Transcription Factors Pmr1 and Pmr2 Cooperatively Regulate Melanin Biosynthesis, Conidia Development and Secondary Metabolism in Pestalotiopsis microspora

Melanins are the common fungal pigment, which contribute to stress resistance and pathogenesis. However, few studies have explored the regulation mechanism of its synthesis in filamentous fungi. In this study, we identified two transcription factors, Pmr1 and Pmr2, in the filamentous fungus Pestalotiopsis microspora. Computational and phylogenetic analyses revealed that Pmr1 and Pmr2 were located in the gene cluster for melanin biosynthesis. The targeted deletion mutant strain Δpmr1 displayed defects in biosynthesis of conidia pigment and morphological integrity. The deletion of pmr2 resulted in reduced conidia pigment, but the mycelial morphology had little change. Moreover, Δpmr2 produced decreased conidia. RT-qPCR data revealed that expression levels of genes in the melanin biosynthesis gene cluster were downregulated from the loss of Pmr1 and Pmr2. Interestingly, the yield of secondary metabolites in the mutant strains Δpmr1 and Δpmr2 increased, comparing with the wild type, and additionally, Pmr1 played a larger regulatory role in secondary metabolism. Taken together, our results revealed the crucial roles of the transcription factors Pmr1 and Pmr2 in melanin synthesis, asexual development and secondary metabolism in the filamentous fungus P. microspora.

Mitochondrial fission dysfunction alleviates heterokaryon incompatibility-triggered cell death in the industrial filamentous fungus Aspergillus oryzae

ABSTRACTIn filamentous fungi, cell-to-cell recognition is a fundamental requirement for the formation, development, and maintenance of complex hyphal networks. Basically, self/compatible individuals within the fungal species are capable of fusing together, a step important for crossbreeding, which results in the formation of viable vegetative heterokaryons. Conversely, the fusion of incompatible individuals does not result in the formation of viable hyphal networks, but it often leads to growth inhibition or cell death. Even though a number of studies have been conducted to investigate such incompatibility, the understanding of the associated molecular mechanism is still limited, and this restricts the possibility of crossbreeding incompatible individuals. Therefore, in this study, the characteristics of compatibility/incompatibility in the industrial filamentous fungus, Aspergillus oryzae, were comprehensively investigated. Protoplast fusion and co-culture assays indicated the existence of a correlation between strain phylogeny and compatibility/incompatibility features. Time-course fluorescence observations were employed to investigate the types of incompatible responses that are induced at different cellular levels upon incompatible cell fusion, which eventually lead to cell death. Propidium iodide-indicated cell death, ROS accumulation, and mitochondrial fragmentation were identified as the major responses, with mitochondrial fragmentation showing the most significant subcellular change immediately after incompatible cell fusion. Furthermore, the deletions of mitochondrial fission-related genes Aofis1 and Aodnm1 in incompatible pairing alleviated cell death, indicating that mitochondrial fission is an important mechanism by which incompatibility-triggered cell death occurs. Therefore, this study provides new insights about heterokaryon incompatibility.IMPORTANCEFor a long time, it was believed that as an asexual fungus, A. oryzae does not exhibit any sexual cycle. However, the fungus has two mating types, indicating the potential for sexual reproduction besides a known parasexual cycle. Therefore, given that viable heterokaryon formation following cell fusion is an important step required for genetic crossing, we explored the mechanism of incompatibility, which restricts the possibility of cell fusion in A. oryzae. Protoplast fusion and co-culture assays led to the identification of various vegetative compatible groups. Mitochondrial fragmentation was found to be the most significant incompatible cellular response that occurred in organelles during incompatible pairing, while the deletion of mitochondrial fission-related genes was identified as a strategy used to alleviate incompatibility-triggered cell death. Thus, this study revealed a novel mechanism by which mitochondrial fission regulates incompatible responses.

Basic interactions of Aspergillus niger with Se(IV)

Filamentous fungus Aspergillus niger is commonly found on decaying vegetation or in indoor environment and has a number of uses, including application in bioremediation. Hence, the basic interactions of this common mould with selenite were studied, including biovolatilization, bioaccumulation and toxicity effects of selenite on fungal growth. The fungal strain, originally isolated from noncontaminated soil, was cultivated under aerobic conditions on liquid cultivation media with concentration of Se(IV) 19 or 27 mg.l-1 during 25 days. The fungal growth in the presence of selenite was not inhibited when compared to control, only the sporulation was reduced. The concentration of Se(IV) in liquid medium decreased rapidly within first ten days to 1 mg.l-1. However, according to results from the 25th day of cultivation, the concentration of total selenium in medium did not change significantly and only negligible amount of selenium (less then 1%) was bioaccumulated. That indicates some biotransformation of selenite into other selenium species. During the cultivation, up to 21% of total amount of selenium was transformed into volatile derivatives (biovolatilization) by filamentous fungus A. niger.

Raman microspectroscopy imaging analysis of extracellular vesicles (EVs) biogenesis by filamentous fungus Penicilium chrysogenum

Mechanism of production of extracellular vesicles (EVs) and their molecular contents are of great interest owing to their diverse roles in biological systems and are far from being completely understood. Even though, cellular cargo release mediated by EVs have been demonstrated in several cases, their role in secondary metabolite production and release remains elusive. In this study we investigate this aspect in detail using Raman micro-spectroscopic imaging. We provide considerable evidence to suggest that the release of antibiotic penicillin by filamentous fungus Penicillium chrysogenuminvolves EVs. Morphological modifications of the fungal body during biogenesis, changes in cell composition at the locus of biogenesis, and major molecular contents of the released EVs are also revealed in this study.

Luteapyrone, a Novel ƴ-Pyrone Isolated from the Filamentous Fungus Metapochonia lutea.

In the process of screening for new bioactive microbial metabolites we found a novel ƴ-pyrone derivative for which we propose the trivial name luteapyrone, in a recently described microscopic filamentous fungus, Metapochonia lutea BiMM-F96/DF4. The compound was isolated from the culture extract of the fungus grown on modified yeast extract sucrose medium by means of flash chromatography followed by preparative HPLC. The chemical structure was elucidated by NMR and LC-MS. The new compound was found to be non-cytotoxic against three mammalian cell lines (HEK 263, KB-3.1 and Caco-2). Similarly, no antimicrobial activity was observed in tested microorganisms (gram positive and negative bacteria, yeast and fungi).

Autophagy deficiency boosts the production of kojic acid in the filamentous fungus Aspergillus oryzae

We found that the expression of genes involved in kojic acid (KA) biosynthesis, kojA, kojR, and kojT, was highly elevated in the Aspergillus oryzae autophagy-deficient mutants. In agreement, KA production was much increased in these mutants. Nuclear translocation of KojR, a transcription factor, was observed in the autophagy mutants before they were starved, explaining why KA production was boosted.