School of Chemical Engineering and Technology, Tianjin University, Tianjin, People's Republic of China.
Key Laboratory of System Bioengineering, Ministry of Education, Tianjin University, Tianjin, People's Republic of China.
Appl Microbiol Biotechnol. 2019 Apr;103(8):3511-3520. doi: 10.1007/s00253-019-09735-w. Epub 2019 Mar 12.
Sandalwood oil is a valuable resource derived from Santalum album. It has antibacterial, cosmetic, and sedative effects. α-Santalene is the precursor of α-santalol, the main component of sandalwood oil. Yarrowia lipolytica is an oleaginous yeast, which has been metabolically engineered to produce valuable compounds such as terpenoids and biofuel. This study presents a method for the heterologous synthesis of α-santalene by Y. lipolytica. Using Y. lipolytica ATCC 201249, a codon-optimized plant-origin α-santalene synthase (STS) was integrated into the genome, and a yield of 5.19 mg/L α-santalene was obtained after fermentation. Upstream genes in the MVA pathway (ERG8, ERG10, ERG12, ERG13, ERG19, ERG20, HMG1, and tHMG1) were overexpressed, and we found that the key genes ERG8, HMG1, and tHMG1 can increase the supply of FPP and the yield of α-santalene. ERG8 and HMG1 were overexpressed in multiple-copy formats, and the plasmid pERG8HMG1 and ERG8-HMG1 expression modules were optimized as single-copy and multiple-copy formats, respectively. The overexpression of single-copy plasmid pERG8HMG1 led to α-santalene yield of 13.31 mg/L. The optimal feeding strategy was determined by initial carbon source concentration optimizations and five feeding methods. Using 50 g/L glucose as the initial carbon source, maintaining the carbon source concentration at 5-20 g/L during the feeding process is most conducive to increased production. These results were verified in a 5-L fermenter by batch and fed-batch fermentation. The OD of fed-batch fermentation broth reached 79.09, and the production of α-santalene reached 27.92 mg/L; 5.38 times of the initial yield, without by-products farnesol and trans-α-bergamotene.
檀香油是从檀香属植物中提取的一种有价值的资源。它具有抗菌、美容和镇静作用。α-檀香烯是 α-檀香醇的前体,α-檀香醇是檀香油的主要成分。解脂耶氏酵母是一种油脂酵母,已被代谢工程改造以生产萜类化合物和生物燃料等有价值的化合物。本研究提出了一种通过解脂耶氏酵母异源合成 α-檀香烯的方法。利用解脂耶氏酵母 ATCC 201249,将经过密码子优化的植物源 α-檀香烯合酶(STS)整合到基因组中,发酵后获得 5.19mg/L 的 α-檀香烯。过表达甲羟戊酸途径中的上游基因(ERG8、ERG10、ERG12、ERG13、ERG19、ERG20、HMG1 和 tHMG1),我们发现关键基因 ERG8、HMG1 和 tHMG1 可以增加 FPP 的供应和 α-檀香烯的产量。以多拷贝的形式过表达 ERG8 和 HMG1,并分别优化质粒 pERG8HMG1 和 ERG8-HMG1 表达模块为单拷贝和多拷贝形式。单拷贝质粒 pERG8HMG1 的过表达导致 α-檀香烯的产量达到 13.31mg/L。通过初始碳源浓度优化和五种进料方式确定了最佳进料策略。以 50g/L 葡萄糖为初始碳源,在进料过程中保持碳源浓度在 5-20g/L 最有利于提高产量。这些结果在 5L 发酵罐中通过分批和补料分批发酵得到验证。补料分批发酵的发酵液 OD 值达到 79.09,α-檀香烯的产量达到 27.92mg/L;是初始产量的 5.38 倍,没有副产物法呢醇和反式-α-波旁烯。
