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Pullulan, which is a microbial exopolysaccharide, has found widespread applications in foods, biomedicines, and cosmetics. Despite its versatility, most wild-type strains tend to yield low levels of pullulan production, and their mutants present genetic instability, achieving a limited increase in pullulan production. Therefore, mining new wild strains with robust pullulan-producing abilities remains an urgent concern. In this study, we found a novel strain, namely, Aureobasidium melanogenum ZH27, that had a remarkable pullulan-producing capacity and optimized its cultivation conditions using the one-factor-at-a-time method. To elucidate the reasons that drove the hyper-production of pullulan, we scrutinized changes in cell morphology and gene expressions. The results reveal that strain ZH27 achieved 115.4 ± 1.82 g/L pullulan with a productivity of 0.87 g/L/h during batch fermentation within 132 h under the optimized condition (OC). This pullulan titer increased by 105% compared with the initial condition (IC). Intriguingly, under the OC, swollen cells featuring 1–2 large vacuoles predominated during a rapid pullulan accumulation, while these swollen cells with one large vacuole and several smaller ones were prevalent under the IC. Moreover, the expressions of genes associated with pullulan accumulation and by-product synthesis were almost all upregulated. These findings suggest that swollen cells and large vacuoles may play pivotal roles in the high level of pullulan production, and the accumulation of by-products also potentially contributes to pullulan synthesis. This study provides a novel and promising candidate for industrial pullulan production.

Marine fungi represent an important and sustainable resource, from which the search for novel biological substances for application in the pharmacy or food industry offers great potential. In our research, novel polysaccharide (AUM-1) was obtained from marine Aureobasidium melanogenum SCAU-266 were obtained and the molecular weight of AUM-1 was determined to be 8000 Da with 97.30% of glucose, 1.9% of mannose, and 0.08% galactose, owing to a potential backbone of α-D-Glcp-(1→2)-α-D-Manp-(1→4)-α-D-Glcp-(1→6)-(SO3−)-4-α-D-Glcp-(1→6)-1-β-D-Glcp-1→2)-α-D-Glcp-(1→6)-β-D-Glcp-1→6)-α-D-Glcp-1→4)-α-D-Glcp-6→1)-[α-D-Glcp-4]26→1)-α-D-Glcp and two side chains that consisted of α-D-Glcp-1 and α-D-Glcp-(1→6)-α-D-Glcp residues. The immunomodulatory effect of AUM-1 was identified. Then, the potential molecular mechanism by which AUM-1 may be connected to ferroptosis was indicated by metabonomics, and the expression of COX2, SLC7A11, GPX4, ACSL4, FTH1, and ROS were further verified. Thus, we first speculated that AUM-1 has a potential effect on the ferroptosis-related immunomodulatory property in RAW 264.7 cells by adjusting the expression of GPX4, regulated glutathione (oxidative), directly causing lipid peroxidation owing to the higher ROS level through the glutamate metabolism and TCA cycle. Thus, the ferroptosis related immunomodulatory effect of AUM-1 was obtained.

Aureobasidium melanogenum is a black yeast-like fungus that occurs frequently both in nature and in domestic environments. It is becoming increasingly important as an opportunistic pathogen. Nevertheless, its effect on human cells has not yet been studied. In this study, we investigated the effect of A. melanogenum cells and extracellular vesicles (EVs) on human cell lines A549 (human lung cells), HDFa (human dermal fibroblasts), and SH-SY5Y (human neuroblastoma cells). Scanning electron microscopy (SEM) showed no direct interaction between A. melanogenum cells and human cell lines, but there were some changes in HDFa cells. As a possible cause for this change, we tested the cytotoxic effect of EVs from A. melanogenum on the same cell lines. We isolated EVs from the fungus and prepared three different pools: a non-melanin pool (containing mainly EVs), a melanin pool (containing mainly melanin nanoparticles), and a total pool (containing both EVs and melanin nanoparticles). All three pools were characterized and then added to human cell lines to test their cytotoxicity. Unlike in some other fungal opportunistic pathogens, no effects of fungal EVs on human cell viability were observed. Therefore, the opportunistic potential of A. melanogenum remains only partially understood.

Natural melanin is a biopolymer with wide application prospects in medicine, food, cosmetics, environmental protection, agriculture, and so on. Microbial fermentation is an important and effective way to produce melanin. In this study, Aureobasidium melanogenum , known as black yeast with cellular pleomorphism, was used for the production of melanin. Based on the characteristic of A. melanogenum secreting melanin under oligotrophic stress, a simple medium containing only glucose, MgSO 4 ·7H 2 O, and KCl was constructed for the production of melanin. The melanin titer of 6.64 ± 0.22 g/L was obtained after 20 days of fermentation without pH control. The cell morphological changes of A. melanogenum during the production of melanin were recorded, and the results showed that chlamydospore might be the most favorable cell morphology for melanin synthesis. Then, different fermentation strategies with cell morphology analysis were developed to further improve the production of melanin in a 5-L fermenter. Results showed that the maximum titer of melanin reached 18.50 g/L by using the fermentation strategy integrating pH control, ammonium salt addition, and H 2 O 2 stimulation, which increased by 178.6% than that of the strategy without pH control. Furthermore, the melanin obtained from the fermentation broth was characterized as eumelanin containing an indole structure. This study provided a potentially feasible fermentation strategy for the industrial production of melanin.

Summary Currently, piperazic acid is chemically synthesized using ecologically unfriendly processes. Microbial synthesis from glucose is an attractive alternative to chemical synthesis. In this study, we report the production of L‐piperazic acid via microbial fermentation with the first engineered fungal strain of Aureobasidium melanogenum; this strain was constructed by chassis development, genetic element reconstitution and optimization, synthetic rewiring and constitutive genetic circuit reconstitution, to build a robust L‐piperazic acid synthetic cascade. These genetic modifications enable A. melanogenum to directly convert glucose to L‐piperazic acid without relying on the use of either chemically synthesized precursors or harsh conditions. This bio‐based process overcomes the shortcomings of the conventional synthesis routes. The ultimately engineered strain is a very high‐efficient cell factory that can excrete 1.12 ± 0.05 g l‐1 of L‐piperazic acid after a 120‐h 10.0‐l fed‐batch fermentation; this is the highest titre of L‐piperazic acid reported using a microbial cell factory. L‐piperazic acid via microbial fermentation with the first engineered fungal strain of Aureobasidium melanogenum was achieved. This strain was constructed by chassis development, genetic element reconstitution and optimization, synthetic rewiring, and constitutive genetic circuit reconstitution to build a robust L‐piperazic acid synthetic cascade. The ultimately engineered strain has the highest titer of L‐piperazic acid of 1.12 ± 0.05 g l‐1 ever reported.

The melanin produced by Aureobasidium melanogenum XJ5-1 obtained from the Taklimakan Desert can play an important role in adaptation of the yeast strain to various stress treatments. It is very important to know how the desert-derived yeast sense, respond and adapt to the harsh environments. However, it is still unclear how melanin is genetically controlled by signaling pathways and transcriptional factors. In this study, it was found that the mitogen-activated protein kinase (MAPK) Slt2 in the cell wall integrity (CWI) signal pathway could regulate activity of the transcriptional activator Swi4; in turn, the Swi4 could control the expression of the CMR1 gene. The melanin-specific transcriptional activator Cmr1 encoded by the CMR1 gene was specifically bound to the promoter with the sequence TTCTCTCCA of the PKS1 gene and strongly stimulated expression of the PKS1 gene and any other genes responsible for melanin biosynthesis, so that a large amount of melanin could be produced by A. melanogenum XJ5-1. Therefore, melanin biosynthesis in the desert-derived A. melanogenum XJ5-1 was controlled mainly by the CWI signal pathway among the cell wall-related signal pathways via a transcriptional activator Cmr and regulation of the melanin biosynthesis in A. melanogenum XJ5-1 was completely different from that of the melanin biosynthesis in any other fungi. This is the first time to show that melanin biosynthesis in the desert-derived A. melanogenum XJ5-1 is controlled mainly by the CWI signal pathway via a transcriptional activator Cmr1. This would provide the fundamentals for further research on the desert-derived yeast to sense, respond and adapt to the harsh environments.

This review explores the production of the fungal polysaccharide pullulan by mutants and natural isolates of Aureobasidium species using strain improvement. Pullulan is a neutral polysaccharide gum whose structure is a maltotriose-containing glucan. This polysaccharide gum has applications in the fields of food, pharmaceuticals, biomedical and wastewater treatment. The strain improvement of Aureobasidium species has focused on the pullulan production process, including the isolation of strains exhibiting reduced pigmentation, polysaccharide overproduction, the production of pullulan with variable molecular weight, and increased osmotolerant strains promoting pullulan production at high carbon source concentrations and pullulan production on hemicellulosic substrates. The majority of studies have emphasized the isolation of reduced pigmentation and pullulan hyperproducer strains since the goal of large-scale commercial pullulan production is to synthesize non-pigmented polysaccharides. A promising area of strain improvement is the isolation of strains that synthesize authentic pullulan from hemicellulosic substrates. If strain improvement in this area is successful, the goal of commercially producing pullulan at a competitive cost will eventually be achieved.

Aureobasidium melanogenum P16 is a high pullulan-producing yeast. However, glucose repression on its pullulan biosynthesis must be relieved. After the gene encoding a glucose repressor was cloned, characterized and analyzed, it was found that the repressor belonged to one member of the CreA in filamentous fungi, not to one member of the Mig1 in yeasts. After the CREA gene was fully removed from the yeast strain P16, the glucose repression in the disruptant DG41 was relieved. At the same time, the pullulan production by the disruptant DG41 was enhanced compared to that by its wild-type strain P16, and the transcriptional levels of the gene encoding a glucosyltransferase, three genes encoding glucose transporters, the gene encoding a 6-P-glucose kinase and the genes encoding α-amylase, glucoamylase and pullulanase in the disruptant DG41 were also promoted. However, the transcriptional levels of the genes encoding the CreA and another two glucose transporters were greatly reduced. During the 10-liter fermentation, the disruptant DG41 produced 64.93 ± 1.33 g/l pullulan from 120 g/l of glucose, while its wild-type strain P16 produced only 52.0 ± 1.95 g/l pullulan within 132 h. After the CREA gene was complemented in the disruptant D373, the pullulan production by the transformant BC4 was greatly reduced compared to that by its wild-type strain P16, and the transcriptional levels of the many genes in the transformant BC4 were also decreased. All the results confirmed that the CreA played an important role in the regulation of pullulan biosynthesis in A. melanogenum P16, and that glucose derepression on pullulan biosynthesis could improve pullulan production from glucose. This study opened the possibility for improving the industrial production of this exopolysaccharide by genetic engineering.

The abundant presence of xylan in low-cost lignocellulosic biomasses establishes its monomeric sugar, xylose, as a pivotal substrate for sustainable bioconversion processes. Although significant advances have been devoted to rewiring the metabolic pathways for xylose assimilation, the effort on regulatory dimensions remains scare. Aureobasidium spp., yeast-forming fungi known for their broad xylanolytic activities and high-yield production of value-added metabolites, represent promising microbial cell factories. However, the regulatory mechanism of xylan degradation and pentose catabolism in these yeasts has not been elucidated. In this study, we identified AmXlnR as the key transcriptional regulator governing xylan degradation and pentose catabolism (d-xylose and l-arabinose) in Aureobasidium melanogenum. Integrated transcriptomic, biochemical, and genetic analyses demonstrate that AmXlnR functions as an activator of xylanase and β-xylosidase genes, while functions as a repressor of α-l-arabinofuranosidase genes, through recognition of specific promoter motifs. Furthermore, AmXlnR positively influences pullulan biosynthesis from pentoses by significantly upregulating the pentose catabolic pathway. Notably, overexpression of AmXLNR alone enhanced pullulan production from xylose, achieving a titer of 56.75 ± 1.51 g/L, which is comparable to the yield obtained with glucose as the carbon source. These findings establish AmXlnR as a key regulator of xylanolytic gene expression in A. melanogenum and provide a new strategic approach to improve bioconversion of lignocellulosic biomass-derived pentose for high-value product synthesis. [Display omitted]

The black yeast-like fungus Aureobasidium melanogenum is an opportunistic human pathogen frequently found indoors. Its traits, potentially linked to pathogenesis, have never been systematically studied. Here, we examine 49 A. melanogenum strains for growth at 37 °C, siderophore production, hemolytic activity, and assimilation of hydrocarbons and human neurotransmitters and report within-species variability. All but one strain grew at 37 °C. All strains produced siderophores and showed some hemolytic activity. The largest differences between strains were observed in the assimilation of hydrocarbons and human neurotransmitters. We show for the first time that fungi from the order Dothideales can assimilate aromatic hydrocarbons. To explain the background, we sequenced the genomes of all 49 strains and identified genes putatively involved in siderophore production and hemolysis. Genomic analysis revealed a fairly structured population of A.melanogenum, raising the possibility that some phylogenetic lineages have higher virulence potential than others. Population genomics indicated that the species is strictly clonal, although more than half of the genomes were diploid. The existence of relatively heterozygous diploids in an otherwise clonal species is described for only the second time in fungi. The genomic and phenotypic data from this study should help to resolve the non-trivial taxonomy of the genus Aureobasidium and reduce the medical hazards of exploiting the biotechnological potential of other, non-pathogenic species of this genus.