Metabolic Engineering of Yarrowia lipolytica for Conversion of Waste Cooking Oil into Omega‑3 Eicosapentaenoic Acid

Omega-3 polyunsaturated fatty acids (PUFAs), especially eicosapentaenoic acid (EPA, C20:5), are crucial dietary fats known for their numerous health benefits. However, traditional sources of EPA, like fish oil, raise sustainability and environmental concerns, underscoring the need for alternative pr...

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Published in	ACS Engineering Au Vol. 5; no. 2; pp. 128 - 139
Main Authors	Qin, Jiansong, Liu, Na, Abid, Umer, Coleman, Sarah M., Wang, Yongdan, Fu, Qiang, Yoon, Seongkyu, Alper, Hal S., Xie, Dongming
Format	Journal Article
Language	English
Published	United States American Chemical Society 16.04.2025
Subjects	eicosapentaenoic acid omega-3 fatty acids triglycerides waste cooking oil Yarrowia lipolytica
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Abstract	Omega-3 polyunsaturated fatty acids (PUFAs), especially eicosapentaenoic acid (EPA, C20:5), are crucial dietary fats known for their numerous health benefits. However, traditional sources of EPA, like fish oil, raise sustainability and environmental concerns, underscoring the need for alternative production methods. The engineered oleaginous yeast Yarrowia lipolytica has emerged as a promising candidate for sustainable production of EPA. This study explores the efficient production of EPA with an earlier engineeredY. lipolytica strain Y8412, utilizing waste cooking oil (WCO) as an alternative carbon source. While cofeeding WCO resulted in increased total lipid content, it also caused an increase in intracellular free fatty acid (FFA) levels, which can be toxic to cells and reduce EPA synthesis. To solve this issue, we first overexpressed FAA1 and GPD1 genes converting excess FFAs into triglycerides (TAGs). Additionally, we knocked out TGL3/4 genes, which encode lipases linked to lipid bodies, to minimize the degradation of TAGs back into FFAs. The modified strains significantly reduced intracellular FFA levels and improved EPA production. Notably, the TGL4 knockout strain Y8412T4– showed 57% increase in EPA production titer and nearly 50% increase in carbon conversion yield compared to the parental strain Y8412 fed with glucose only. These findings suggest that preventing TAG degradation by knocking out TGL4 is an effective approach for enhanced EPA production when WCO is used to partially replace glucose as the carbon source. This study offers an effective engineering strategy for low-cost, high-yield, and sustainable production of omega-3 fatty acids from waste feedstocks.
AbstractList	Omega-3 polyunsaturated fatty acids (PUFAs), especially eicosapentaenoic acid (EPA, C20:5), are crucial dietary fats known for their numerous health benefits. However, traditional sources of EPA, like fish oil, raise sustainability and environmental concerns, underscoring the need for alternative production methods. The engineered oleaginous yeast Yarrowia lipolytica has emerged as a promising candidate for sustainable production of EPA. This study explores the efficient production of EPA with an earlier engineeredY. lipolytica strain Y8412, utilizing waste cooking oil (WCO) as an alternative carbon source. While cofeeding WCO resulted in increased total lipid content, it also caused an increase in intracellular free fatty acid (FFA) levels, which can be toxic to cells and reduce EPA synthesis. To solve this issue, we first overexpressed FAA1 and GPD1 genes converting excess FFAs into triglycerides (TAGs). Additionally, we knocked out TGL3/4 genes, which encode lipases linked to lipid bodies, to minimize the degradation of TAGs back into FFAs. The modified strains significantly reduced intracellular FFA levels and improved EPA production. Notably, the TGL4 knockout strain Y8412T4– showed 57% increase in EPA production titer and nearly 50% increase in carbon conversion yield compared to the parental strain Y8412 fed with glucose only. These findings suggest that preventing TAG degradation by knocking out TGL4 is an effective approach for enhanced EPA production when WCO is used to partially replace glucose as the carbon source. This study offers an effective engineering strategy for low-cost, high-yield, and sustainable production of omega-3 fatty acids from waste feedstocks. Omega-3 polyunsaturated fatty acids (PUFAs), especially eicosapentaenoic acid (EPA, C20:5), are crucial dietary fats known for their numerous health benefits. However, traditional sources of EPA, like fish oil, raise sustainability and environmental concerns, underscoring the need for alternative production methods. The engineered oleaginous yeast Yarrowia lipolytica has emerged as a promising candidate for sustainable production of EPA. This study explores the efficient production of EPA with an earlier engineeredY. lipolytica strain Y8412, utilizing waste cooking oil (WCO) as an alternative carbon source. While cofeeding WCO resulted in increased total lipid content, it also caused an increase in intracellular free fatty acid (FFA) levels, which can be toxic to cells and reduce EPA synthesis. To solve this issue, we first overexpressed FAA1 and GPD1 genes converting excess FFAs into triglycerides (TAGs). Additionally, we knocked out TGL3/4 genes, which encode lipases linked to lipid bodies, to minimize the degradation of TAGs back into FFAs. The modified strains significantly reduced intracellular FFA levels and improved EPA production. Notably, the TGL4 knockout strain Y8412T4- showed 57% increase in EPA production titer and nearly 50% increase in carbon conversion yield compared to the parental strain Y8412 fed with glucose only. These findings suggest that preventing TAG degradation by knocking out TGL4 is an effective approach for enhanced EPA production when WCO is used to partially replace glucose as the carbon source. This study offers an effective engineering strategy for low-cost, high-yield, and sustainable production of omega-3 fatty acids from waste feedstocks.Omega-3 polyunsaturated fatty acids (PUFAs), especially eicosapentaenoic acid (EPA, C20:5), are crucial dietary fats known for their numerous health benefits. However, traditional sources of EPA, like fish oil, raise sustainability and environmental concerns, underscoring the need for alternative production methods. The engineered oleaginous yeast Yarrowia lipolytica has emerged as a promising candidate for sustainable production of EPA. This study explores the efficient production of EPA with an earlier engineeredY. lipolytica strain Y8412, utilizing waste cooking oil (WCO) as an alternative carbon source. While cofeeding WCO resulted in increased total lipid content, it also caused an increase in intracellular free fatty acid (FFA) levels, which can be toxic to cells and reduce EPA synthesis. To solve this issue, we first overexpressed FAA1 and GPD1 genes converting excess FFAs into triglycerides (TAGs). Additionally, we knocked out TGL3/4 genes, which encode lipases linked to lipid bodies, to minimize the degradation of TAGs back into FFAs. The modified strains significantly reduced intracellular FFA levels and improved EPA production. Notably, the TGL4 knockout strain Y8412T4- showed 57% increase in EPA production titer and nearly 50% increase in carbon conversion yield compared to the parental strain Y8412 fed with glucose only. These findings suggest that preventing TAG degradation by knocking out TGL4 is an effective approach for enhanced EPA production when WCO is used to partially replace glucose as the carbon source. This study offers an effective engineering strategy for low-cost, high-yield, and sustainable production of omega-3 fatty acids from waste feedstocks. Omega-3 polyunsaturated fatty acids (PUFAs), especially eicosapentaenoic acid (EPA, C20:5), are crucial dietary fats known for their numerous health benefits. However, traditional sources of EPA, like fish oil, raise sustainability and environmental concerns, underscoring the need for alternative production methods. The engineered oleaginous yeast has emerged as a promising candidate for sustainable production of EPA. This study explores the efficient production of EPA with an earlier engineered strain Y8412, utilizing waste cooking oil (WCO) as an alternative carbon source. While cofeeding WCO resulted in increased total lipid content, it also caused an increase in intracellular free fatty acid (FFA) levels, which can be toxic to cells and reduce EPA synthesis. To solve this issue, we first overexpressed and genes converting excess FFAs into triglycerides (TAGs). Additionally, we knocked out / genes, which encode lipases linked to lipid bodies, to minimize the degradation of TAGs back into FFAs. The modified strains significantly reduced intracellular FFA levels and improved EPA production. Notably, the knockout strain Y8412T4 showed 57% increase in EPA production titer and nearly 50% increase in carbon conversion yield compared to the parental strain Y8412 fed with glucose only. These findings suggest that preventing TAG degradation by knocking out is an effective approach for enhanced EPA production when WCO is used to partially replace glucose as the carbon source. This study offers an effective engineering strategy for low-cost, high-yield, and sustainable production of omega-3 fatty acids from waste feedstocks. Omega-3 polyunsaturated fatty acids (PUFAs), especially eicosapentaenoic acid (EPA, C20:5), are crucial dietary fats known for their numerous health benefits. However, traditional sources of EPA, like fish oil, raise sustainability and environmental concerns, underscoring the need for alternative production methods. The engineered oleaginous yeast Yarrowia lipolytica has emerged as a promising candidate for sustainable production of EPA. This study explores the efficient production of EPA with an earlier engineered Y. lipolytica strain Y8412, utilizing waste cooking oil (WCO) as an alternative carbon source. While cofeeding WCO resulted in increased total lipid content, it also caused an increase in intracellular free fatty acid (FFA) levels, which can be toxic to cells and reduce EPA synthesis. To solve this issue, we first overexpressed FAA1 and GPD1 genes converting excess FFAs into triglycerides (TAGs). Additionally, we knocked out TGL3 / 4 genes, which encode lipases linked to lipid bodies, to minimize the degradation of TAGs back into FFAs. The modified strains significantly reduced intracellular FFA levels and improved EPA production. Notably, the TGL4 knockout strain Y8412T4 – showed 57% increase in EPA production titer and nearly 50% increase in carbon conversion yield compared to the parental strain Y8412 fed with glucose only. These findings suggest that preventing TAG degradation by knocking out TGL4 is an effective approach for enhanced EPA production when WCO is used to partially replace glucose as the carbon source. This study offers an effective engineering strategy for low-cost, high-yield, and sustainable production of omega-3 fatty acids from waste feedstocks.
Author	Coleman, Sarah M. Liu, Na Abid, Umer Alper, Hal S. Xie, Dongming Qin, Jiansong Wang, Yongdan Yoon, Seongkyu Fu, Qiang
AuthorAffiliation	Department of Chemical Engineering McKetta Department of Chemical Engineering
AuthorAffiliation_xml	– name: Department of Chemical Engineering – name: McKetta Department of Chemical Engineering
Author_xml	– sequence: 1 givenname: Jiansong surname: Qin fullname: Qin, Jiansong organization: Department of Chemical Engineering – sequence: 2 givenname: Na surname: Liu fullname: Liu, Na organization: Department of Chemical Engineering – sequence: 3 givenname: Umer surname: Abid fullname: Abid, Umer organization: Department of Chemical Engineering – sequence: 4 givenname: Sarah M. orcidid: 0000-0002-0243-9776 surname: Coleman fullname: Coleman, Sarah M. organization: McKetta Department of Chemical Engineering – sequence: 5 givenname: Yongdan surname: Wang fullname: Wang, Yongdan organization: Department of Chemical Engineering – sequence: 6 givenname: Qiang surname: Fu fullname: Fu, Qiang organization: Department of Chemical Engineering – sequence: 7 givenname: Seongkyu surname: Yoon fullname: Yoon, Seongkyu organization: Department of Chemical Engineering – sequence: 8 givenname: Hal S. orcidid: 0000-0002-8246-8605 surname: Alper fullname: Alper, Hal S. email: halper@che.utexas.edu organization: McKetta Department of Chemical Engineering – sequence: 9 givenname: Dongming orcidid: 0000-0003-3881-7975 surname: Xie fullname: Xie, Dongming email: Dongming_Xie@uml.edu organization: Department of Chemical Engineering
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Title	Metabolic Engineering of Yarrowia lipolytica for Conversion of Waste Cooking Oil into Omega‑3 Eicosapentaenoic Acid
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