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

Abstract Microbial lipid metabolism is an attractive route for producing aliphatic chemicals, commonly referred to as oleochemicals. The predominant metabolic engineering strategy centers on heterologous thioesterases capable of producing fatty acids of desired size. To convert acids to desired oleochemicals (e.g. fatty alcohols, ketones), metabolic engineers modify cells to block beta-oxidation, reactivate fatty acids as coenzyme-A thioesters, and redirect flux towards termination enzymes with broad substrate utilization ability. These genetic modifications narrow the substrate pool available for the termination enzyme but cost one ATP per reactivation - an expense that could be saved if the acyl-chain was directly transferred from ACP- to CoA-thioester. In this work, we demonstrate an alternative acyl-transferase strategy for producing medium-chain oleochemicals. Through bioprospecting, mutagenesis, and metabolic engineering, we developed strains of Escherichia coli capable of producing over 1 g/L of medium-chain free fatty acids, fatty alcohols, and methyl ketones using the transacylase strategy.