Reaping the Chemical Diversity of Morinagamyces vermicularis Using Feature-Based Molecular Networking

IF 3.3 2区生物学 Q2 CHEMISTRY, MEDICINAL

Journal of Natural Products Pub Date : 2024-09-15 DOI:10.1021/acs.jnatprod.4c0065410.1021/acs.jnatprod.4c00654

Karen Harms, Esteban Charria-Girón, Alberto Miguel Stchigel, Yasmina Marin-Felix* and Frank Surup*,

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Abstract

Moringadepsin (6) and chaetone B (7) were isolated by us in the course of a conventional chemical screening of Morinagamyces vermicularis CBS 303.81, a fungus belonging to the relatively underexplored family Schizotheciaceae of the phylum Ascomycota. Since these metabolites did not account for the antifungal activity observed in a crude extract of this fungus, we utilized an MS/MS-based molecular networking approach to get a thorough insight into the secondary metabolites produced by this strain. Manual annotation of high-resolution fragmentation mass spectra by CANOPUS classified a major molecular family as putatively new thiodiketopiperazines. However, these results were opposite to the results of ChemWalker analysis based solely on MS/MS data, assigning these metabolites as various polyketides. Thus, targeted preparative HPLC isolation focusing on the most abundant features within this major molecular family resulted in the isolation of five secondary metabolites. Their structures were elucidated based on HRMS and NMR data as four new thiodiketopiperazine derivatives, botryosulfuranols D–G (1–4), alongside the known botryosulfuranol A (5). Compounds 1–3 and 5 exhibited moderate to weak antifungal activity against different test strains, accounting for the initial antifungal activity observed for its crude extract. Our study stressed the importance of full NMR-based structure elucidation for metabolomics research.

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利用基于特征的分子网络收获莫里纳加米氏菌（Marinagamyces vermicularis）的化学多样性

Morinagamyces vermicularis CBS 303.81 属于子囊菌门五味子科（Schizotheciaceae），是一种未被充分开发的真菌，我们在对其进行常规化学筛选的过程中分离出了 Moringadepsin (6) 和 chaetone B (7)。由于这些代谢物不能解释在该真菌的粗提取物中观察到的抗真菌活性，我们采用了基于 MS/MS 的分子网络方法来深入了解该菌株产生的次级代谢物。通过 CANOPUS 对高分辨率碎片质谱的手动注释，我们将一个主要的分子家族归类为可能的新型硫代酮哌嗪类化合物。然而，这些结果与仅基于 MS/MS 数据的 ChemWalker 分析结果相反，后者将这些代谢物归类为各种多酮类化合物。因此，针对这一主要分子家族中最丰富的特征进行有针对性的制备型高效液相色谱分离，最终分离出五种次级代谢物。根据 HRMS 和 NMR 数据，它们的结构被阐明为四种新的硫代二酮哌嗪衍生物，即植物硫醇 D-G（1-4），以及已知的植物硫醇 A（5）。化合物 1-3 和 5 对不同的试验菌株表现出中等到较弱的抗真菌活性，这也是其粗提取物具有初步抗真菌活性的原因。我们的研究强调了基于核磁共振的全面结构阐明对于代谢组学研究的重要性。

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

Journal of Natural Products 生物-药学

CiteScore

9.10

自引率

5.90%

发文量

294

审稿时长

2.3 months

期刊介绍： The Journal of Natural Products invites and publishes papers that make substantial and scholarly contributions to the area of natural products research. Contributions may relate to the chemistry and/or biochemistry of naturally occurring compounds or the biology of living systems from which they are obtained. Specifically, there may be articles that describe secondary metabolites of microorganisms, including antibiotics and mycotoxins; physiologically active compounds from terrestrial and marine plants and animals; biochemical studies, including biosynthesis and microbiological transformations; fermentation and plant tissue culture; the isolation, structure elucidation, and chemical synthesis of novel compounds from nature; and the pharmacology of compounds of natural origin. When new compounds are reported, manuscripts describing their biological activity are much preferred. Specifically, there may be articles that describe secondary metabolites of microorganisms, including antibiotics and mycotoxins; physiologically active compounds from terrestrial and marine plants and animals; biochemical studies, including biosynthesis and microbiological transformations; fermentation and plant tissue culture; the isolation, structure elucidation, and chemical synthesis of novel compounds from nature; and the pharmacology of compounds of natural origin.