Litcius/Paper detail

Metabolic engineering strategies to produce medium-chain oleochemicals via acyl-ACP:CoA transacylase activity

Qiang Yan, William T. Cordell, Michael A. Jindra, Dylan K. Courtney, Madeline K Kuckuk, Xuanqi Chen, Brian F. Pfleger

2022Nature Communications29 citationsDOIOpen Access PDF

Abstract

Microbial lipid metabolism is an attractive route for producing oleochemicals. The predominant strategy centers on heterologous thioesterases to synthesize desired chain-length fatty acids. To convert acids to oleochemicals (e.g., fatty alcohols, ketones), the narrowed fatty acid pool needs to be reactivated as coenzyme A thioesters at cost of one ATP per reactivation - an expense that could be saved if the acyl-chain was directly transferred from ACP- to CoA-thioester. Here, we demonstrate such an alternative acyl-transferase strategy by heterologous expression of PhaG, an enzyme first identified in Pseudomonads, that transfers 3-hydroxy acyl-chains between acyl-carrier protein and coenzyme A thioester forms for creating polyhydroxyalkanoate monomers. We use it to create a pool of acyl-CoA's that can be redirected to oleochemical products. Through bioprospecting, mutagenesis, and metabolic engineering, we develop three strains of Escherichia coli capable of producing over 1 g/L of medium-chain free fatty acids, fatty alcohols, and methyl ketones.

Topics & Concepts

ThioesterMetabolic engineeringCoenzyme ABiochemistryThioesteraseChemistryHeterologous expressionFatty acidPolyhydroxyalkanoatesEnzymeEscherichia coliBiosynthesisBiologyBacteriaRecombinant DNAGeneGeneticsReductaseMicrobial Metabolic Engineering and BioproductionEnzyme Catalysis and Immobilizationbiodegradable polymer synthesis and properties