Disrupted short chain specific ß-oxidation and improved synthase expression increase synthesis of short chain fatty acids in Saccharomyces cerevisiae.

Biologically derived fatty acids have gained tremendous interest as an alternative to petroleum-derived fuels and chemical precursors. We previously demonstrated the synthesis of short chain fatty acids in Saccharomyces cerevisiae by introduction of the Homo sapiens fatty acid synthase (hFAS) with heterologous phosphopantetheine transferases and heterologous thioesterases. In this study, short chain fatty acid production was improved by combining a variety of novel enzyme and metabolic engineering strategies. The use of a H. sapiens-derived thioesterase and phosphopantetheine transferase were evaluated. In addition, strains were engineered to disrupt either the full ß-oxidation (by deleting FAA2, PXA1, and POX1) or short chain-specific ß-oxidation (by deleting FAA2, ANT1, and PEX11) pathways. Prohibiting full ß-oxidation increased hexanoic and octanoic acid levels by 8- and 79-fold relative to the parent strain expressing hFAS. However, by targeting only short chain ß-oxidation, hexanoic and octanoic acid levels increased further to 31- and 140-fold over the parent. In addition, an optimized hFAS gene increased hexanoic, octanoic, decanoic and total short chain fatty acid levels by 2.9-, 2.0-, 2.3-, and 2.2-fold, respectively, relative to the non-optimized counterpart. By combining these unique enzyme and metabolic engineering strategies, octanoic acid was increased more than 181-fold over the parent strain expressing hFAS.

Overproduction and secretion of free fatty acids through disrupted neutral lipid recycle in Saccharomyces cerevisiae.

The production of fuels and chemicals from biorenewable resources is important to alleviate the environmental concerns, costs, and foreign dependency associated with the use of petroleum feedstock. Fatty acids are attractive biomolecules due to the flexibility of their iterative biosynthetic pathway, high energy content, and suitability for conversion into other secondary chemicals. Free fatty acids (FFAs) that can be secreted from the cell are particularly appealing due to their lower harvest costs and straightforward conversion into a broad range of biofuel and biochemical products. Saccharomyces cerevisiae was engineered to overproduce extracellular FFAs by targeting three native intracellular processes. ß-oxidation was disrupted by gene knockouts in FAA2, PXA1 and POX1, increasing intracellular fatty acids levels up to 55%. Disruptions in the acyl-CoA synthetase genes FAA1, FAA4 and FAT1 allowed the extracellular detection of free fatty acids up to 490mg/L. Combining these two disrupted pathways, a sextuple mutant (Δfaa1 Δfaa4 Δfat1 Δfaa2 Δpxa1 Δpox1) was able to produce 1.3g/L extracellular free fatty acids. Further diversion of carbon flux into neutral lipid droplet formation was investigated by the overexpression of DGA1 or ARE1 and by the co-overexpression of a compatible lipase, TGL1, TGL3 or TGL5. The sextuple mutant overexpressing the diacylglycerol acyltransferase, DGA1, and the triacylglycerol lipase, TGL3, yielded 2.2g/L extracellular free fatty acids. This novel combination of pathway interventions led to 4.2-fold higher extracellular free fatty acid levels than previously reported for S. cerevisiae.