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Genome-scale and pathway engineering for the sustainable aviation fuel precursor isoprenol production in Pseudomonas putida

Deepanwita Banerjee, Ian Sofian Yunus, Xi Wang, Jinho Kim, Jinho Kim, Aparajitha Srinivasan, Russel Menchavez, Yan Chen, Jennifer Gin, Christopher J. Petzold, Héctor García Martín, Jon Magnuson, Paul D. Adams, Blake A. Simmons, Aindrila Mukhopadhyay, Joonhoon Kim, Joonhoon Kim, Taek Soon Lee

2024Metabolic Engineering39 citationsDOIOpen Access PDF

Abstract

Sustainable aviation fuel (SAF) will significantly impact global warming in the aviation sector, and important SAF targets are emerging. Isoprenol is a precursor for a promising SAF compound DMCO (1,4-dimethylcyclooctane) and has been produced in several engineered microorganisms. Recently, Pseudomonas putida has gained interest as a future host for isoprenol bioproduction as it can utilize carbon sources from inexpensive plant biomass. Here, we engineer metabolically versatile host P. putida for isoprenol production. We employ two computational modeling approaches (Bilevel optimization and Constrained Minimal Cut Sets) to predict gene knockout targets and optimize the "IPP-bypass" pathway in P. putida to maximize isoprenol production. Altogether, the highest isoprenol production titer from P. putida was achieved at 3.5 g/L under fed-batch conditions. This combination of computational modeling and strain engineering on P. putida for an advanced biofuels production has vital significance in enabling a bioproduction process that can use renewable carbon streams.

Topics & Concepts

Pseudomonas putidaAviationSustainable productionProduction (economics)Scale (ratio)GenomeMetabolic engineeringBiologyBiotechnologyEngineeringGeneticsGeneGeographyAerospace engineeringEconomicsCartographyMacroeconomicsMicrobial Metabolic Engineering and BioproductionBiofuel production and bioconversionPlant biochemistry and biosynthesis