Laboratory of Food Enzyme Engineering, Institute of Food Science and Technology, Chinese Academy of Agricultural Sciences, Beijing, 100193, People's Republic of China.
Laboratory of Biocatalysis and Synthetic Biotechnology, State Key Laboratory of Bioreactor Engineering, East China University of Science and Technology, 130 Meilong Road, Shanghai, 200237, China.
Appl Microbiol Biotechnol. 2020 May;104(9):3897-3907. doi: 10.1007/s00253-020-10433-1. Epub 2020 Mar 4.
Vanillin is a popular flavoring compound and an important food additive. Owing to the consumer preference for inexpensive natural aroma flavors, vanillin production through a biotechnological pathway has become of great interest and commercial value in recent years. In this study, an enzymatic synthetic system for vanillin using a coenzyme-independent decarboxylase (FDC) and oxygenase (CSO2) cascade was reconstituted and optimized. This system produces a slightly higher production yield (40.20%) than the largest yield reported for immobilized FDC and CSO2 (35.00%) with ferulic acid as a substrate. It was previously reported that the low catalytic activity and thermal instability of CSO2 restrict the overall productivity of vanillin. In present study, site-directed mutagenesis was applied to rate-limiting oxygenase CSO2 to generate positive mutants. The production yields of mutants A49P (58.44%) and Q390A (65.29%) were 1.45- and 1.62-fold that of CSO2 wild type, respectively. The potential mechanism for enhanced vanillin production using A49P involved increased thermostability and catalytic efficiency, while that using Q390A was probably associated with a better thermostable performance and increased catalytic efficiency resulting from a larger entrance channel.
香草醛是一种常用的调味化合物和重要的食品添加剂。由于消费者偏爱廉价的天然香气,近年来,通过生物技术途径生产香草醛引起了极大的兴趣和商业价值。在这项研究中,重新构建并优化了使用辅酶非依赖性脱羧酶(FDC)和加氧酶(CSO2)级联的香草醛酶促合成系统。与以阿魏酸为底物的固定化 FDC 和 CSO2 的最大产量(35.00%)相比,该系统产生了略高的产量(40.20%)。先前的研究表明,CSO2 的低催化活性和热不稳定性限制了香草醛的整体产率。在本研究中,对限速加氧酶 CSO2 进行了定点突变,以产生阳性突变体。突变体 A49P(58.44%)和 Q390A(65.29%)的产率分别比 CSO2 野生型提高了 1.45 倍和 1.62 倍。使用 A49P 提高香草醛产量的潜在机制涉及增加热稳定性和催化效率,而使用 Q390A 可能与更好的热稳定性性能和增加的催化效率有关,这是由于更大的入口通道所致。
