Revisiting the fermentation of Sceletium tortuosum

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS

ACS Applied Bio Materials Pub Date : 2024-10-30 DOI:10.1016/j.sajb.2024.10.044

Elizaveta Koroleva , Herman Redelinghuys , Cleo G. Conacher , Corné van Deventer , Jody R Harvey , Alfred Botha , Marina Rautenbach , Marietjie A. Stander

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Abstract

Sceletium tortuosum, a medicinal plant used as natural antidepressant, has been fermented traditionally to yield what is believed by its users to be a stronger more potent product. The question persists if fermenting is changing the actives (mesembrine alkaloids) in the plant material or if it is just a natural way of concentrating it and increasing its bioavailability. In this study the plant material was macerated and incubated over a period of 9 days with regular sampling to monitor any chemical and metagenomic changes over time. Ultra-high pressure liquid chromatography-mass spectrometry (UHPLC-MS) analysis showed that the first significant changes in the chemical composition occurred after 5 days when Fusarium species became the predominant species in the microflora. To confirm whether fusaroid taxa do play a role in the alkaloid production and/or changes in the alkaloid profile, the sterilized plant biomass was inoculated with three Fusarium species as monocultures and the fermentation monitored. The alkaloid profile in the control did not change over time, but similarly to the natural fermentation, one of the Fusarium species yielded an increase in epimesembranol and decreases in some of the other alkaloids which indicates that the microbiome indeed plays a role.

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重新审视 Sceletium tortuosum 的发酵过程

Sceletium tortuosum 是一种用作天然抗抑郁剂的药用植物，传统上经过发酵后，使用者认为其药效更强。但问题是，发酵是否会改变植物材料中的活性物质（间氨基生物碱），或者发酵是否只是浓缩活性物质并提高其生物利用率的一种自然方法。在这项研究中，对植物材料进行了为期 9 天的浸渍和培养，并定期取样，以监测随着时间推移发生的任何化学和元基因组变化。超高压液相色谱-质谱（UHPLC-MS）分析表明，5 天后化学成分首次发生显著变化，镰刀菌成为微生物区系中的主要物种。为了确认镰刀菌类群是否在生物碱的生产和/或生物碱成分的变化中发挥作用，在灭菌植物生物质中接种了三种镰刀菌单株，并对发酵过程进行了监测。对照组中的生物碱含量没有随时间发生变化，但与自然发酵类似，其中一种镰刀菌产生的表烷醇有所增加，而其他一些生物碱则有所减少，这表明微生物群确实在其中发挥了作用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

ACS Applied Bio Materials Chemistry-Chemistry (all)

CiteScore

9.40

自引率

2.10%

发文量

464