Shen Hong-Jie, Cheng Bi-Yan, Zhang Yan-Mei, Tang Liang, Li Zhen, Bu Yi-Fan, Li Xi-Ran, Tian Gui-Qiao, Liu Jian-Zhong
Biotechnology Research Center and Biomedical Center, South China Sea Bio-Resource Exploitation and Utilization Collaborative Innovation Center, School of Life Sciences, Sun Yat-sen University, Guangzhou 510275, China.
Biotechnology Research Center and Biomedical Center, South China Sea Bio-Resource Exploitation and Utilization Collaborative Innovation Center, School of Life Sciences, Sun Yat-sen University, Guangzhou 510275, China.
Metab Eng. 2016 Nov;38:180-190. doi: 10.1016/j.ymben.2016.07.012. Epub 2016 Jul 26.
Engineered heterologous multi-gene metabolic pathways often suffer from flux imbalance and toxic metabolites, as the production host typically lacks the regulatory mechanisms for the heterologous pathway. Here, we first coordinated the expression of all genes of the mevalonate (MEV) pathway from Saccharomyces cerevisiae using the tunable intergenic regions (TIGRs), and then dynamically regulated the TIGR-mediated MEV pathway to prevent the accumulation of toxic metabolites by using IPP/FPP-responsive promoter. After introduction of the dynamically controlled TIGR-mediated MEV pathway into Escherichia coli, the content and concentration of zeaxanthin in shaker flask cultures were 2.0- and 2.1-fold higher, respectively, than those of the strain harboring the statically controlled non-TIGR-mediated MEV pathway. The content and concentration of zeaxanthin in E. coli ZEAX (pZSP-MevT-MevBIS-2) reached 722.46mg/L and 23.16mg/g dry cell weight (DCW), respectively, in 5.0L fed-batch fermentation. We also comparatively analyzed the proteomes between E. coli ZEAX and E. coli ZEAX (pZSP-MevT-MevBIS-2) to understand the mechanism of zeaxanthin biosynthesis. The results of the comparative proteomes demonstrate that zeaxanthin overproduction may be associated with increased precursor availability, increased NADPH availability, increased ATP availability, oxidative stress response, and increased membrane storage capacity for zeaxanthin due to changes in both cellular shape and membrane composition.
工程化的异源多基因代谢途径常常受到通量失衡和有毒代谢物的困扰,因为生产宿主通常缺乏对异源途径的调控机制。在此,我们首先使用可调基因间区域(TIGRs)协调酿酒酵母甲羟戊酸(MEV)途径所有基因的表达,然后通过使用IPP/FPP响应启动子动态调节TIGR介导的MEV途径,以防止有毒代谢物的积累。将动态控制的TIGR介导的MEV途径引入大肠杆菌后,摇瓶培养物中玉米黄质的含量和浓度分别比含有静态控制的非TIGR介导的MEV途径的菌株高2.0倍和2.1倍。在5.0L补料分批发酵中,大肠杆菌ZEAX(pZSP-MevT-MevBIS-2)中玉米黄质的含量和浓度分别达到722.46mg/L和23.16mg/g干细胞重量(DCW)。我们还比较分析了大肠杆菌ZEAX和大肠杆菌ZEAX(pZSP-MevT-MevBIS-2)之间的蛋白质组,以了解玉米黄质生物合成的机制。比较蛋白质组的结果表明,玉米黄质的过量生产可能与前体可用性增加、NADPH可用性增加、ATP可用性增加、氧化应激反应以及由于细胞形状和膜组成的变化导致的玉米黄质膜储存能力增加有关。
