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.

Showing 1 - 8 of 8 results
1.

Gene Delivery and Analysis of Optogenetic Induction of Lytic Cell Death.

blue CRY2clust CRY2olig HT-29
Curr Protoc, Apr 2024 DOI: 10.1002/cpz1.1023 Link to full text
Abstract: Necroptosis is a form of inflammatory lytic cell death involving active cytokine production and plasma membrane rupture. Progression of necroptosis is tightly regulated in time and space, and its signaling outcomes can shape the local inflammatory environment of cells and tissues. Pharmacological induction of necroptosis is well established, but the diffusive nature of chemical death inducers makes it challenging to study cell-cell communication precisely during necroptosis. Receptor-interacting protein kinase 3, or RIPK3, is a crucial signaling component of necroptosis, acting as a crucial signaling node for both canonical and non-canonical necroptosis. RIPK3 oligomerization is crucial to the formation of the necrosome, which regulates plasma membrane rupture and cytokine production. Commonly used necroptosis inducers can activate multiple downstream signaling pathways, confounding the signaling outcomes of RIPK3-mediated necroptosis. Opsin-free optogenetic techniques may provide an alternative strategy to address this issue. Optogenetics uses light-sensitive protein-protein interaction to modulate cell signaling. Compared to chemical-based approaches, optogenetic strategies allow for spatiotemporal modulation of signal transduction in live cells and animals. We developed an optogenetic system that allows for ligand-free optical control of RIPK3 oligomerization and necroptosis. This article describes the sample preparation, experimental setup, and optimization required to achieve robust optogenetic induction of RIPK3-mediated necroptosis in colorectal HT-29 cells. We expect that this optogenetic system could provide valuable insights into the dynamic nature of lytic cell death. © 2024 The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: Production of lentivirus encoding the optogenetic RIPK3 system Support Protocol: Quantification of the titer of lentivirus Basic Protocol 2: Culturing, chemical transfection, and lentivirus transduction of HT-29 cells Basic Protocol 3: Optimization of optogenetic stimulation conditions Basic Protocol 4: Time-stamped live-cell imaging of HT-29 lytic cell death Basic Protocol 5: Quantification of HT-29 lytic cell death.
2.

Spatially Defined Gene Delivery into Native Cells with the Red Light-Controlled OptoAAV Technology.

red PhyB/PIF6 A-431 in vitro
Curr Protoc, Jun 2022 DOI: 10.1002/cpz1.440 Link to full text
Abstract: The OptoAAV technology allows spatially defined delivery of transgenes into native target cells down to single-cell resolution by the illumination with cell-compatible and tissue-penetrating red light. The system is based on an adeno-associated viral (AAV) vector of serotype 2 with an engineered capsid (OptoAAV) and a photoreceptor-containing adapter protein mediating the interaction of the OptoAAV with the surface of the target cell in response to low doses of red and far-red light. In this article, we first provide detailed protocols for the production, purification, and analysis of the OptoAAV and the adapter protein. Afterward, we describe in detail the application of the OptoAAV system for the light-controlled transduction of human cells with global and patterned illumination. © 2022 The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: Production, purification, and analysis of PhyB-DARPinEGFR adapter protein Basic Protocol 2: Production, purification, and analysis of OptoAAV Basic Protocol 3: Red light-controlled viral transduction with the OptoAAV system Support Protocol: Spatially resolved transduction of two transgenes with the OptoAAV system.
3.

SPARK: A Transcriptional Assay for Recording Protein-Protein Interactions in a Defined Time Window.

blue AsLOV2 HEK293T
Curr Protoc, Jul 2021 DOI: 10.1002/cpz1.190 Link to full text
Abstract: Protein-protein interactions (PPIs) are ubiquitously involved in cellular processes such as gene expression, enzymatic catalysis, and signal transduction. To study dynamic PPIs, real-time methods such as Förster resonance energy transfer and bioluminescence resonance energy transfer can provide high temporal resolution, but they only allow PPI detection in a limited area at a time and do not permit post-PPI analysis or manipulation of the cells. Integration methods such as the yeast two-hybrid system and split protein systems integrate PPI signals over time and allow subsequent analysis, but they lose information on dynamics. To address some of these limitations, an assay named SPARK (Specific Protein Association tool giving transcriptional Readout with rapid Kinetics) has recently been published. Similar to many existing integrators, SPARK converts PPIs into a transcriptional signal. SPARK, however, also adds blue light as a co-stimulus to achieve temporal gating; SPARK only records PPIs during light stimulation. Here, we describe the procedures for using SPARK assays to study a dynamic PPI of interest, including designing DNA constructs and optimization in HEK293T/17 cell cultures. These protocols are generally applicable to various PPI partners and can be used in different biological contexts. © 2021 Wiley Periodicals LLC. Basic Protocol 1: Designing DNA constructs for SPARK Basic Protocol 2: Performing the SPARK assay in HEK293T/17 cell cultures Support Protocol 1: Lentivirus preparation Support Protocol 2: Immunostaining of SPARK components.
4.

Optogenetic Tools for Manipulating Protein Subcellular Localization and Intracellular Signaling at Organelle Contact Sites.

blue Magnets Cos-7 HeLa U-2 OS
Curr Protoc, 3 Mar 2021 DOI: 10.1002/cpz1.71 Link to full text
Abstract: Intracellular signaling processes are frequently based on direct interactions between proteins and organelles. A fundamental strategy to elucidate the physiological significance of such interactions is to utilize optical dimerization tools. These tools are based on the use of small proteins or domains that interact with each other upon light illumination. Optical dimerizers are particularly suitable for reproducing and interrogating a given protein-protein interaction and for investigating a protein's intracellular role in a spatially and temporally precise manner. Described in this article are genetic engineering strategies for the generation of modular light-activatable protein dimerization units and instructions for the preparation of optogenetic applications in mammalian cells. Detailed protocols are provided for the use of light-tunable switches to regulate protein recruitment to intracellular compartments, induce intracellular organellar membrane tethering, and reconstitute protein function using enhanced Magnets (eMags), a recently engineered optical dimerization system. © 2021 Wiley Periodicals LLC. Basic Protocol 1: Genetic engineering strategy for the generation of modular light-activated protein dimerization units Support Protocol 1: Molecular cloning Basic Protocol 2: Cell culture and transfection Support Protocol 2: Production of dark containers for optogenetic samples Basic Protocol 3: Confocal microscopy and light-dependent activation of the dimerization system Alternate Protocol 1: Protein recruitment to intracellular compartments Alternate Protocol 2: Induction of organelles' membrane tethering Alternate Protocol 3: Optogenetic reconstitution of protein function Basic Protocol 4: Image analysis Support Protocol 3: Analysis of apparent on- and off-kinetics Support Protocol 4: Analysis of changes in organelle overlap over time.
5.

Optogenetic Control of RhoA to Probe Subcellular Mechanochemical Circuitry.

blue TULIP HEK293T
Curr Protoc Cell Biol, Mar 2020 DOI: 10.1002/cpcb.102 Link to full text
Abstract: Spatiotemporal localization of protein function is essential for physiological processes from subcellular to tissue scales. Genetic and pharmacological approaches have played instrumental roles in isolating molecular components necessary for subcellular machinery. However, these approaches have limited capabilities to reveal the nature of the spatiotemporal regulation of subcellular machineries like those of cytoskeletal organelles. With the recent advancement of optogenetic probes, the field now has a powerful tool to localize cytoskeletal stimuli in both space and time. Here, we detail the use of tunable light-controlled interacting protein tags (TULIPs) to manipulate RhoA signaling in vivo. This is an optogenetic dimerization system that rapidly, reversibly, and efficiently directs a cytoplasmic RhoGEF to the plasma membrane for activation of RhoA using light. We first compare this probe to other available optogenetic systems and outline the engineering logic for the chosen recruitable RhoGEFs. We also describe how to generate the cell line, spatially control illumination, confirm optogenetic control of RhoA, and mechanically induce cell-cell junction deformation in cultured tissues. Together, these protocols detail how to probe the mechanochemical circuitry downstream of RhoA signaling. © 2020 by John Wiley & Sons, Inc. Basic Protocol 1: Generation of a stable cell line expressing TULIP constructs Basic Protocol 2: Preparation of collagen substrate for imaging Basic Protocol 3: Transient transfection for visualization of downstream effectors Basic Protocol 4: Calibration of spatial illumination Basic Protocol 5: Optogenetic activation of a region of interest.
6.

LOVTRAP: A Versatile Method to Control Protein Function with Light.

blue LOVTRAP Cos-7 HEK293 HeLa
Curr Protoc Cell Biol, 1 Dec 2016 DOI: 10.1002/cpcb.12 Link to full text
Abstract: We describe a detailed procedure for the use of LOVTRAP, an approach to reversibly sequester and release proteins from cellular membranes using light. In the application described here, proteins that act at the plasma membrane are held at mitochondria in the dark, and reversibly released by irradiation. The technique relies on binding of an engineered Zdk domain to a LOV2 domain, with affinity <30 nM in the dark and >500 nM upon irradiation between 400 and 500 nm. LOVTRAP can be applied to diverse proteins, as it requires attaching only one member of the Zdk/LOV2 pair to the target protein, and the other to the membrane where the target protein is to be sequestered. Light-induced protein release occurs in less than a second, and the half-life of return can be adjusted using LOV point mutations (∼2 to 500 sec). © 2016 by John Wiley & Sons, Inc.
7.

Optogenetic Control of Nuclear Protein Import in Living Cells Using Light-Inducible Nuclear Localization Signals (LINuS).

blue AsLOV2 HEK293T
Curr Protoc Chem Biol, 2 Jun 2016 DOI: 10.1002/cpch.4 Link to full text
Abstract: Many biological processes are regulated by the timely import of specific proteins into the nucleus. The ability to spatiotemporally control the nuclear import of proteins of interest therefore allows study of their role in a given biological process as well as controlling this process in space and time. The light-inducible nuclear localization signal (LINuS) was developed based on a natural plant photoreceptor that reversibly triggers the import of proteins of interest into the nucleus with blue light. Each LINuS is a small, genetically encoded domain that is fused to the protein of interest at the N or C terminus. These protocols describe how to carry out initial microscopy-based screening to assess which LINuS variant works best with a protein of interest. © 2016 by John Wiley & Sons, Inc.
8.

Tools for controlling protein interactions using light.

blue UV Cryptochromes UV receptors Review
Curr Protoc Cell Biol, 2 Sep 2014 DOI: 10.1002/0471143030.cb1716s64 Link to full text
Abstract: Genetically encoded actuators that allow control of protein-protein interactions using light, termed 'optical dimerizers', are emerging as new tools for experimental biology. In recent years, numerous new and versatile dimerizer systems have been developed. Here we discuss the design of optical dimerizer experiments, including choice of a dimerizer system, photoexcitation sources, and the coordinate use of imaging reporters. We provide detailed protocols for experiments using two dimerization systems we previously developed, CRY2/CIB and UVR8/UVR8, for use in controlling transcription, protein localization, and protein secretion using light. Additionally, we provide instructions and software for constructing a pulse-controlled LED device for use in experiments requiring extended light treatments.
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