Curated Optogenetic Publication Database

Abstract: The development of multicellular organisms is controlled by highly dynamic molecular and cellular processes organized in spatially restricted patterns. Recent advances in optogenetics are allowing protein function to be controlled with the precision of a pulse of laser light in vivo, providing a powerful new tool to perturb developmental processes at a wide range of spatiotemporal scales. In this Primer, we describe the most commonly used optogenetic tools, their application in developmental biology and in the nascent field of synthetic morphogenesis.

Abstract: Optogenetics has demonstrated great potential in the fields of tissue engineering and regenerative medicine, from basic research to clinical applications. Spatiotemporal encoding during individual development has been widely identified and is considered a novel strategy for regeneration. A as a noninvasive method with high spatiotemporal resolution, optogenetics are suitable for this strategy. In this review, we discuss roles of dynamic signal coding in cell physiology and embryonic development. Several optogenetic systems are introduced as ideal optogenetic tools, and their features are compared. In addition, potential applications of optogenetics for tissue engineering are discussed, including light-controlled genetic engineering and regulation of signaling pathways. Furthermore, we present how emerging biomaterials and photoelectric technologies have greatly promoted the clinical application of optogenetics and inspired new concepts for optically controlled therapies. Our summation of currently available data conclusively demonstrates that optogenetic tools are a promising method for elucidating and simulating developmental processes, thus providing vast prospects for tissue engineering and regenerative medicine applications.

Abstract: Non-neuronal optogenetic approaches empower precise regulation of protein dynamics in live cells but often require target-specific protein engineering. To address this challenge, we developed a generalizable light-modulated protein stabilization system (GLIMPSe) to control intracellular protein level independent of its functionality. We applied GLIMPSe to control two distinct classes of proteins: mitogen-activated protein kinase phosphatase 3 (MKP3), a negative regulator of the extracellu-lar signal-regulated kinase (ERK) pathway, as well as a constitutively active form of MEK (CA MEK), a positive regulator of the same pathway. Kinetics study showed that light-induced protein stabilization could be achieved within 30 minutes of blue light stimulation. GLIMPSe enables target-independent optogenetic control of protein activities and therefore minimizes the systematic variation embedded within different photoactivatable proteins. Overall, GLIMPSe promises to achieve light-mediated post-translational stabilization of a wide array of target proteins in live cells.

Abstract: Introduction: Controlling gene expression is a fundamental goal of basic and synthetic biology because it allows insight into cellular function and control of cellular activity. We explored the possibility of generating an optogenetic repressor of gene expression in the model organism Saccharomyces cerevisiae by using light to control the nuclear localization of nuclease-dead Cas9, dCas9. Methods: The dCas9 protein acts as a repressor for a gene of interest when localized to the nucleus in the presence of an appropriate guide RNA (sgRNA). We engineered dCas9, the mammalian transcriptional repressor Mxi1, and an optogenetic tool to control nuclear localization (LINuS) as parts in an existing yeast optogenetic toolkit. This allowed expression cassettes containing novel dCas9 repressor configurations and guide RNAs to be rapidly constructed and integrated into yeast. Results: Our library of repressors displays a range of basal repression without the need for inducers or promoter modification. Populations of cells containing these repressors can be combined to generate a heterogeneous population of yeast with a 100-fold expression range. We find that repression can be dialed modestly in a light dose- and intensity-dependent manner. We used this library to repress expression of the lanosterol 14-alpha-demethylase Erg11, generating yeast with a range of sensitivity to the important antifungal drug fluconazole. Conclusions: This toolkit will be useful for spatiotemporal perturbation of gene expression in Saccharomyces cerevisiae. Additionally, we believe that the simplicity of our scheme will allow these repressors to be easily modified to control gene expression in medically relevant fungi, such as pathogenic yeasts.

Abstract: Optical dimerizers have been developed to untangle signaling pathways, but they are of limited use in vivo, partly due to their inefficient activation under two-photon (2P) excitation. To overcome this problem, we developed Förster resonance energy transfer (FRET)-assisted photoactivation, or FRAPA. On 2P excitation, mTagBFP2 efficiently absorbs and transfers the energy to the chromophore of CRY2. Based on structure-guided engineering, a chimeric protein with 40% FRET efficiency was developed and named 2P-activatable CRY2, or 2paCRY2. 2paCRY2 was employed to develop a RAF1 activation system named 2paRAF. In three-dimensionally cultured cells expressing 2paRAF, extracellular signal-regulated kinase (ERK) was efficiently activated by 2P excitation at single-cell resolution. Photoactivation of ERK was also accomplished in the epidermal cells of 2paRAF-expressing mice. We further developed an mTFP1-fused LOV domain that exhibits efficient response to 2P excitation. Collectively, FRAPA will pave the way to single-cell optical control of signaling pathways in vivo.

Abstract: Protein degradation is an effective native mechanism used in modulating intracellular information, and thus it plays an essential role in maintaining cellular homeostasis. Repurposing native protein degradation in a synthetic context is gaining attention as a new strategy to manipulate cellular behavior rapidly for a wide range of applications including disease detection and therapy. This review examines the native mechanisms and machineries by which mammalian cells degrade their own proteins including the sequence of events from identifying a candidate for degradation to the protein's destruction. Next, it explores engineering efforts to degrade both exogenous and native proteins with high specificity and control by targeting proteins into the degradation cascade. A complete understanding of design rules with an ability to use cellular information as signals will allow control over the cellular behavior in a well-defined manner.

Abstract: Collective cell migration is emerging as a major driver of embryonic development, organogenesis, tissue homeostasis, and tumor dissemination. In contrast to individually migrating cells, collectively migrating cells maintain cell-cell adhesions and coordinate direction-sensing as they move. While non-muscle myosin II has been studied extensively in the context of cells migrating individually in vitro, its roles in cells migrating collectively in three-dimensional, native environments are not fully understood. Here we use genetics, Airyscan microscopy, live imaging, optogenetics, and Förster resonance energy transfer to probe the localization, dynamics, and functions of myosin II in migrating border cells of the Drosophila ovary. We find that myosin accumulates transiently at the base of protrusions, where it functions to retract them. E-cadherin and myosin co-localize at border cell-border cell contacts and cooperate to transmit directional information. A phosphomimetic form of myosin is sufficient to convert border cells to a round morphology and blebbing migration mode. Together these studies demonstrate that distinct and dynamic pools of myosin II regulate protrusion dynamics within and between collectively migrating cells and suggest a new model for the role of protrusions in collective direction sensing in vivo. Movie S1 Movie S1 Live imaging of border cell specification and delamination from anterior epithelium From Figure 1D-I. Slbo promoter driving Lifeact-GFP (green) marks border cells, Upd-Gal4, UAS-DsRed.nls (red) mark polar cell nuclei. Hoechst 33342 (blue) marks DNA. Time resolution is 4 min. Movie S2 Movie S2 Representative Z-projected and registered live imaging of Sqh-mCherry accumulating in cortical junctions (flashing arrows) during border cell migration. From Figure 3J-K. Time resolution is 25 sec. Movie S3 Movie S3 Representative Z-projected and registered live imaging of E-cad-GFP during border cell migration. From Figure 3M-N. Time resolution is 60 sec. Movie S4 Movie S4 Representative Z-projection of control flpout cells from hs-Flp;, Slbo>Lifeact-GFP; AyGal4, UAS-RFP. Clonal cells are marked by magenta nuclei (nls-RFP). Time resolution is 2.5 min. From Supp. Figure 3 A-D. Movie S5 Movie S5 Representative Z-projection of Sqh-RNAi flpout cells from hs-Flp;, Slbo>Lifeact-GFP; AyGal4, UAS-RFP, UAS-sqh-RNAi. Clonal cells are marked by magenta nuclei (nls-RFP). Time resolution is 2.5 min. From Supp. Figure 3 E-H. Movie S6 Movie S6 Representative Z-projected c306-Gal4; tub-GAL80ts driving UAS-Lifeact-GFP and UAS-white RNAi. Time resolution is 2 min. From Supp. Figure 4 A-D. Movie S7 Movie S7 Representative Z-projected c306-Gal4; tub-GAL80ts driving UAS-Lifeact-GFP and UAS-sqh-RNAi showing frequent side protrusions. Time resolution is 2 min. From Supp. Figure 4 E-H. White arrows indicate ectopic side and rear protrusions. Movie S8 Movie S8 Representative Z-projected c306-Gal4; tub-GAL80ts driving UAS-Lifeact-GFP and UAS-sqh-RNAi showing long lived side protrusions. Time resolution is 2 min. From Supp. Figure 4 I-L. Movie S9 Movie S9 Representative Z-projected live imaging of c306-Gal4 driving UAS-white-RNAi in clusters co-expressing Lifeact-GFP under the control of the slbo enhancer and Sqh-mCherry from its endogenous promoter during periods of protrusive and round migration phases. From Figure 6A-D. 25 min corresponds to 6A and B and 1hr:25 min corresponds to 6C and D. Time resolution is 2.5 min. Movie S10 Movie S10 Sqh-mCherry (magenta) channel from Supplementary Movie 9. From Figure 6A-D. 25 min corresponds to 6A and B and 1hr:25 min corresponds to 6C and D. Time resolution is 2.5 min. Movie S11 Movie S11 Representative Z-projected live imaging of c306-Gal4 driving UAS-Ecad-RNAi in clusters co-expressing Lifeact-GFP under the control of the slbo enhancer and Sqh-mCherry from its endogenous promoter during a protrusive phase of migration. From Figure 6E-F. Time resolution is 2.5 min. Movie S12 Movie S12 Sqh-mCherry (magenta) channel from Supplementary Movie 11. From Figure 6E-F. Time resolution is 2.5 min. Movie S13 Movie S13 Representative Z-projected live imaging of c306-Gal4 driving UAS-Ecad-RNAi in clusters co-expressing Lifeact-GFP under the control of the slbo enhancer and Sqh-mCherry from its endogenous promoter during a rounded phase of migration. From Figure 6G-H. Time resolution is 2.5 min. Movie S14 Movie S14 Sqh-mCherry (magenta) channel from Supplementary Movie 13. From Figure 6G-H. Time resolution is 2.5 min. Movie S15 Movie S15 Example segmentation analysis from a representative Z-projected time lapse of a cluster expressing c306-Gal4 driving UAS-white-RNAi in clusters co-expressing Lifeact-GFP under the control of the slbo enhancer and Sqh-mCherry from its endogenous promoter during migration. Time lapse analyzed in Imaris by 1. segmentation of the cluster using Lifeact-GFP, 2. Rendering of Sqh-mCherry by masking the inside of the Life-act surface, 3. performing a distance transformation using the masked Sqh-mCherry that is color coded for distance from membrane (dark colors are short distances and bright/white colors are more distant), 4. combining the distance transformation with the Sqh-mCherry mask to only include the cortical 2 μm of the original Sqh-mCherry signal for quantification in Figure 6I. Movie S16 Movie S16 Representative Z-projected time lapse of Lifeact-GFP and Sqh-mCherry expressing clusters used for quantification of Figure 7B-C during protrusion/retractions cycles. Time resolution is 2 min. Movie S17 Movie S17 Sqh-mCherry channel from Supplementary movie 16. Time resolution is 2 min. Movie S18 Movie S18 Representative Z-projections of Lifeact-GFP (green) in c306-Gal4; tub-GAL80ts driving UAS-Lifeact-GFP and UAS-Sqh-E20E21 migrating border cells clusters that split. Time resolution is 2 min. Movie S19 Movie S19 Representative Z-projections of Lifeact-GFP (green) in c306-Gal4; tub-GAL80ts driving UAS-LifeactGFP and UAS-Sqh-E20E21 migrating border cells clusters during protrusive phase. Time resolution is 2 min. Movie S20 Movie S20 Representative Z-projection of Lifeact-GFP (green) in c306-Gal4; tub-GAL80ts driving UAS-Lifeact-GFP and UAS-Sqh-E20E21 border cells cluster at the oocyte border during a blebbing phase. Time resolution is 2 min. Movie S21 Movie S21 Representative Z-projection of control cluster expressing slbo-Gal4; UAS-PLCδ1-PH-GFP. Time resolution is 2 min. Movie S22 Movie S22 Representative Z-projection of cluster expressing slbo-Gal4; UAS-PLCδ1-PH-GFP, UAS-Rho1V14. Blebs are marked by white arrows. Time resolution is 2 min.

Abstract: Background Photocontrol of protein activity has become a helpful strategy for regulating biological pathways. Herein, a method for the precise and reversible photocontrol of oxidase activity was developed by using the conformational change of the AsLOV2 domain. Results The AsLOV2 domain was inserted into the nonconserved sites exposed on the surface of the AdhP protein, and the alov9 fusion was successfully screened for subsequent optical experiments under the assumption that neither of these actions affected the original activity of AdhP protein. The activity of alov9 was noticeably inhibited when the fusion was exposed to 470 nm blue light and recovered within 30 min. As a result, we could precisely and reversibly photocontrol alov9 activity through the optimization of several parameters, including cofactor concentration, light intensity, and illumination time. Conclusions An efficient method was developed for the photoinhibition of enzymatic activity based on the insertion of the light-sensitive AsLOV2 domain, providing new ideas for photocontrolling metabolic pathways without carriers in the future.

Abstract: Targeted cell ablation is a powerful approach for studying the role of specific cell populations in a variety of organotypic functions, including cell differentiation, and organ generation and regeneration. Emerging tools for permanently or conditionally ablating targeted cell populations and transiently inhibiting neuronal activities exhibit a diversity of application and utility. Each tool has distinct features, and none can be universally applied to study different cell types in various tissue compartments. Although these tools have been developed for over 30 years, they require additional improvement. Currently, there is no consensus on how to select the tools to answer the specific scientific questions of interest. Selecting the appropriate cell ablation technique to study the function of a targeted cell population is less straightforward than selecting the method to study a gene's functions. In this review, we discuss the features of the various tools for targeted cell ablation and provide recommendations for optimal application of specific approaches.

Abstract: Light-inducible approaches provide means to control biological systems with spatial and temporal resolution that is unmatched by traditional genetic perturbations. Recent developments of optogenetic and chemo-optogenetic systems for induced proximity in cells facilitate rapid and reversible manipulation of highly dynamic cellular processes and have become valuable tools in diverse biological applications. The new expansions of the toolbox facilitate control of signal transduction, genome editing, 'painting' patterns of active molecules onto cellular membranes and light-induced cell cycle control. A combination of light- and chemically induced dimerization approaches has also seen interesting progress. Here we provide an overview of the optogenetic systems and the emerging chemo-optogenetic systems, and discuss recent applications in tackling complex biological problems.

Abstract: We developed VIEW-MOD (Versatile Illumination Engine with a Modular Optical Design): a compact, multi-modality microscope, which accommodates multiple illumination schemes including variable angle total internal reflection, point scanning and vertical/horizontal light sheet. This system allows combining and flexibly switching between different illuminations and imaging modes by employing three electrically tunable lenses and two fast-steering mirrors. This versatile optics design provides control of 6 degrees of freedom of the illumination source (3 translation, 2 tilt, and beam shape) plus the axial position of the imaging plane. We also developed standalone software with an easy-to-use GUI to calibrate and control the microscope. We demonstrate the applications of this system and software in biosensor imaging, optogenetics and fast 3D volume imaging. This system is ready to fit into complex imaging circumstances requiring precise control of illumination and detection paths, and has a broad scope of usability for a myriad of biological applications.

Abstract: Light-sensing protein domains that link an exogenous light signal to the activity of an enzyme have attracted much notice for engineering new regulatory mechanisms into proteins and for studying the dynamic behavior of intracellular reactions as well as reaction cascades. Light-oxygen-voltage (LOV) photoreceptors are blue light-sensing modules that have been intensely characterized for this purpose and linked to several proteins of interest. For successful application of these tools it is crucial to identify appropriate fusion strategies for combining sensor and enzyme domains that sustain activity and light-induced responsivity. Terminal fusion of LOV domains is the natural strategy; however, this is not transferrable to T7 RNA polymerase since both of its termini are involved in catalysis. We show here that it is possible to covalently insert LOV domains into the polymerase protein while preserving its activity and generating new light-responsive allosteric coupling.

Abstract: In order to study the role of signaling proteins, such as kinases and GTPases, in brain functions it is necessary to control their activity at the appropriate spatiotemporal resolution and to examine the cellular and behavioral effects of such changes in activity. Reduced spatiotemporal resolution in the regulation of these proteins activity will impede the ability to understand the proteins normal functions as longer modification of their activity in non-normal locations could lead to effects different from their natural functions. To control intracellular signaling proteins at the highest temporal resolution recent innovative optogenetic approaches were developed to allow the control of photoactivable signaling proteins activity by light. These photoactivatable proteins can be activated in selected cell population in brain and in specific subcellular compartments. Minimal-invasive tools are being developed to photoactivate these proteins for study and therapy. Together these techniques afford an unprecedented spatiotemporal control of signaling proteins activity to unveil the function of brain proteins with high accuracy in behaving animals. As dysfunctional signaling proteins are involved in brain diseases, the optogenetic technique has also the potential to be used as a tool to treat brain diseases.

Abstract: Membrane contact sites (MCSs) are specialized subcellular compartments formed by closely apposed membranes from two organelles. The intermembrane gap is separated by a distance ranging from 10 to 35 nm. MCSs are typically maintained through dynamic protein-protein and protein-lipid interactions. These intermembrane contact sites constitute important intracellular signalling hotspots to mediate a plethora of cellular processes, including calcium homeostasis, lipid metabolism, membrane biogenesis and organelle remodelling. In recent years, a series of genetically encoded probes and chemogenetic or optogenetic actuators have been invented to aid the visualization and interrogation of MCSs in both fixed and living cells. These molecular tools have greatly accelerated the pace of mechanistic dissection of membrane contact sites at the molecular level. In this review, we present an overview on the latest progress in this endeavour, and provide a general guide to the selection of methods and molecular tools for probing interorganellar membrane contact sites.

Abstract: The transcription factor p53 is a stress sensor that turns specific sets of genes on to allow the cell to respond to the stress depending on its severity and type. p53 is classified as tumor suppressor because its function is to maintain genome integrity promoting cell cycle arrest, apoptosis, or senescence to avoid proliferation of cells with damaged DNA. While in many human cancers the p53 gene is itself mutated, there are some in which the dysfunction of the p53 pathway is caused by the overexpression of negative regulators of p53, such as Mdm2, that keep it at low levels at all times. Here we develop an optogenetic approach to control endogenous p53 levels with blue light. Specifically, we control the nuclear localization of the Mmd2-binding PMI peptide using the light-inducible export system LEXY. In the dark, the PMI-LEXY fusion is nuclear and binds to Mdm2, consenting to p53 to accumulate and transcribe the target gene p21. Blue light exposure leads to the export of the PMI-LEXY fusion into the cytosol, thereby Mdm2 is able to degrade p53 as in the absence of the peptide. This approach may be useful to study the effect of localized p53 activation within a tissue or organ.

Abstract: Control of protein activity in living cells can reveal the role of spatiotemporal dynamics in signaling circuits. Protein analogs with engineered allosteric responses can be particularly effective in the interrogation of protein signaling, as they can replace endogenous proteins with minimal perturbation of native interactions. However, it has been a challenge to identify allosteric sites in target proteins where insertion of responsive domains produces an allosteric response comparable to the activity of native proteins. Here, we describe a detailed protocol to generate genetically encoded analogs of proteins that can be allosterically controlled by either rapamycin or blue light, as well as experimental procedures to produce and test these analogs in vitro and in mammalian cell lines. We describe computational methods, based on crystal structures or homology models, to identify effective sites for insertion of either an engineered rapamycin-responsive (uniRapR) domain or the light-responsive light-oxygen-voltage 2 (LOV2) domain. The inserted domains allosterically regulate the active site, responding to rapamycin with irreversible activation, or to light with reversible inactivation at higher spatial and temporal resolution. These strategies have been successfully applied to catalytic domains of protein kinases, Rho family GTPases, and guanine exchange factors (GEFs), as well as the binding domain of a GEF Vav2. Computational tasks can be completed within a few hours, followed by 1-2 weeks of experimental validation. We provide protocols for computational design, cloning, and experimental testing of the engineered proteins, using Src tyrosine kinase, GEF Vav2, and Rho GTPase Rac1 as examples.

Abstract: Optogenetic control of protein activity is a versatile technique to gain control over cellular processes, e.g. for biomedical and biotechnological applications. Among other techniques, the regulation of protein abundance by controlling either transcription or protein stability found common use as this controls the activity of any type of target protein. Here, we report modules of an improved variant of the photosensitive degron module and a light-sensitive transcription factor, which we compared to doxycycline-dependent transcriptional control. Given their modularity the combined control of synthesis and stability of a given target protein resulted in the synergistic down regulation of its abundance by light. This combined module exhibits very high switching ratios, profound downregulation of protein abundance at low light-fluxes as well as fast protein depletion kinetics. Overall, this synergistic optogenetic multistep control (SOMCo) module is easy to implement and results in a regulation of protein abundance superior to each individual component.

Abstract: Stomata serve dual and often conflicting roles, facilitating carbon dioxide influx into the plant leaf for photosynthesis and restricting water efflux via transpiration. Strategies for reducing transpiration without incurring a cost for photosynthesis must circumvent this inherent coupling of carbon dioxide and water vapor diffusion. We expressed the synthetic, light-gated K+ channel BLINK1 in guard cells surrounding stomatal pores in Arabidopsis to enhance the solute fluxes that drive stomatal aperture. BLINK1 introduced a K+ conductance and accelerated both stomatal opening under light exposure and closing after irradiation. Integrated over the growth period, BLINK1 drove a 2.2-fold increase in biomass in fluctuating light without cost in water use by the plant. Thus, we demonstrate the potential of enhancing stomatal kinetics to improve water use efficiency without penalty in carbon fixation.

Abstract: The precise spatiotemporal regulation of protein synthesis is essential for many complex biological processes such as memory formation, embryonic development and tumor formation. Current methods used to study protein synthesis offer only a limited degree of spatiotemporal control. Optogenetic methods, in contrast, offer the prospect of controlling protein synthesis non-invasively within minutes and with a spatial scale as small as a single synapse. Here, we present a hybrid yeast system where growth depends on the activity of human eukaryotic initiation factor 4E (eIF4E) that is suitable for screening optogenetic designs for the down-regulation of protein synthesis. We used this system to screen a diverse initial panel of 15 constructs designed to couple a light switchable domain (PYP, RsLOV, LOV, Dronpa) to 4EBP2 (eukaryotic initiation factor 4E binding protein 2), a native inhibitor of translation initiation. We identified cLIPS1 (circularly permuted LOV inhibitor of protein synthesis 1), a fusion of a segment of 4EBP2 and a circularly permuted version of the LOV2 domain from Avena sativa, as a photo-activated inhibitor of translation. Adapting the screen for higher throughput, we tested small libraries of cLIPS1 variants and found cLIPS2, a construct with an improved degree of optical control. We show that these constructs can both inhibit translation in yeast harboring a human eIF4E in vivo, and bind human eIF4E in vitro in a light-dependent manner. This hybrid yeast system thus provides a convenient way for discovering optogenetic constructs that can regulate of human eIF4E-depednednt translation initiation in a mechanistically defined manner.

Abstract: Optical induction of intracellular signaling by membrane-associated and integral membrane proteins allows spatiotemporally precise control over second messenger signaling and cytoskeletal rearrangements that are important to cell migration, development, and proliferation. Optogenetic membrane recruitment of a protein-of-interest to control its signaling by altering subcellular localization is a versatile means to these ends. Here, we summarize the signaling characteristics and underlying structure-function of RGS-LOV photoreceptors as single-component membrane recruitment tools that rapidly, reversibly, and efficiently carry protein cargo from the cytoplasm to the plasma membrane by a light-regulated electrostatic interaction with the membrane itself. We place the technology-relevant features of these recently described natural photosensory proteins in context of summarized protein engineering and design strategies for optically controlling membrane protein signaling.

Abstract: Bacteriophytochromes are a subfamily of the diverse light responsive phytochrome photoreceptors. Considering their preferential interaction with biliverdin IXα as endogenous cofactor, they have recently been used for creating optogenetic tools and engineering fluorescent probes. Ideal absorption characteristics for the activation of bacteriophytochrome-based systems in the therapeutic near-infrared window as well the availability of biliverdin in mammalian tissues have resulted in tremendous progress in re-engineering bacteriophytochromes for diverse applications. At the same time, both the structural analysis and the functional characterization of diverse naturally occurring bacteriophytochrome systems have unraveled remarkable differences in signaling mechanisms and have so far only touched the surface of the evolutionary diversity within the family of bacteriophytochromes. This review highlights recent findings and future challenges.

Abstract: Optogenetics, genetically encoded engineering of proteins to respond to light, has enabled precise control of the timing and localization of protein activity in live cells and for specific cell types in animals. Light-sensitive ion channels have become well established tools in neurobiology, and a host of new methods have recently enabled the control of other diverse protein structures as well. This review focuses on approaches to switch proteins between physiologically relevant, naturally occurring conformations using light, accomplished by incorporating light-responsive engineered domains that sterically and allosterically control the active site.

Abstract: Cell morphogenesis is critical for embryonic development, tissue formation, and wound healing. Our ability to manipulate endogenous mechanisms to control cell shape, however, remains limited. Here we combined surface micropatterning of adhesion molecules with optogenetic activation of intracellular signaling pathways to control the nature and morphology of cellular protrusions. We employed geometry-dependent pre-organization of cytoskeletal structures together with acute activation of signaling pathways that control actin assembly to create a tool capable of generating membrane protrusions at defined cellular locations. Further, we find that the size of microfabricated patterns of adhesion molecules influences the molecular mechanism of cell protrusion: larger patterns enable cells to create actin-filled lamellipodia while smaller patterns promote formation of spherical blebs. Optogenetic perturbation of signaling pathways in these cells changes the size of blebs and convert them into lamellipodia. Our results demonstrate how the coordinated manipulation of adhesion geometry and cytoskeletal dynamics can be used to control membrane protrusion and cell morphogenesis.

Abstract: Biological networks sense extracellular stimuli and generate appropriate outputs within the cell that determine cellular response. Biological signal generators are becoming an important tool for understanding how information is transmitted in these networks and controlling network behavior. Signal generators produce well-defined, dynamic, intracellular signals of important network components, such as kinase activity or the concentration of a specific transcription factor. Synthetic biology tools coupled with in silico control have enabled the construction of these sophisticated biological signal generators. Here we review recent advances in biological signal generator construction and their use in systems biology studies. Challenges for constructing signal generators for a wider range of biological networks and generalizing their use are discussed.

Abstract: Optogenetic dimerizers are modular domains that can be utilized in a variety of versatile ways to modulate cellular biochemistry. Because of their modularity, many applications using these tools can be easily transferred to new targets without extensive engineering. While a number of photodimerizer systems are currently available, the field remains nascent, with new optimizations for existing systems and new approaches to regulating biological function continuing to be introduced at a steady pace.