Fungi are widely distributed in the terrestrial environment, freshwater, and marine habitat. Only approximately 100,000 of these have been classified although there are about 5.1 million characteristic fungi all over the world. These eukaryotic microbes produce specialized metabolites and participate in a variety of ecological functions, such as quorum detection, chemical defense, allelopathy, and maintenance of symbiosis. Fungi therefore remain an important resource for the screening and discovery of biologically active natural products. Sesquiterpenoids are arguably the richest natural products from plants and micro-organisms. The rearrangement of the 15 high-ductility carbons gave rise to a large number of different skeletons. At the same time, abundant structural variations lead to a diversification of biological activity. This review examines the isolation, structural determination, bioactivities, and synthesis of sesquiterpenoids that were specially produced by fungi over the past five years (2015–2020).
Seven
new merosesquiterpenoids, trichothecrotocins D–J (1–7), two new trichothecene sesquiterpenoids,
trichothecrotocins K (12) and L (13), and
six known compounds (8–11, 14, and 15), were isolated from a potato-associated
fungus, Trichothecium crotocinigenum. Compounds 5 and 6 were racemates which were further separated
as pure enantiomers. Structures together with absolute configurations
were established by extensive spectroscopic analysis, as well as quantum
chemistry calculations on ECD and optical rotations. Compounds 1–4 are rare meroterpenoids featuring
a seco-phenyl group, while 1 and 2 possessed a novel 6–6/5 fused ring system. Compounds 1–4, 8, 11,
and 12 showed antifungal activity against four plant
pathogens with MIC values of 8–128 μg/mL. It is suggested
that the meroterpenoids produced by T. crotocinigenum may play an important role in the antifungal property of the fungus,
thereby protecting the host plant, i.e., potato.
Fungi have traditionally been a very rewarding source of biologically active natural products, while diterpenoids from fungi, such as the cyathane-type diterpenoids from Cyathus and Hericium sp., the fusicoccane-type diterpenoids from Fusicoccum and Alternaria sp., the guanacastane-type diterpenoids from Coprinus and Cercospora sp., and the harziene-type diterpenoids from Trichoderma sp., often represent unique carbon skeletons as well as diverse biological functions. The abundances of novel skeletons, biological activities, and biosynthetic pathways present new opportunities for drug discovery, genome mining, and enzymology. In addition, diterpenoids peculiar to fungi also reveal the possibility of differing biological evolution, although they have similar biosynthetic pathways. In this review, we provide an overview about the structures, biological activities, evolution, organic synthesis, and biosynthesis of diterpenoids that have been specially produced by fungi from 2010 to 2020. We hope this review provides timely illumination and beneficial guidance for future research works of scholars who are interested in this area.
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