植物中作为黄酮生物合成逆过程的结肠降解:异同。

Katrin Sak
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引用次数: 0

摘要

背景:多年来,人们一直认为结肠的主要功能是重吸收水分和盐分以及排出未使用的食物材料。直到最近,人们才发现人体肠道微生物群在不同食物成分(包括植物性黄酮类化合物)的新陈代谢中发挥着至关重要的作用。目前,有关摄入的类黄酮在结肠中的降解、参与降解的细菌和产生的代谢产物的知识正在迅速增加。一般来说,在小肠中未被吸收的类黄酮会进入结肠,在结肠中暴露于肠道微生物群:在这篇文章中,黄酮类化合物在结肠中的降解被认为是其在植物中生物合成的一个逆过程,并特别关注黄酮亚类。根据这种方法:在植物中合成的东西将在人体结肠中分解。研究强调了几种反向相似性,包括黄酮苷的水解是肠道降解的第一步,而植物中黄酮生物合成的最后一个反应是糖分子的附着;结肠还原与植物在中心杂环中引入 C2-C3 双键形成对比;或微生物环裂变与植物黄酮杂环的闭环形成对比。尽管存在这些反向相似性,但植物中黄酮类化合物途径的前体与人类肠道微生物代谢产物的范围不同。在人体结肠中,由于肠道微生物群具有多种酶解能力,从摄入的类黄酮中产生了多种酚酸。这些代谢产物的生物活性和对健康的潜在影响在很大程度上仍然未知。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Colonic Degradation as Reverse Process to Flavone Biosynthesis in Plants: Similarities and Differences.

Background: For many years, it was thought that the main function of the colon is the reabsorption of water and salt and the elimination of unused food materials. Only very recently, a crucial role of the human intestinal microbiota in the metabolism of different food constituents, including plant foods-derived flavonoids, was discovered. Currently, the knowledge about colonic degradation of ingested flavonoids, involved bacteria and produced catabolites is rapidly increasing. In general, flavonoids unabsorbed in the small intestine reach the colon, where they are exposed to the gut microbiota.

Key findings and conclusion: In this perspective article, colonic degradation of flavonoids is considered a reverse process to their biosynthesis in plants, with a special focus on the subclass of flavones. According to this approach: what is composed in plants, will be decomposed in the human colon. Several inverse similarities are highlighted, including hydrolysis of flavonoid glycosides as the first step in the gut degradation contrasted with the attachment of sugar moiety as the last reaction of flavonoid biosynthesis in plants, colonic reduction contrasted with plant introduction of C2-C3 double bond in the central heterocyclic ring, or microbial ring fission contrasted with plant ring closure of the heterocyclic ring of flavones. Despite these inverse similarities, precursors of flavonoid pathway in plants are different from the spectrum of gut microbial catabolites in humans. In the human colon, a wide variety of phenolic acids are produced from the ingested flavonoids, due to the diverse enzymatic capacity of intestinal microbiota. The bioactivities and potential health impacts of these catabolites are still largely unknown.

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