Optogenetic switches for light-controlled gene expression in yeast

Salinas, F.; Rojas, Vicente; Delgado, Verónica; Agosín, Eduardo; Larrondo, Luis F.

doi:10.1007/s00253-017-8178-8

Cited by 39 publications

(41 citation statements)

References 100 publications

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“…Optogenetics take advantage of light‐sensitive genetically encoded proteins to actuate processes inside of the cell in a light‐dependent manner. Light is a powerful actuator as it is inexpensive, easily controlled in time and space, and S. cerevisiae contains no known native photoreceptors (Salinas, Rojas, Delgado, Agosin, & Larrondo, ). The ability to rapidly add and remove light from cell culture or spatially target specific cells makes it particularly advantageous for applications that require spatiotemporal precision such as dynamic stimulation or real‐time feedback control of cellular processes (Benzinger & Khammash, ; Castillo‐Hair, Igoshin, & Tabor, ; Harrigan, Madani, & El‐Samad, ; Lugagne & Dunlop, ; Milias‐Argeitis, Rullan, Aoki, Buchmann, & Khammash, ; Ng et al, ; Rullan, Benzinger, Schmidt, Milias‐Argeitis, & Khammash, ; Toettcher, Gong, Lim, & Weiner, ).…”

Section: Introductionmentioning

confidence: 99%

A yeast optogenetic toolkit (yOTK) for gene expression control in Saccharomyces cerevisiae

An-Adirekkun

Stewart

Geller

et al. 2019

Biotech & Bioengineering

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Optogenetic tools for controlling gene expression are ideal for tuning synthetic biological networks due to the exquisite spatiotemporal control available with light.Here we develop an optogenetic system for gene expression control integrated with an existing yeast toolkit allowing for rapid, modular assembly of light-controlled circuits in the important chassis organism Saccharomyces cerevisiae. We reconstitute activity of a split synthetic zinc-finger transcription factor (TF) using light-induced dimerization mediated by the proteins CRY2 and CIB1. We optimize function of this split TF and demonstrate the utility of the toolkit workflow by assembling cassettes expressing the TF activation domain and DNA-binding domain at different levels.Utilizing this TF and a synthetic promoter we demonstrate that light intensity and duty cycle can be used to modulate gene expression over the range currently available from natural yeast promoters. This study allows for rapid generation and prototyping of optogenetic circuits to control gene expression in S. cerevisiae. K E Y W O R D Slight-inducible promoter, MoClo, optogenetics, Saccharomyces cerevisiae, yeast Jidapas (My) An-adirekkun, Cameron J. Stewart, and Stephanie H. Geller contributed equally to this study.

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Section: Introductionmentioning

confidence: 99%

A yeast optogenetic toolkit (yOTK) for gene expression control in Saccharomyces cerevisiae

An-Adirekkun

Stewart

Geller

et al. 2019

Biotech & Bioengineering

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“…The performance of our light-dependent OptoMB/SH2 binding pair is comparable to that of other optical dimerization systems previously used to control transcription, protein-protein interactions, or protein localization 60–62 . However, these previous systems have been developed by fusing proteins of interest to specific light-dependent interaction partners (such as PhyB/PIF3 or Cry2/CIB) evolved in photosensitive organisms.…”

Section: Discussionmentioning

confidence: 68%

Light-responsive monobodies for dynamic control of customizable protein binding

Carrasco-López

Zhao

Gil

et al. 2020

Preprint

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Customizable, high affinity protein-protein interactions, such as those mediated by antibodies and antibody-like molecules, are invaluable to basic and applied research and have become pillars for modern therapeutics. The ability to reversibly control the binding activity of these proteins to their targets on demand would significantly expand their applications in biotechnology, medicine, and research. Here we present, as proof-of-principle, a light-controlled monobody (OptoMB) that works in vitro and in vivo, whose affinity for its SH2-domain target exhibits a 300-fold shift in binding affinity upon illumination. We demonstrate that our αSH2-OptoMB can be used to purify SH2-tagged proteins directly from crude E. coli extract, achieving 99.8% purity and over 40% yield in a single purification step. This OptoMB belongs to a new class of light-sensitive protein binders we call OptoBinders (OptoBNDRs) which, by virtue of their ability to be designed to bind any protein of interest, have the potential to find new powerful applications as light-switchable binders of untagged proteins with high affinity and selectivity, and with the temporal and spatial precision afforded by light.

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“…Alternatively, bursting could be controlled directly with a time course of induced gene expression. For chemical inducers, this can be accomplished in a microfluidics setting via regulated flow [25], but recent developments also allow arbitrary time courses of induction in bulk cultures using optogenetics [26]. Regarding duration of the expression bursts, our expectation is that for a detectable effect this duration should be shorter than the timescale to nucleate new clusters.…”

Section: Discussionmentioning

confidence: 99%

Physical model of protein cluster positioning in growing bacteria

et al. 2017

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Chemotaxic receptors in bacteria form clusters at cell poles and also laterally, and this clustering plays an important role in signal transduction. These clusters were found to be periodically arranged on the surface of the bacterium Escherichia coli, independent of any known positioning mechanism. In this work we extend a model based on diffusion and aggregation to more realistic geometries and present a means based on “bursty” protein production to distinguish spontaneous positioning from an independently existing positioning mechanism. We also consider the case of isotropic cellular growth and characterize the degree of order arising spontaneously. Our model could also be relevant for other examples of periodically positioned protein clusters in bacteria.

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Optogenetic switches for light-controlled gene expression in yeast

Cited by 39 publications

References 100 publications

A yeast optogenetic toolkit (yOTK) for gene expression control in Saccharomyces cerevisiae

A yeast optogenetic toolkit (yOTK) for gene expression control in Saccharomyces cerevisiae

Light-responsive monobodies for dynamic control of customizable protein binding

Physical model of protein cluster positioning in growing bacteria

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