Georgios Pothoulakis scite author profile

8Characterisation of genetic control elements is essential for the predictable engineering 9 of synthetic biology systems. The current standard for in vivo characterisation of control 10 elements is through the use of fluorescent reporter proteins such as green fluorescent 11 protein (GFP). Gene expression, however, involves not only protein production but also 12 the production of messenger RNA (mRNA). Here we present the use of the Spinach 13 aptamer sequence, an RNA mimic of GFP, as a tool to characterise mRNA expression in 14 Escherichia coli. We show how the aptamer can be incorporated into gene expression 15 cassettes and how co-expressing it with a red fluorescent protein (mRFP1) allows, for 16 the first time, simultaneous measurement of mRNA and protein levels from engineered 17 constructs. Using flow cytometry, we apply this tool here to evaluate ribosome binding 18 site sequences and promoters and use it to highlight the differences in the temporal 19 behaviour of transcription and translation. 20 21

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Utilizing RNA origami scaffolds in Saccharomyces cerevisiae for dCas9-mediated transcriptional control

Pothoulakis

Nguyen

Andersen

2022

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Designer RNA scaffolds constitute a promising tool for synthetic biology, as they can be genetically expressed to perform specific functions in vivo such as scaffolding enzymatic cascades and regulating gene expression through CRISPR-dCas9 applications. RNA origami is a recently developed RNA design approach that allows construction of large RNA nanostructures that can position aptamer motifs to spatially organize other molecules, including proteins. However, it is still not fully understood how positioning multiple aptamers on a scaffold and the orientation of a scaffold affects functional properties. Here, we investigate fusions of single-guide RNAs and RNA origami scaffolds (termed sgRNAO) capable of recruiting activating domains for control of gene expression in yeast. Using MS2 and PP7 as orthogonal protein-binding aptamers, we observe a gradual increase in transcriptional activation for up to four aptamers. We demonstrate that different aptamer positions on a scaffold and scaffold orientation affect transcriptional activation. Finally, sgRNAOs are used to regulate expression of enzymes of the violacein biosynthesis pathway to control metabolic flux. The integration of RNA origami nanostructures at promoter sites achieved here, can in the future be expanded by the addition of functional motifs such as riboswitches, ribozymes and sensor elements to allow for complex gene regulation.

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Synthetic gene regulation for independent external induction of the Saccharomyces cerevisiae pseudohyphal growth phenotype

Pothoulakis

Ellis

2018

Commun Biol

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Pseudohyphal growth is a multicellular phenotype naturally performed by wild budding yeast cells in response to stress. Unicellular yeast cells undergo gross changes in their gene regulation and elongate to form branched filament structures consisting of connected cells. Here, we construct synthetic gene regulation systems to enable external induction of pseudohyphal growth in Saccharomyces cerevisiae. By controlling the expression of the natural PHD1 and FLO8 genes we are able to trigger pseudohyphal growth in both diploid and haploid yeast, even in different types of rich media. Using this system, we also investigate how members of the BUD gene family control filamentation in haploid cells. Finally, we employ a synthetic genetic timer network to control pseudohyphal growth and further explore the reversibility of differentiation. Our work demonstrates that synthetic regulation can exert control over a complex multigene phenotype and offers opportunities for rationally modifying the resulting multicellular structure.

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Synthetic Translational Regulation by Protein-Binding RNA Origami Scaffolds

2022

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Rational design approaches for the regulation of gene expression are expanding the synthetic biology toolbox. However, only a few tools for regulating gene expression at the translational level have been developed. Here, we devise an approach for translational regulation using the MS2 and PP7 aptamer and coat-protein pairs in Escherichia coli . The aptamers are used as operators in transcription units that encode proteins fused to their cognate coat proteins, which leads to self-repression. RNA origami scaffolds that contain up to four aptamers serve as an alternate binder to activate translation. With this system, we demonstrate that the increase in expression of a reporter protein is dependent on both the concentration and number of aptamers on RNA origami scaffolds. We also demonstrate regulation of multiple proteins using a single MS2 coat protein fusion and apply this method to regulate the relative expression of enzymes of the branched pathway for deoxyviolacein biosynthesis.

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Using Spinach Aptamer to Correlate mRNA and Protein Levels in Escherichia coli

Pothoulakis¹,

Ellis²

2015

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