| Title: | Engineering the oleaginous yeast Yarrowia lipolytica to produce the aroma compound beta-ionone |
| Author(s): | Czajka JJ; Nathenson JA; Benites VT; Baidoo EEK; Cheng Q; Wang Y; Tang YJ; |
| Address: | "Department of Energy, Environmental and Chemical Engineering, Washington University, St. Louis, MO, 63130, USA. Lawrence Berkeley National Laboratory, Berkeley, CA, 94720, USA. Department of Mathematics, Statistics and Computer Science, University of Illinois at Chicago, Chicago, IL, 60607, USA. Monsanto Company, St Louis, MO, 63167, USA. Arch Innotek, LLC, 4320 Forest Park Ave, St. Louis, MO, 63108, USA. ywang@arch-innotek.com. Department of Energy, Environmental and Chemical Engineering, Washington University, St. Louis, MO, 63130, USA. yinjie.tang@wustl.edu" |
| DOI: | 10.1186/s12934-018-0984-x |
| ISSN/ISBN: | 1475-2859 (Electronic) 1475-2859 (Linking) |
| Abstract: | "BACKGROUND: beta-Ionone is a fragrant terpenoid that generates a pleasant floral scent and is used in diverse applications as a cosmetic and flavoring ingredient. A growing consumer desire for natural products has increased the market demand for natural beta-ionone. To date, chemical extraction from plants remains the main approach for commercial natural beta-ionone production. Unfortunately, changing climate and geopolitical issues can cause instability in the beta-ionone supply chain. Microbial fermentation using generally recognized as safe (GRAS) yeast offers an alternative method for producing natural beta-ionone. Yarrowia lipolytica is an attractive host due to its oleaginous nature, established genetic tools, and large intercellular pool size of acetyl-CoA (the terpenoid backbone precursor). RESULTS: A push-pull strategy via genome engineering was applied to a Y. lipolytica PO1f derived strain. Heterologous and native genes in the mevalonate pathway were overexpressed to push production to the terpenoid backbone geranylgeranyl pyrophosphate, while the carB and biofunction carRP genes from Mucor circinelloides were introduced to pull flux towards beta-carotene (i.e., ionone precursor). Medium tests combined with machine learning based data analysis and (13)C metabolite labeling investigated influential nutrients for the beta-carotene strain that achieved > 2.5 g/L beta-carotene in a rich medium. Further introduction of the carotenoid cleavage dioxygenase 1 (CCD1) from Osmanthus fragrans resulted in the beta-ionone production. Utilization of in situ dodecane trapping avoided ionone loss from vaporization (with recovery efficiencies of ~ 76%) during fermentation operations, which resulted in titers of 68 mg/L beta-ionone in shaking flasks and 380 mg/L in a 2 L fermenter. Both beta-carotene medium tests and beta-ionone fermentation outcomes indicated the last enzymatic step CCD1 (rather than acetyl-CoA supply) as the key bottleneck. CONCLUSIONS: We engineered a GRAS Y. lipolytica platform for sustainable and economical production of the natural aroma beta-ionone. Although beta-carotene could be produced at high titers by Y. lipolytica, the synthesis of beta-ionone was relatively poor, possibly due to low CCD1 activity and non-specific CCD1 cleavage of beta-carotene. In addition, both beta-carotene and beta-ionone strains showed decreased performances after successive sub-cultures. For industrial application, beta-ionone fermentation efforts should focus on both CCD enzyme engineering and strain stability improvement" |
| Keywords: | Metabolic Engineering/*methods Norisoprenoids/*metabolism Yarrowia/*metabolism 13C labeling Acetyl-CoA Fed-batch fermentation Machine learning Strain stability Terpenoid beta-carotene; |
| Notes: | "MedlineCzajka, Jeffrey J Nathenson, Justin A Benites, Veronica T Baidoo, Edward E K Cheng, Qianshun Wang, Yechun Tang, Yinjie J eng MCB1616619/Directorate for Biological Sciences/ IIP1722313/Directorate for Engineering/ England 2018/09/03 Microb Cell Fact. 2018 Sep 1; 17(1):136. doi: 10.1186/s12934-018-0984-x" |
