AUTHOR=Yamaguchi Shigenari , Fujioka Tomonori , Yoshimi Akira , Kumagai Toshitaka , Umemura Maiko , Abe Keietsu , Machida Masayuki , Kawai Kiyoshi 

TITLE=Discovery of a gene cluster for the biosynthesis of novel cyclic peptide compound, KK-1, in Curvularia clavata

JOURNAL=Frontiers in Fungal Biology

VOLUME=3

YEAR=2023

URL=https://www.frontiersin.org/journals/fungal-biology/articles/10.3389/ffunb.2022.1081179

DOI=10.3389/ffunb.2022.1081179

ISSN=2673-6128

ABSTRACT=<p>KK-1, a cyclic depsipeptide with 10 residues produced by a filamentous fungus <italic>Curvularia clavata</italic> BAUA-2787, is a promising pesticide active compound with high activity against many plant pathogens, especially <italic>Botrytis cinerea</italic>. As a first step toward the future mass production of KK-1 through synthetic biological approaches, we aimed to identify the genes responsible for the KK-1 biosynthesis. To achieve this, we conducted whole genome sequencing and transcriptome analysis of <italic>C. clavata</italic> BAUA-2787 to predict the KK-1 biosynthetic gene cluster. We then generated the overexpression and deletion mutants for each cluster gene using our originally developed transformation system for this fungus, and analyzed the KK-1 production and the cluster gene expression levels to confirm their involvement in KK-1 biosynthesis. As a result of these, a region of approximately 71 kb was found, containing 10 open reading frames, which were co-induced during KK-1 production, as a biosynthetic gene cluster. These include <italic>kk1B</italic>, which encodes nonribosomal peptide synthetase with a domain structure that is consistent with the structural features of KK-1, and <italic>kk1F</italic>, which encodes a transcription factor. The overexpression of <italic>kk1F</italic> increased the expression of the entire cluster genes and, consequently, improved KK-1 production, whereas its deletion decreased the expression of the entire cluster genes and almost eliminated KK-1 production, demonstrating that the protein encoded by <italic>kk1F</italic> regulates the expressions of the other nine cluster genes cooperatively as the pathway-specific transcription factor. Furthermore, the deletion of each cluster gene caused a reduction in KK-1 productivity, indicating that each gene is involved in KK-1 production. The genes <italic>kk1A</italic>, <italic>kk1D</italic>, <italic>kk1H</italic>, and <italic>kk1I</italic>, which showed a significant decrease in KK-1 productivity due to deletion, were presumed to be directly involved in KK-1 structure formation, including the biosynthesis of the constituent residues. <italic>kk1C</italic>, <italic>kk1E</italic>, <italic>kk1G</italic>, and <italic>kk1J</italic>, which maintained a certain level of KK-1 productivity despite deletion, were possibly involved in promoting or assisting KK-1 production, such as extracellular transportation and the removal of aberrant units incorporated into the peptide chain.</p>