Institute of Bioengineering, College of Chemical and Biological Engineering, Zhejiang University, Hangzhou 310027, PR China.
Institute of Bioengineering, College of Chemical and Biological Engineering, Zhejiang University, Hangzhou 310027, PR China; Key Laboratory of Biomass Chemical Engineering of Ministry of Education, Zhejiang University, Hangzhou 310027, PR China.
Metab Eng. 2017 Jan;39:257-266. doi: 10.1016/j.ymben.2016.12.011. Epub 2016 Dec 27.
Current studies on microbial isoprene biosynthesis have mostly focused on regulation of the upstream mevalonic acid (MVA) or methyl-erythritol-4-phosphate (MEP) pathway. However, the downstream bottleneck restricting isoprene biosynthesis capacity caused by the weak expression and low activity of plant isoprene synthase (ISPS) under microbial fermentation conditions remains to be alleviated. Here, based on a previously constructed Saccharomyces cerevisiae strain with enhanced precursor supply, we strengthened the downstream pathway through increasing both the expression and activity of ISPS to further improve isoprene production. Firstly, a two-level expression enhancement system was developed for the P-controlled ISPS by overexpression of GAL 4. Meanwhile, the native GAL1/7/10 promoters were deleted to avoid competition for the transcriptional activator Gal4p, and GAL80 was disrupted to eliminate the dependency of gene expression on galactose induction. The IspS expression was obviously elevated upon enhanced Gal4p supply, and the isoprene production was improved from 6.0mg/L to 23.6mg/L in sealed-vial cultures with sucrose as carbon source. Subsequently, a novel high-throughput screening method was developed based on precursor toxicity and used for ISPS directed evolution towards enhanced catalytic activity. Combinatorial mutagenesis of the resulting ISPS mutants generated the best mutant ISPSM4, introduction of which into the GAL4-overexpressing strain YXM29 achieved 50.2mg/L of isoprene in sealed vials, and the isoprene production reached 640mg/L and 3.7g/L in aerobic batch and fed-batch fermentations, respectively. These results demonstrated the effectiveness of the proposed combinatorial engineering strategy in isoprene biosynthesis, which might also be feasible and instructive for biotechnological production of other valuable chemicals.
目前,微生物异戊二烯生物合成的研究主要集中在上游甲羟戊酸(MVA)或甲基赤藓醇-4-磷酸(MEP)途径的调控上。然而,在微生物发酵条件下,由于植物异戊烯合酶(ISPS)表达较弱和活性较低,导致下游成为限制异戊二烯生物合成能力的瓶颈,这一问题仍有待缓解。在这里,我们基于之前构建的增强前体供应的酿酒酵母菌株,通过增加 ISPS 的表达和活性来增强下游途径,以进一步提高异戊二烯的产量。首先,通过过表达 GAL4 构建了一个用于 P 控制的 ISPS 的两级表达增强系统。同时,删除了天然的 GAL1/7/10 启动子,以避免与转录激活因子 Gal4p 竞争,并且敲除了 GAL80 以消除基因表达对半乳糖诱导的依赖。增强 Gal4p 供应后,IspS 的表达明显升高,以蔗糖为碳源的密封瓶培养中,异戊二烯产量从 6.0mg/L 提高到 23.6mg/L。随后,我们开发了一种基于前体毒性的新型高通量筛选方法,并用于 ISPS 定向进化以提高催化活性。对所得 ISPS 突变体进行组合诱变,产生了最佳突变体 ISPSM4,将其引入 GAL4 过表达菌株 YXM29 中,在密封瓶中实现了 50.2mg/L 的异戊二烯,在好氧分批和分批补料发酵中,异戊二烯产量分别达到 640mg/L 和 3.7g/L。这些结果表明,所提出的组合工程策略在异戊二烯生物合成中是有效的,这对于其他有价值化学品的生物技术生产也可能是可行和有指导意义的。
