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Engineering an Optogenetic CRISPRi Platform for Improved Chemical Production

Peiling Wu, Yu‐Fen Chen, Mingyu Liu, Gezhi Xiao, Jifeng Yuan

2020ACS Synthetic Biology54 citationsDOI

Abstract

Microbial synthesis of chemicals typically requires the redistribution of metabolic flux toward the synthesis of targeted products. Dynamic control is emerging as an effective approach for solving the hurdles mentioned above. As light could control the cell behavior in a spatial and temporal manner, the optogenetic-CRISPR interference (opto-CRISPRi) technique that allocates the metabolic resources according to different optical signal frequencies will enable bacteria to be controlled between the growth phase and the production stage. In this study, we applied a blue light-sensitive protein EL222 to regulate the expression of the dCpf1-mediated CRISPRi system that turns off the competitive pathways and redirects the metabolic flux toward the heterologous muconic acid synthesis in Escherichia coli. We found that the opto-CRISPRi system dynamically regulating the suppression of the central metabolism and competitive pathways could increase the muconic acid production by 130%. These results demonstrated that the opto-CRISPRi platform is an effective method for enhancing chemical synthesis with broad utilities.

Topics & Concepts

OptogeneticsCRISPR interferenceMetabolic engineeringSynthetic biologyFlux (metallurgy)CRISPRBiochemical engineeringEscherichia coliChemistryMetabolic pathwayBiologyBiological systemComputational biologyBiochemistryMetabolismCas9EnzymeNeuroscienceGeneEngineeringOrganic chemistryCRISPR and Genetic EngineeringMicrobial Metabolic Engineering and BioproductionGene Regulatory Network Analysis
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