[Metabolic engineering study on biosynthesis of 4-hydroxybenzyl alcohol from L-tyrosine in Escherichia coli].

代谢工程 成分 发酵 大肠杆菌 化学 活性成分 生物合成 生物化学 公认安全 生物转化 生物技术 食品科学 生物 基因 药理学
作者
D.M. Xu,Xiao‐Qing Bao,Xiwen Wu,Yu Xing,Chaoyang Tan
出处
期刊:PubMed [National Institutes of Health]
卷期号:47 (4): 906-912 被引量:2
标识
DOI:10.19540/j.cnki.cjcmm.20211107.101
摘要

As an important active ingredient in the rare Chinese herb Gastrodiae Rhizoma and also the main precursor for gastrodin biosynthesis, 4-hydroxybenzyl alcohol has multiple pharmacological activities such as anti-inflammation, anti-tumor, and anti-cerebral ischemia. The pharmaceutical products with 4-hydroxybenzyl alcohol as the main component have been increasingly favored. At present, 4-hydroxybenzyl alcohol is mainly obtained by natural extraction and chemical synthesis, both of which, however, exhibit some shortcomings that limit the long-term application of 4-hydroxybenzyl alcohol. The wild and cultivated Gastrodia elata resources are limited. The chemical synthesis requires many steps, long time, and harsh reaction conditions. Besides, the resulting by-products are massive and three reaction wastes are difficult to treat. Therefore, how to artificially prepare 4-hydroxybenzyl alcohol with high yield and purity has become an urgent problem facing the medical researchers. Guided by the theory of microbial metabolic engineering, this study employed the genetic engineering technologies to introduce three genes ThiH, pchF and pchC into Escherichia coli for synthesizing 4-hydroxybenzyl alcohol with L-tyrosine. And the fermentation conditions of engineering strain for producing 4-hydroxybenzyl alcohol in shake flask were also discussed. The experimental results showed that under the conditions of 0.5 mmol·L~(-1) IPTG, 15 ℃ induction temperature, and 40 ℃ transformation temperature, M9 Y medium containing 200 mg·L~(-1) L-tyrosine could be transformed into(69±5)mg·L~(-1) 4-hydroxybenzyl alcohol, which has laid a foundation for producing 4-hydroxybenzyl alcohol economically and efficiently by further expanding the fermentation scale in the future.
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