emerged as a powerful vertebrate model for cardiovascular research due to its transparency, genetic tractability, and conserved cardiac physiology, similar to humans. These features allow real-time in vivo imaging, the functional assessment of cardiac performance, and the tracking of signaling pathways that are fundamental in cardiovascular development and disease. Recent advances in nanotechnology and optogenetics have introduced complementary tools for probing and manipulating cardiovascular systems with high spatial and temporal precision. Nanoparticle-based platforms enable the tunable delivery of drugs, nucleic acids, and imaging agents, while optogenetic systems allow the light-mediated control of gene expression, signaling pathways, and cardiac electrophysiology. In this review, we summarize recent progress in the application of nanoparticle-based technologies and the emerging optogenetic tools in zebrafish cardiovascular research, including the optical control of cardiac signaling and electrophysiology. We briefly discuss emerging complementary efforts toward nanoparticle and optogenetic approaches, how to overcome key technical limitations, such as light penetration and gene delivery, and how to facilitate the development of fully optical platforms for cardiovascular disease modeling and drug screening.
9.
Red/far-red light optogenetics: technological principles and biomedical applications.
Abstract:
As an interdisciplinary frontier integrating optical technologies and genetic principles, optogenetics enables precise spatiotemporal control of gene expression and neuronal activity via light-sensitive molecular assemblies, thereby driving transformative advancements in biomedical fields. Red/far-red light optogenetic tools, by virtue of the advantages of long wavelengths, have emerged as powerful platforms for deep-tissue manipulations for both basic researches and clinical applications. Although a number of in-depth studies on various red/far-red light optogenetic tools and their biomedical applications have been published, there has not yet been a comprehensive review that systematically summarizes the advancements of diverse researches on this type of optogenetics. This article systematically delineates the technology of red/far-red light optogenetics, focusing on the molecular mechanisms and biomedical applications of two core photoreceptor protein families: phytochromes and channelrhodopsins. Phytochromes distributed in plants, bacteria and fungi undergo reversible red/far-red light-driven conformational conversion, initiating downstream signaling cascades that support various optogenetic technologies. Channelrhodopsins, originally microalgal blue-light-gated cation channels, are engineered into red-shifted variants, enabling rapid and non-invasive red/far-red light-controlled neuronal excitability manipulation at precise spatiotemporal resolution. The representative case studies of applications of phytochromes-based optogenetic tools in gene editing, transcriptional regulation, light-gated drug delivery and deep tissue imaging and diagnosis; as well as applications of red-shifted channelrhodopsins-based optogenetic tools in spatiotemporally precise neuromodulation are discussed in detail. Moreover, the main technical challenges in the utilization of red/far-red light optogenetic tools are analyzed. With continuous advancements of wavelength-optimized actuators and closed-loop control architectures, red/far-red light optogenetic techniques are poised to drive multidisciplinary convergence, offering unprecedented tools for decoding cellular dynamics and accelerating therapeutic discoveries.
10.
Advances in mechanistic understanding of light signal transduction derived from plant structural biology.
Abstract:
Light is a pivotal environmental signal regulating diverse plant developmental and physiological processes, including seed germination, hypocotyl elongation, phototropism, metabolite biosynthesis, stress resistance, temperature response, and circadian rhythms. Multiple signal transduction pathways of ultraviolet, blue light, and red/far-red light as well as related protein interaction networks in plants have been identified. Deciphering the mechanisms of light perception and signal transduction is of great significance to crop breeding and optogenetic manipulation. Structural biology has profoundly advanced the studies of light signal transduction by elucidating high-resolution three-dimensional (3D) structures of photoreceptors and their downstream signaling components. These studies uncover the molecular basis underlying perception and transduction of different light signals by plants. This review summarizes key structural findings of plant light signal transduction, highlighting the architectures and molecular functions of photoreceptors and associated signaling factors. We also outline the mechanisms underlying photoreceptor activation, inhibition, and regulatory interactions within light signaling networks and discuss the challenges in this field.
11.
Optogenetic manipulation of estrogen receptor signaling to improve estrogen deficiency.
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Liu, J
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Xie, L
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Wang, J
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Chen, Q
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Zhu, M
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Zhang, L
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Xie, S
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Lu, B
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Chen, X
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Xu, Y
Abstract:
Estrogen receptor (ER)-mediated genomic actions are crucial for maintaining various physiological functions, and their dysfunction is associated with numerous human diseases. Traditional estrogen replacement therapy (ERT) is commonly used to manage estrogen deficiency-related conditions, such as vulvovaginal atrophy during menopause, but its systemic effects pose notable risks. This study introduces OptoER, an optogenetic tool engineered to precisely modulate ER-mediated genomic pathways through light-induced transcription regulation, offering spatial-temporal control over ER-dependent gene expression. Our in vitro studies demonstrate that OptoER significantly enhances ER-specific gene transcription and protein synthesis, leading to improved cell proliferation and migration. In a proof-of-principle study using ovariectomized (OVX) mice, OptoER demonstrated considerable therapeutic potential for vaginal atrophy, with observed improvement in epithelial thickness and keratinization. These findings suggest that OptoER provides a targeted therapeutic strategy for estrogen deficiency conditions, with significant implications for treating vaginal atrophy and promoting regenerative healing in estrogen-deprived tissues.
12.
Rapid optogenetic manipulation of autophagy reveals that the nuclear pore complex is a robust autophagy substrate.
Abstract:
Autophagy, a conserved recycling process, manages intracellular quality control to mitigate stress. To determine the rapid effects of autophagy perturbation, we developed the first optogenetic tool to rapidly inhibit autophagy, termed ASAP. Our approach selectively inhibits autophagy within 5 minutes, providing a precise and dynamic approach to study autophagy regulation. Proteomic profiling with ASAP revealed the most tightly regulated autophagy substrates along with novel, previously unidentified substrates, including nuclear pore complex (NPC) proteins. Interestingly, autophagy regulates quality control of incomplete NPCs still in the cytoplasm via specific LC3-interacting regions (LIRs), sparing NPCs embedded in the nuclear envelope. Upon rapid autophagy inhibition, incomplete NPCs accumulate and instead of undergoing autophagic degradation, cytoplasmic NPCs aggregate in processing bodies. Using ASAP, we demonstrate rapid and specific inhibition of autophagy, revealing that the nuclear pore complex is a tightly regulated autophagy substrate.
13.
Optogenetics for Investigating and Targeting Hallmark Traits of Cancer.
Abstract:
The light-mediated, specific, and precise control of cell functions enabled by optogenetics has become a versatile method for investigating and combatting cancer. An increasing set of optogenetic tools enables tightly controlled regulation of ion flux across biological membranes, gene expression, gene editing, and protein-protein interactions and is being used to interrogate hallmark traits of cancer at the cellular, subcellular, and organismic level. This enables, on the one hand, the identification of critical signaling circuits required for cancer development and progression in vitro and in animal models and can flag potential intervention points for pharmacologic interference. On the other hand, optogenetics can improve the level of control in cell-based therapeutics. The current article provides a review of optogenetic tools and approaches used in the cancer research field and their multiple applications for improving our understanding of signal transduction pathways, modulating immune functions in the tumor microenvironment, facilitating drug screening, or directly attacking cancer cells. Key advantages and achievements of optogenetics in the cancer research field and remaining barriers for clinical applications are discussed.
14.
Versatile applications of Light-Oxygen-Voltage (LOV) domain proteins in optical microscopy.
Abstract:
Various blue-light photoreceptor proteins have photo-responsive domains known as light, oxygen, voltage (LOV) domains, which are extensively distributed in plants, algae, fungi, and bacteria. When exposed to blue light, the flavin chromophore and a highly conserved cysteine residue form a covalent adduct on a microsecond time scale. LOV domains are common photosensory modules that can be applied to optogenetics, regulated synthesis of reactive oxygen species, and fluorescence microscopy. This review explores the photocycle kinetics and applications of various LOV domains, which have been explored for confocal microscopy, two-photon microscopy, and super-resolution microscopy. Many LOV domains have been derived and modulated for use in different types of microscopic applications. Molecular understanding, diversity of LOV domains, and versatile photo-physical characteristics of these proteins have immense potential for the development of useful probes for various microscopy tools. There is a great demand for perspective research on LOV domain proteins for harnessing their possible optobiotechnological applications.
15.
Single-cell analysis and control of microbial systems using optogenetics.
Abstract:
Single-cell resolution studies have transformed our understanding of microbial systems, revealing substantial cell-to-cell heterogeneity and complex dynamic behaviors. This review describes recent advances in using optogenetics, where light-sensitive proteins control cellular processes, to investigate microbial behavior at the individual cell level. We discuss studies where optogenetic approaches have enabled high-resolution analysis of properties such as relative cell positioning, subcellular localization, morphology, and gene expression dynamics. In addition, we highlight emerging feedback and event-driven control methods that dynamically modulate cellular states using light signals. By leveraging light's unique capabilities for spatial and temporal manipulation, researchers can now probe cellular characteristics with unprecedented precision. We anticipate significant advances as researchers introduce more sophisticated dynamically patterned light signals for single-cell microbial research.
16.
The cell biologist's guide to detecting and modulating membrane phospholipids.
Abstract:
Molecular biology has benefited enormously from repurposed tools-many enzymes and antibodies evolved for other functions but are now essential for interrogating biological function by manipulating proteins or nucleic acids. In contrast, lipids have remained technically difficult to visualize or manipulate in cells. This review introduces tools that bring lipid biology into reach for molecular cell biologists, using familiar experimental approaches. We first describe adaptations of immunofluorescence and live-cell imaging of fluorescent molecules to track lipids. Then, we discuss tools for manipulating lipid levels, including pharmacologic inhibitors, synthetic biology platforms for inducible lipid generation or degradation, and optogenetic systems for precise temporal control. While some methods remain technically demanding, most tools are now broadly accessible. Our goal is to offer a practical framework for integrating lipid biology into mainstream cell biology experiments.
17.
Design principles for optogenetic-based targeted protein degradation.
Abstract:
Precise regulation of protein abundance is essential for understanding dynamic cellular processes and for advancing therapeutic development. However, existing approaches lack the spatiotemporal resolution required to these cellular processes. Recent advances in optogenetics have enabled the design of optogenetic targeted protein degradation systems (Opto-TPD) allowing reversible and non-invasive control of protein stability with high spatiotemporal precision. In this review, we systematically summarize the design principles of Opto-TPD tools, including those based on light-oxygen-voltage (LOV)-domain conformational systems, light-inducible dimerization systems, and light-controlled degradation tool expression systems. We further highlight their applications in probing protein function, modulating signaling pathways, and therapeutic translations. By comparing the mechanistic features, performance, and limitations of each platform, we aim to provide a comprehensive resource for guiding future tool optimization. Altogether, these Opto-TPD tools represent a powerful and versatile complement to existing protein manipulation technologies, expanding the toolbox for precise control of protein homeostasis in living systems.
18.
Optogenetic Proximity Labeling Maps Spatially Resolved Mitochondrial Surface Proteomes and a Locally Regulated Ribosome Pool.
Abstract:
Outer mitochondrial membranes (OMM) function as dynamic hubs for inter-organelle communication, integrating bidirectional signals, and coordinating organelle behavior in a context-dependent manner. However, tools for mapping mitochondrial surface proteomes with high spatial and temporal resolution remain limited. Here, we introduce an optogenetic proximity labeling strategy using LOV-Turbo, a light-activated biotin ligase, to profile mitochondrial surface proteomes with improved precision, temporal control, and reduced background. By fusing LOV-Turbo to a panel of variants of an OMM-anchored protein, Miro1, we generate spatially distinct baits that resolve modular architectures and regulatory states of the OMM proteomes across diverse conditions, a database we name MitoSurf. Building on this proteomic map, we present RiboLOOM, a platform that defines LOV-Turbo labeled ribosomes and their bound mRNAs at the mitochondrial surface. MitoSurf and RiboLOOM uncover a spatially distinct ribosome pool at the OMM that is maintained by Miro1, enabling local mRNA engagement and translation of mitochondria-related proteins. These findings establish Miro1 as a key organizer of mitochondrial protein biogenesis through spatial confinement of surface-associated ribosomes. Our platform reveals an uncharted layer of mitochondrial surface biology and provides a generalizable strategy to dissect dynamic RNA-protein-organelle interfaces in living cells.
19.
Closed-loop optogenetic control of cell biology enables outcome-driven microscopy.
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Passmore, JB
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Rates, A
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Schröder, J
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van Laarhoven, MTP
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Hellebrekers, VJW
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van Hoef, HG
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Geurts, AJM
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van Straaten, W
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Nijenhuis, W
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Berger, F
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Smith, CS
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Smal, I
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Kapitein, LC
Abstract:
Smart microscopy is transforming biological imaging by integrating real-time analysis with adaptive acquisition to enhance imaging efficiency. Whereas many emerging implementations are event-driven and focus on on-demand data acquisition to reduce phototoxicity, we here present 'outcome-driven' microscopy, a framework combining smart microscopy with optogenetics to control cell biological processes and achieve predefined outcomes. We validate this approach using light-based control of cell migration and nucleocytoplasmic transport, demonstrating robust spatiotemporal control of cellular behaviour in single cells and in cell populations.
20.
Evolution and design shape protein dynamics in LOV domains - spanning picoseconds to days.
Abstract:
Light-sensitive proteins allow organisms to perceive and respond to their environment, and have diversified over billions of years. Among these, Light-Oxygen-Voltage (LOV) domains are widespread photosensors that control diverse physiological processes and are increasingly used in optogenetics. Yet, the evolutionary constraints that shaped their protein dynamics and thereby their functional diversity remain poorly resolved. Here we systematically characterize the dynamics of 21 natural LOV core domains, significantly extending the spectroscopically resolved catalog through the addition of 18 previously unstudied variants. Using time-resolved spectroscopy, we uncover an exceptional kinetic diversity spanning from picoseconds to days and identify distinct functional clusters within the LOV family. These clusters reflect evolutionary branching, including a divergence of ≈1.0 billion years between investigatedLOV variants from plants and ≈0.4 billion years of separation within one of these functional clusters. Individual variants with extreme photocycles emerge as promising anchor points for optogenetic applications, ranging from highly efficient adduct formation to ultrafast recovery. Beyond natural diversity, we introduce a LOV domain generated by artificial intelligence-guided protein design. Despite being sequentially remote from its maternal template, this variant retains core photocycle function while exhibiting unique biophysical properties, thereby occupying a new region on the biophysical landscape. Our work emphasizes how billions of years of evolution defined LOV protein dynamics, and how protein design can expand this repertoire, engineering next-generation optogenetic tools.
21.
Optogenetic engineering of synthetic and natural receptors: design principles, functional mechanisms and biomedical applications.
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Zhao, J
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Chen, Y
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Gao, B
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Zhang, L
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Gao, N
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Hao, S
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Gao, Z
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Cai, W
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Yang, J
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Yang, G
Abstract:
Cellular receptors serve as central hubs that translate external signals into intracellular programs governing cell fate, function and behavior. Achieving precise and reversible control over receptor activity has long been a major challenge in both fundamental biology and translational medicine. Optogenetic receptor engineering provides a transformative solution by integrating photosensitive domains into natural receptor frameworks. This strategy enables light-dependent modulation of signaling with high spatial and temporal precision while maintaining minimal disturbance to endogenous pathways. Unlike chemogenetic systems or classical photoreceptive ion channels, this approach preserves endogenous ligand specificity and avoids slow ligand diffusion/clearance-associated artifacts. Through such systems, researchers can dissect causal relationships in dynamic signaling events, finely manipulate neuromodulatory and immune circuits and program cellular activities involved in development and tissue regeneration. The approach also allows quantitative control of signaling intensity and duration, offering new opportunities for linking molecular design to physiological outcomes. By combining optogenetic principles with advances in materials science and bioelectronics, future designs may achieve improved optical fidelity, enhanced light penetration and better signal amplification within complex biological environments. Integration with AI-guided protein engineering may also accelerate the discovery of optimized photosensory-receptor pairings. Together, these developments point to an emerging field where light-responsive receptors function as programmable interfaces between photonic control and cellular computation. In summary, the engineering of optogenetic receptors establishes a conceptual and technological framework for reversible, accurate and tunable regulation of cellular communication. This review summarizes current progress, outlines key design principles and provides conceptual guidelines for advancing next-generation light-responsive receptors and their biomedical applications. However, key translational challenges-including immunogenicity of non-human photoreceptors, limited gene-delivery efficiency and long-term biosafety-remain to be addressed through nonviral delivery strategies, autologous cell engineering and de-immunized or humanized photoreceptor design.
22.
Technological advances in visualizing and rewiring microtubules during plant development.
Abstract:
Microtubules are crucial regulators of plant development and are organized by a suite of microtubule-associated proteins (MAPs) that can rapidly remodel the array in response to various cues. This complexity has inspired countless studies into microtubule function from the subcellular to tissue scale, revealing an ever-increasing number of microtubule-dependent processes. Developing a comprehensive understanding of how local microtubule configuration, dynamicity, and remodeling drive developmental progression requires new approaches to capture and alter microtubule behavior. In this review, we will introduce the technological advancements we believe are poised to transform the study of microtubules in plant cells. In particular, we focus on (1) advanced imaging and analysis methods to quantify microtubule organization and behavior, and (2) novel tools to target specific microtubule populations in vivo. By showcasing innovative methodologies developed in non-plant systems, we hope to motivate their increased adoption and raise awareness of possible means of adapting them for studying microtubules in plants.
23.
Engineered AcrIIA5 for optogenetic control of CRISPR-Cas9-based genome editing.
Abstract:
The CRISPR-Cas9 system has been proven to be a powerful tool for gene editing in living cells and shows great potential in genetic disease treatment. Anti-CRISPR (Acr)-based optogenetic tools could spatiotemporally regulate the activity of CRISPR-Cas9, thereby improving the precision and safety of gene editing. However, these tools could only regulate a certain Cas9 protein because of the high specificity of Acr used, limiting their further application. In this study, we developed a new optogenetic tool named CASANOVA-A5 (CRISPR-Cas9 activity switching via a novel optogenetic variant of AcrIIA5) by inserting the blue light sensor AsLOV2 into AcrIIA5 with a broad inhibition spectrum. We proved that the CASANOVA-A5 could regulate the gene editing activity of SpCas9, SaCas9, NmeCas9, and St1Cas9 in a blue light-dependent manner. Additionally, we engineered AcrIIA5-LOV9 by integrating the blue light-dependent degron module LOV9, showing obvious optical regulation for SpCas9. Together, our work demonstrates two feasible methods to engineer the Acrs to potent optogenetic tools and suggests systematic strategies for further optimization.
24.
Coiled-coil register transitions and coupling with the effector's inhibitory site enables high fold changes in blue light-regulated diguanylate cyclases.
Abstract:
Cellular signaling cascades rely on transfer of information from one protein to another or within a single protein. To facilitate signal integration, specific structural motifs evolved that allow signal processing and also enable modular downstream response integration, facilitating sophisticated regulatory mechanisms. On a structural level, especially coiled-coil helices are frequently observed as signaling motifs. In diguanylate cyclases (DGCs) featuring GGDEF domains, N-terminal coiled-coils frequently activate systems by rearrangements of the interdimer active site. The variety of sensory domains that modulate this structural equilibrium in response to different stimuli highlights the importance of DGCs in bacterial adaptation. One interesting example of sensor DGCs is blue light-activated light-oxygen-voltage (LOV)-GGDEF couples. Here, we describe molecular details of a two-stage mechanism that allows tight dark-state inhibition while enabling high enzymatic activities upon illumination, achieving fold changes exceeding 10,000-fold. Using an in vivo activity assay, we screened amino acid substitutions at the inhibitory interface and the sensor-effector linker region to identify variants that promote enzymatic activity in the dark. In combination with chimeras of LOV and GGDEF domains preventing inhibitory interface formation, we successfully stabilized elongated active-state conformations and confirmed the role of the inhibitory interface between sensor and effector in the tight dark-state inhibition. Interestingly, the initially generated chimeras are still light regulatable as long as the linker sequence is not stabilized in either inhibiting or stimulating coiled-coil register. Our results offer valuable insights for potential optogenetic applications but also demonstrate inherent challenges associated with Methylotenera sp. LOV-activated DGCs.
25.
Structural characterization of Meiothermus ruber LOV domain.
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Semenov, O
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Nazarenko, V
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Yudenko, A
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Kovalev, K
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Goncharov, I
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Natarov, I
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Mikhailov, A
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Kuznetsova, E
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Nikolaev, A
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Yang, Y
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Sluchanko, NN
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Borshchevskiy, V
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Remeeva, A
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Gushchin, I
Abstract:
Light Oxygen Voltage (LOV) domains are important widespread receptors of blue light that also found applications in optogenetics and imaging. While LOV domains from mesophiles are relatively well characterized, their counterparts from thermophilic microorganisms remain understudied. Here, we express two constructs of a LOV domain belonging to a histidine kinase from Meiothermus ruber, MrLOV and MrLOVe, and show that they are photoactive, with recovery time values of 21 and 27 min, respectively, and thermostable. Crystal structures reveal that MrLOV, which lacks helices A'α and Jα, forms a parallel dimer, whereas MrLOVe is a tetramer organized as an antiparallel dimer of two parallel dimers interacting via helices Jα. One MrLOVe dimer is symmetric, and the other is asymmetric, with conformational differences mirroring activation-related changes in other LOV domains. Our data provide the structural basis for understanding and engineering of thermophilic LOVs and pave the way for development of thermostable and photostable LOV-derived optogenetic tools and flavin-based fluorescent proteins.