海洋吲哚生物碱的多样性和生物活性。我们知道什么,缺少什么?

IF 10.2 1区 化学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY Natural Product Reports Pub Date : 2023-02-15 DOI:10.1039/D2NP00085G
Darren C. Holland and Anthony R. Carroll
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引用次数: 2

摘要

涵盖:截至2021年底,海洋吲哚生物碱(n=2048)及其报告的生物活性。尽管每年报告的海洋天然产物(MNP)数量不断增加,但大多数只进行了细胞毒性、抗菌和/或抗真菌生物活性的检测,其中大多数在这些检测中被发现是无活性的。在这种情况下,为什么天然产物继续在它们不太可能显示出显著活性的测定中进行检查,哪些靶标可能对扩大其生物相关化学空间的知识更有用?我们对2048种海洋吲哚生物碱(MIAs)的生物活性进行了荟萃分析,这是截至2021年底报道的一个不同的MNP亚类,这突出表明,高达86%的已发表的MIAs的生物活性潜力仍未得到充分探索和/或未确定。尽管大多数已发表的MIAs不是细胞毒性或抗微生物的,但仍有人继续关注使用这些测定来评估新的结构相关类似物。使用化学信息学分析,使用基于片段的指纹对2048个MIA的化学多样性进行聚类,并评估其对特定疾病靶标的生物活性潜力的结构-活性趋势。这些分析表明,有几组MIA具有强大而多样的活性,许多类似物以前只在细胞毒性试验中测试过,可以更好地利用它们来产生与治疗新发疾病的铅相关的结构-活性关系。来自非天然来源的吲哚药物和药物先导结构的集合也被纳入数据集中,提供了互补的生物活性图谱,进一步用于预测潜在新活性的未充分开发区域,并更好地指导MIAs的未来测试。我们的研究结果清楚地表明,MIAs的生物学评估继续在狭窄的生物测定和疾病靶点上进行,将重点转移到无毒疾病靶点应该提供对生物相关化学空间的更多了解,旨在最大限度地发挥MIAs在药物发现中的潜力。
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Marine indole alkaloid diversity and bioactivity. What do we know and what are we missing?†

Covering: marine indole alkaloids (n = 2048) and their reported bioactivities up to the end of 2021

Despite increasing numbers of marine natural products (MNPs) reported each year, most have only been examined for cytotoxic, antibacterial, and/or antifungal biological activities with the majority found to be inactive in these assays. In this context, why are natural products continuing to be examined in assays they are unlikely to show significant activity in, and what targets might be more useful for expanding knowledge of their biologically relevant chemical space? We have undertaken a meta-analysis of the biological activities for 2048 marine indole alkaloids (MIAs), a diverse sub-class of MNPs reported up to the end of 2021, and this has highlighted that the bioactivity potentials for up to 86% of published MIAs remains underexplored and/or undefined. Although most published MIAs are not cytotoxic or antimicrobial, there is a continued focus on using these assays to evaluate new structurally related analogues. Using cheminformatics analyses, the chemical diversity of the 2048 MIAs were clustered using fragment based fingerprints and their reported bioactivity potency towards specific disease targets was assessed for structure activity trends. These analyses showed that there are groups of MIAs that possess potent and diverse activities and that many analogues, previously tested only in cellular toxicity assays, could be better exploited to generate structure activity relationships associated with leads to treat emerging diseases. A collection of indole drug and drug-lead structures from non-natural sources were also incorporated into the dataset providing complementary bioactivity profiles that were further used to predict underexplored areas of potential new activity and to better direct future testing of MIAs. Our findings clearly suggest the biological evaluation of MIAs continues to be conducted on a narrow range of bioassays and disease targets, and that shifting the focus to non-toxic disease targets should provide expanded knowledge of biologically relevant chemical space aimed at maximising the potential of MIAs for drug discovery.

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来源期刊
Natural Product Reports
Natural Product Reports 化学-生化与分子生物学
CiteScore
21.20
自引率
3.40%
发文量
127
审稿时长
1.7 months
期刊介绍: Natural Product Reports (NPR) serves as a pivotal critical review journal propelling advancements in all facets of natural products research, encompassing isolation, structural and stereochemical determination, biosynthesis, biological activity, and synthesis. With a broad scope, NPR extends its influence into the wider bioinorganic, bioorganic, and chemical biology communities. Covering areas such as enzymology, nucleic acids, genetics, chemical ecology, carbohydrates, primary and secondary metabolism, and analytical techniques, the journal provides insightful articles focusing on key developments shaping the field, rather than offering exhaustive overviews of all results. NPR encourages authors to infuse their perspectives on developments, trends, and future directions, fostering a dynamic exchange of ideas within the natural products research community.
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