Rational engineering to enhance C8-fatty acid biosynthesis in Picosynechococcus sp. PCC 7002

Medium-chain fatty acids (e.g., C8-C14) are important biofuel precursors that can be produced from CO 2 by cyanobacteria and other photoautotrophs. However, cyanobacteria naturally direct a relatively small fraction of fixed carbon to lipid synthesis, primarily producing long-chain membrane-bound fatty acids. We investigated whether mitigating kinetic bottlenecks within the fatty acid biosynthesis (FAB) pathway could enhance flux to free fatty acid (FFA) production in Picosynechococcus sp. PCC 7002. Previous in vitro studies proposed that the FAB initiating enzyme FabH is the primary rate-controlling enzyme in PCC 7002. We hypothesized that enhancing fatty acid initiation could increase in vivo FFA production while shifting the kinetic bottleneck further downstream in the pathway. We enabled C8-FFA accumulation by knocking out the native acyl-acyl carrier protein synthetase gene ( aas ) and expressing the highly active Cuphea palustris- derived mutant thioesterase CpFatB1.2-M4-287 (CupTE), which selectively catalyzes C8 chain termination. We then expressed the diatom-derived Chaetoceros sp . GSL56 FabH ortholog (chKASIII), to enhance initiation, and a medium-chain selective E. coli ketosynthase ecFabFI108F (ecFabF*), to enhance elongation. When expressed individually or in combination with ecFabF*, chKASIII slowed growth and decreased net carbon fixation rates relative to the parental Δaas -CupTE strain. However, co-expression of chKASIII, ecFabF*, and CupTE redirected a larger fraction of fixed carbon toward FFA production, increasing relative carbon flux to C8-FFA and decreasing the projected minimum selling price by four-fold. This work demonstrates how systems metabolic engineering can be applied to enhance C8-FFA production in cyanobacteria while highlighting the unpredictable physiological consequences of host metabolic burden. • Expressed a highly active C8-specific thioesterase in PCC 7002 for the first time • Applied a novel method for quantifying acyl-acyl carrier proteins (acyl-ACPs) • Mitigated putative bottlenecks in fatty acid initiation and elongation • Decreased projected costs ∼6-fold by enhancing relative flux to C8-FFA synthesis • Cost improvements were achieved despite reductions in growth and carbon fixation