Controlling gene expression with light: a multidisciplinary endeavour

Hartmann, Denis; Smith, Jefferson M.; Mazzotti, Giacomo; Chowdhry, Razia; Booth, Michael J.

doi:10.1042/bst20200014

Cited by 22 publications

(44 citation statements)

References 161 publications

(196 reference statements)

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“… [2] Mostly, genetically encoded light‐sensitive photoreceptors, which have their natural origin in plants or fungi (e. g. LOV domains, phytochromes or other photosensory proteins), are used to construct recombinant control elements applicable for activating or repressing transcription. [ 1b , 3 ] In contrast, light‐activatable molecules consist of a bioactive component and a photoremovable protecting group, retaining it in an inactive state until irradiation with a certain wavelength restores its bioactivity by photochemically initiated covalent bond cleavage. [4] Different types of biomolecules as nucleic acids, peptides or small inducer molecules can be targeted with this method to achieve light‐regulated gene expression.…”

Section: Introductionmentioning

confidence: 99%

“… [4] Different types of biomolecules as nucleic acids, peptides or small inducer molecules can be targeted with this method to achieve light‐regulated gene expression. [ 1b , 5 ] However, there is still a limited number of small molecule‐inducible gene expression systems available, which have been addressed by light‐regulation. Most of them were targeted in eukaryotic cells by ecdysone, [6] doxycycline, [7] tamoxifen, [8] cyclofen‐OH, [9] methionine, [10] and copper.…”

Section: Introductionmentioning

confidence: 99%

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Optochemical Control of Bacterial Gene Expression: Novel Photocaged Compounds for Different Promoter Systems

et al. 2021

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Photocaged compounds are applied for implementing precise, optochemical control of gene expression in bacteria. To broaden the scope of UV-light-responsive inducer molecules, six photocaged carbohydrates were synthesized and photochemically characterized, with the absorption exhibiting a red-shift. Their differing linkage through ether, carbonate, and carbamate bonds revealed that carbonate and carbamate bonds are convenient. Subsequently, those compounds were successfully applied in vivo for controlling gene expression in E. coli via blue light illumination. Furthermore, benzoate-based expression systems were subjected to light control by establishing a novel photocaged salicylic acid derivative. Besides its synthesis and in vitro characterization, we demonstrate the challenging choice of a suitable promoter system for light-controlled gene expression in E. coli. We illustrate various bottlenecks during both photocaged inducer synthesis and in vivo application and possibilities to overcome them. These findings pave the way towards novel caged inducer-dependent systems for wavelength-selective gene expression.This article is part of a Special Collection dedicated to the Biotrans 2021 conference. Please see our homepage for more articles in the collection.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Optochemical Control of Bacterial Gene Expression: Novel Photocaged Compounds for Different Promoter Systems

et al. 2021

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“…One caveat to the current light-activated DNA templates, and most other synthetic light-activated systems on offer, stems from the use of UV light, which can be cytotoxic at high doses and has little tissue penetration ( Olejniczak et al, 2015 ); therefore, there is a need for light-activated systems that respond to longer wavelengths of light. Alternative optogenetic systems such as light-activated TFs ( Jayaraman et al, 2018 ) or two-component systems ( Zhang et al, 2020 ) can also be used to control cell-free gene expression with more red-shifted wavelengths of light, and other light-activated systems that work well in bacteria may transition into CFPS ( Hartmann et al, 2020 ), although this has yet to be realised. Light-responsive gene expression could be used to controllably produce and release small molecules or proteins and might be applied in tissue engineering efforts to spatially control morphogen gradients and direct tissue differentiation.…”

Section: Alternative Parts For Controlling Communicationmentioning

confidence: 99%

Controlling Synthetic Cell-Cell Communication

Smith

Chowdhry

Booth

2022

Front. Mol. Biosci.

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Synthetic cells, which mimic cellular function within a minimal compartment, are finding wide application, for instance in studying cellular communication and as delivery devices to living cells. However, to fully realise the potential of synthetic cells, control of their function is vital. An array of tools has already been developed to control the communication of synthetic cells to neighbouring synthetic cells or living cells. These tools use either chemical inputs, such as small molecules, or physical inputs, such as light. Here, we examine these current methods of controlling synthetic cell communication and consider alternative mechanisms for future use.

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“…1,2 Because specific tissues can be illuminated at precise timepoints, photoactivatable reagents are well-suited for inducing molecular perturbations in whole organisms with spatial and temporal control. 3,4 These technologies are particularly useful when applied in optically transparent model organisms that develop ex utero such as zebrafish, 5 sea urchins, 6 and ascidians. 7 Oligonucleotide-based reagents are especially versatile probes as they can be readily designed to specifically target any gene, 8,9 and phosphorodiamidate morpholino oligonucleotides (MOs) have been most commonly used to inhibit gene expression in vivo.…”

Section: Introductionmentioning

confidence: 99%

Double-Lariat Caged Morpholino Oligonucleotides for Optical Gene Silencing

Pattanayak

Deiters

Chen

2022

Preprint

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Caged morpholino oligonucleotides (cMOs) are synthetic tools that allow light-inducible gene silencing in live organisms. Previously reported cMOs have utilized hairpin, duplex, and cyclic structures, as well as caged nucleobases. While these optochemical technologies enable efficient optical gene silencing, they can have limited dynamic range. To address this issue, a new caging strategy was developed where the two MO termini are conjugated to an internal position through a self-immolative trifunctional linker, thereby generating a bicyclic cMO with a double lariat-like structure. The efficacy of this alternative cMO design has been demonstrated in zebrafish embryos and compared to the monocyclic constructs.

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Controlling gene expression with light: a multidisciplinary endeavour

Cited by 22 publications

References 161 publications

Optochemical Control of Bacterial Gene Expression: Novel Photocaged Compounds for Different Promoter Systems

Optochemical Control of Bacterial Gene Expression: Novel Photocaged Compounds for Different Promoter Systems

Controlling Synthetic Cell-Cell Communication

Double-Lariat Caged Morpholino Oligonucleotides for Optical Gene Silencing

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