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内生真菌:抗真菌代谢物的宝库。

Endophytic Fungi: A Treasure Trove of Antifungal Metabolites.

作者信息

Saxena Sanjai, Dufossé Laurent, Deshmukh Sunil K, Chhipa Hemraj, Gupta Manish Kumar

机构信息

Department of Biotechnology, Thapar Institute of Engineering and Technology, Patiala 147004, Punjab, India.

Agpharm Bioinnovations LLP, Incubatee: Science and Technology Entrepreneurs Park (STEP), Thapar Institute of Engineering and Technology, Patiala 147004, Punjab, India.

出版信息

Microorganisms. 2024 Sep 18;12(9):1903. doi: 10.3390/microorganisms12091903.

DOI:10.3390/microorganisms12091903
PMID:39338577
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11433805/
Abstract

Emerging and reemerging fungal infections are very common in nosocomial and non-nosocomial settings in people having poor immunogenic profiles either due to hematopoietic stem cell transplants or are using immunomodulators to treat chronic inflammatory disease or autoimmune disorders, undergoing cancer therapy or suffering from an immune weakening disease like HIV. The refractory behavior of opportunistic fungi has necessitated the discovery of unconventional antifungals. The emergence of black fungus infection during COVID-19 also triggered the antifungal discovery program. Natural products are one of the alternative sources of antifungals. Endophytic fungi reside and co-evolve within their host plants and, therefore, offer a unique bioresource of novel chemical scaffolds with an array of bioactivities. Hence, immense possibilities exist that these unique chemical scaffolds expressed by the endophytic fungi may play a crucial role in overcoming the burgeoning antimicrobial resistance. These chemical scaffolds so expressed by these endophytic fungi comprise an array of chemical classes beginning from cyclic peptides, sesquiterpenoids, phenols, anthraquinones, coumarins, etc. In this study, endophytic fungi reported in the last six years (2018-2023) have been explored to document the antifungal entities they produce. Approximately 244 antifungal metabolites have been documented in this period by different groups of fungi existing as endophytes. Various aspects of these antifungal metabolites, such as antifungal potential and their chemical structures, have been presented. Yet another unique aspect of this review is the exploration of volatile antifungal compounds produced by these endophytic fungi. Further strategies like epigenetic modifications by chemical as well as biological methods and OSMAC to induce the silent gene clusters have also been presented to generate unprecedented bioactive compounds from these endophytic fungi.

摘要

新发和再发真菌感染在医院和非医院环境中非常常见,发生在免疫原性较差的人群中,这些人要么是由于造血干细胞移植,要么是正在使用免疫调节剂治疗慢性炎症性疾病或自身免疫性疾病,正在接受癌症治疗,或者患有像艾滋病这样的免疫功能减弱疾病。机会性真菌的难治性行为使得人们有必要发现非常规抗真菌药物。新冠疫情期间出现的黑真菌感染也引发了抗真菌药物的研发项目。天然产物是抗真菌药物的替代来源之一。内生真菌在其宿主植物内生存并共同进化,因此提供了具有一系列生物活性的新型化学支架的独特生物资源。因此,内生真菌表达的这些独特化学支架极有可能在克服日益增长的抗菌耐药性方面发挥关键作用。这些内生真菌表达的化学支架包括一系列化学类别,从环肽、倍半萜、酚类、蒽醌、香豆素等开始。在本研究中,我们对过去六年(2018 - 2023年)报道的内生真菌进行了探索,以记录它们产生的抗真菌物质。在此期间,不同组别的内生真菌记录了大约244种抗真菌代谢产物。本文介绍了这些抗真菌代谢产物的各个方面,如抗真菌潜力及其化学结构。本综述的另一个独特之处是对这些内生真菌产生的挥发性抗真菌化合物的探索。还介绍了通过化学和生物学方法进行表观遗传修饰以及OSMAC等进一步策略,以诱导沉默基因簇,从而从这些内生真菌中产生前所未有的生物活性化合物。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/00b6/11433805/d760b8e7b7d0/microorganisms-12-01903-g016.jpg
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