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Topologies of synthetic gene circuit for optimal fold change activation

Phyana Litovco, Natalia Barger, Ximing Li, Ramez Daniel

2021Nucleic Acids Research24 citationsDOIOpen Access PDF

Abstract

Computations widely exist in biological systems for functional regulations. Recently, incoherent feedforward loop and integral feedback controller have been implemented into Escherichia coli to achieve a robust adaptation. Here, we demonstrate that an indirect coherent feedforward loop and mutual inhibition designs can experimentally improve the fold change of promoters, by reducing the basal level while keeping the maximum activity high. We applied both designs to six different promoters in E. coli, starting with synthetic inducible promoters as a proof-of-principle. Then, we examined native promoters that are either functionally specific or systemically involved in complex pathways such as oxidative stress and SOS response. Both designs include a cascade having a repressor and a construct of either transcriptional interference or antisense transcription. In all six promoters, an improvement of up to ten times in the fold change activation was observed. Theoretically, our unitless models show that when regulation strength matches promoter basal level, an optimal fold change can be achieved. We expect that this methodology can be applied in various biological systems for biotechnology and therapeutic applications.

Topics & Concepts

PromoterBiologySynthetic biologyRepressorComputational biologyTranscription (linguistics)GeneFeed forwardTranscription factorGeneticsCell biologyGene expressionEngineeringPhilosophyControl engineeringLinguisticsGene Regulatory Network AnalysisCRISPR and Genetic EngineeringBacterial Genetics and Biotechnology
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