A Green-Light-Responsive System for the Control of Transgene Expression in Mammalian and Plant Cells

Chatelle, Claire; Ochoa-Fernandez, Rocio; Engesser, Raphael; Schneider, Nils; Beyer, Hannes M.; Jones, Alex R.; Timmer, Jens; Zurbriggen, Matías D.; Weber, Wilfried

doi:10.1021/acssynbio.7b00450

Cited by 73 publications

(52 citation statements)

References 45 publications

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“…Despite these technical and experimental constraints, the first optogenetic tools have already been successfully implemented in plants (Table 1). These include a phytochrome-based red light-inducible and a CarH-based green light-regulated expression system (Müller et al, 2014;Ochoa-Fernandez et al, 2016;Chatelle et al, 2018). The former is activated by red light and inactivated by far-red light.…”

Section: Transcriptional Switchesmentioning

confidence: 99%

“…Simple supplementation of ambient illumination in greenhouses with low intensities of far-red light keeps the system repressed. Irradiation with red light leads to quantitatively controlled activation of gene expression (Müller et al, 2014;Chatelle et al, 2018). The second strategy comprises the engineering of a green lightinducible bacterial photoreceptor, CarH.…”

Section: Transcriptional Switchesmentioning

confidence: 99%

“…The second strategy comprises the engineering of a green lightinducible bacterial photoreceptor, CarH. Use of green light as a stimulus minimizes the interference with endogenous plant photoreceptors, as this region of the sunlight spectrum normally does not produce physiologically active signaling responses of relevance (Chatelle et al, 2018).…”

Section: Transcriptional Switchesmentioning

confidence: 99%

“…The development of optogenetic systems lags behind in plants, mostly because of the experimental constraints posed by the unavoidable exposure to environmental light. However, optogenetic approaches in plants have been reported, including phytochrome-and CarH-based, red-and green-light-inducible expression systems (Müller et al, 2014;Ochoa-Fernandez et al, 2016;Chatelle et al, 2018). This opens novel perspectives for engineering synthetic, light-triggered circuits in plants.…”

Section: B Box 1 Optogeneticsmentioning

confidence: 99%

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Synthetic Switches and Regulatory Circuits in Plants

2019

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Synthetic biology is an established but ever-growing interdisciplinary field of research currently revolutionizing biomedicine studies and the biotech industry. The engineering of synthetic circuitry in bacterial, yeast, and animal systems prompted considerable advances for the understanding and manipulation of genetic and metabolic networks; however, their implementation in the plant field lags behind. Here, we review theoretical-experimental approaches to the engineering of synthetic chemical-and light-regulated (optogenetic) switches for the targeted interrogation and control of cellular processes, including existing applications in the plant field. We highlight the strategies for the modular assembly of genetic parts into synthetic circuits of different complexity, ranging from Boolean logic gates and oscillatory devices up to semi-and fully synthetic open-and closed-loop molecular and cellular circuits. Finally, we explore potential applications of these approaches for the engineering of novel functionalities in plants, including understanding complex signaling networks, improving crop productivity, and the production of biopharmaceuticals.

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Section: Transcriptional Switchesmentioning

confidence: 99%

Section: Transcriptional Switchesmentioning

confidence: 99%

Section: Transcriptional Switchesmentioning

confidence: 99%

Section: B Box 1 Optogeneticsmentioning

confidence: 99%

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Synthetic Switches and Regulatory Circuits in Plants

2019

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“…As a target we chose Am1_c0023g2, a red/green GAF domain from Acaryochloris marina, that can bind two distinct bilins -PCB or biliverdin (BV) (27 Am1_c0023g2 can be made responsive to either green, orange, red or far-red light. Optogenetic tools that respond to green light are currently limited to complex cobalamin based systems (28,29) and CcaS/CcaR or cPAC systems that have predefined functions -gene expression (30), or adenylyl cyclase activity respectively (26). In addition, small, monomeric optogenetic tools that operate with far-red light are useful since far-red absorption provides deep tissue penetration ability for use in living animals (31).…”

Section: Introductionmentioning

confidence: 99%

Green, orange, red, and far-red optogenetic tools derived from cyanobacteriochromes

Jang

McDonald

Uppalapati

et al. 2019

Preprint

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Existing optogenetic tools for controlling protein-protein interactions are available in a limited number of wavelengths thereby limiting opportunities for multiplexing. The cyanobacteriochrome (CBCR) family of photoreceptors responds to an extraordinary range of colors, but light-dependent binding partners for CBCR domains are not currently known. We used a phage-display based approach to develop small (~50-residue) monomeric binders selective for the green absorbing state (Pg), or for the red absorbing state (Pr) of the CBCR Am1_c0023g2 with a phycocyanobilin chromophore and also for the far-red absorbing state (Pfr) of Am1_c0023g2 with a biliverdin chromophore. These bind in a 1:1 mole ratio with KDs for the target state from 0.2 to 2 µM and selectivities from 10 to 500-fold. We demonstrate green, orange, red, and far-red light-dependent control of protein-protein interactions in vitro and also in vivo where these multicolor optogenetic tools are used to control transcription in yeast.

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Spatiotemporal Control Over Multicellular Migration Using Green Light Reversible Cell–Cell Interactions

et al. 2021

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cell-cell adhesions leads to the progression of cancer [1c] and subsequent metastasis. [4] Additionally, the control of cell-cell interactions is of interest in the field of bottomup tissue-engineering, which aims to assemble cells as the basic unit into functional tissues. [5] Precise control in time and space over cell-cell interactions is required to successfully assemble appropriate multicellular architectures that resemble the in vivo structures and to control how cells work together within a tissue.In recent years, many tools have been developed to control the formation and the disassembly of cell-cell interactions in a controlled manner and thereby have given insight into the role of cell-cell adhesions. [6] For instance, chemical modifications of the plasma membrane with bioorthogonal reactive functional groups [7] and specific noncovalent interaction partners [8] including complementary DNA strands, [9] biotin-streptavidin, [10] and supramolecular binding partners [11] result in the formation of chemical bonds between neighboring cells. However, in only a few examples, it is possible to reverse these cell-cell interactions once formed. [11] To overcome general concerns related to the chemical modification of the cell membrane (e.g., degradation over time, off-target cell toxicity), it is possible to regulate the expression and the activity of genetically encoded native cell-cell adhesion molecules such as cadherins [12] or artificial surface receptors. [1d,9b,6,12,13] These adhesions allow cells to not only just be brought together but in some cases also to transduce intracellular signals. [1e,12,14] Photoregulation of cell-cell adhesions provides high spatiotemporal control, since light, as a stimulus, can be focused on the desired area and delivered at any given time. Using photocleavable nitrobenzyl [15] and switchable azobenzyl [14] chemical linkers, it has been shown possible to control cell-cell interactions with UV light. [11b,15,16] More recently, optogenetic tools for the regulation of cell-cell interactions with visible light have improved the biocompatibility, [13b,e] while also making it possible to dynamically and reversibly control cell-cell interactions between multiple cell types. [13b,e,16b,17] In these reports, photoswitchable proteins were expressed on the cell's plasma membrane as artificial adhesion molecules, which induced cell-cell interactions through the light-dependent dimerization of these proteins. [6] Depending on the photoswitchable proteins employed cell-cell adhesions between the same or differentThe regulation of cell-cell adhesions in space and time plays a crucial role in cell biology, especially in the coordination of multicellular behavior. Therefore, tools that allow for the modulation of cell-cell interactions with high precision are of great interest to a better understanding of their roles and building tissuelike structures. Herein, the green light-responsive protein CarH is expressed at the plasma membrane of cells as an artificial cell adhesion rece...

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A Green-Light-Responsive System for the Control of Transgene Expression in Mammalian and Plant Cells

Cited by 73 publications

References 45 publications

Synthetic Switches and Regulatory Circuits in Plants

Synthetic Switches and Regulatory Circuits in Plants

Green, orange, red, and far-red optogenetic tools derived from cyanobacteriochromes

Spatiotemporal Control Over Multicellular Migration Using Green Light Reversible Cell–Cell Interactions

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