Scytalol B

The gray mold fungus Botrytis cinerea produces dark-colored conidia and sclerotia due to deposition of melanin on the cell wall of these structures. However, the role of melanin biosynthesis on development and function of conidia and sclerotia have not been well elucidated in this fungus. This study disrupted the melanin biosynthesis gene Bcscd1 (for scytalone dehydratase) in the wild type B05.10, and the resulting mutants were compared with B05.10 and complementary mutants (COM) for growth and development, virulence and response to biotic/abiotic stresses. Three disruption mutants were obtained, and they did not differ from B05.10 and COM in mycelial growth rate on potato dextrose agar, however, they formed brownish conidia and scleotia deficient in melanogenesis, whereas B05.10 and COM formed grayish conidia and black sclerotia with normal melanogenesis. The disruption mutants were as aggressive as B05.10 and COM in infection of tobacco leaves. TEM observation showed that the disruption mutant ΔScd1-85 formed numerous tiny grooves in the conidial cell wall, thereby causing uneven thickness in the cell wall. In contrast, B05.10 and COM rarely formed tiny grooves in their conidial cell wall with even thickness. Moreover, the sclerotial cortex cell wall of ΔScd1-85 lost rigidity and the cells became collapsed, whereas the sclerotial cortex cell wall of B05.10 and COM appeared rigid, and the cells appeared plump in shape. The disruption mutants were more sensitive than B05.10 and COM in response to chemical stresses (H2O2, NaCl, SDS, sorbitol) for conidial germination and sclerotial survival. The sclerotia of the disruption mutants were more susceptible than the sclerotia of B05.10 and COM to infection by the mycoparasite Trichoderma koningiopsis. These results confirmed previous studies about the effect of melanin production on pathogenicity of B. cinerea, and expanded our knowledge about the role of Bcscd1 in cell wall integrity and in response to biotic and abiotic stresses.

Background: The fungal pathogen Botrytis cinerea infects a broad range of horticultural plants worldwide, resulting in significant economic losses. A derivative of chitosan, oligochitosan, has been reported to be an eco-friendly alternative to synthetic fungicides. Results: Oligochitosan can greatly inhibit B. cinerea spore germination and induce protein carbonylation. To further investigate the molecular mechanism underlying the inhibitory effect, a comparative proteome analysis was conducted of oligochitosan-treated versus non-treated B. cinerea spores. The cellular proteins were obtained from B. cinerea spore samples and subjected to two-dimensional gel electrophoresis. In total, 21 differentially expressed proteins (DEPs) were identified. Three DEPs were up-regulated in the oligochitosan-treated versus the untreated spores, including scytalone dehydratase and a serine carboxypeptidase III precursor. By contrast, seven DEPs, including Hsp 88 and cell division cycle protein 48, were down-regulated by oligochitosan treatment. Notably, 10 DEPs, including phosphatidylserine decarboxylase proenzyme and ATP-dependent molecular chaperone HSC82, were only detected in the control spores, whereas one DEP, a non-annotated predicted protein, was only detected in the oligochitosan-treated spores. Conclusion: Oligochitosan may affect the spore germination of B. cinerea by impairing protein function. These findings have practical implications with respect to the use of oligochitosan for controlling fungal pathogens. © 2018 Society of Chemical Industry.

In filamentous fungi, 1,8-dihydroxynaphthalene (DHN) melanin is a major component of the extracellular matrix, endowing fungi with environmental tolerance and some pathogenic species with pathogenicity. However, the subcellular location of the melanin biosynthesis pathway components remains obscure. Using the gray mold pathogen Botrytis cinerea, the DHN melanin intermediate scytalone was characterized via phenotypic and chemical analysis of mutants, and the key enzymes participating in melanin synthesis were fused with fluorescent proteins to observe their subcellular localizations. The Δbcscd1 mutant accumulated scytalone in the culture filtrate rather than in mycelium. Excessive scytalone appears to be self-inhibitory to the fungus, leading to repressed sclerotial germination and sporulation in the Δbcscd1 mutant. The BcBRN1/2 enzymes responsible for synthesizing scytalone were localized in endosomes and found to be trafficked to the cell surface, accompanied by the accumulation of BcSCD1 proteins in the cell wall. In contrast, the early-stage melanin synthesis enzymes BcPKS12/13 and BcYGH1 were localized in peroxisomes. Taken together, the results of this study revealed the subcellular distribution of melanin biosynthetic enzymes in B. cinerea, indicating that the encapsulation and externalization of the melanin synthetic enzymes need to be delicately orchestrated to ensure enzymatic efficiency and protect itself from the adverse effect of the toxic intermediate metabolite.IMPORTANCE The devastating gray mold pathogen Botrytis cinerea propagates via melanized conidia and sclerotia. This study reveals that the sclerotial germination of B. cinerea is differentially affected by different enzymes in the melanin synthesis pathway. Using gene knockout mutants and chemical analysis, we found that excessive accumulation of the melanin intermediate scytalone is inhibitory to B. cinerea. Subcellular localization analysis of the melanin synthesis enzymes of B. cinerea suggested two-stage partitioning of the melanogenesis pathway: the intracellular stage involves the steps until the intermediate scytalone was translocated to the cell surface, whereas the extracellular stage comprises all the steps occurring in the wall from scytalone to final melanin formation. These strategies make the fungus avert self-poisoning during melanin production. This study opens avenues for better understanding the mechanisms of secondary metabolite production in filamentous fungi.