Aspergillus Research Articles

Global patterns of species diversity and distribution in the biomedically and biotechnologically important fungal genus Aspergillus.

Aspergillus fungi are key producers of pharmaceuticals, enzymes, and food products and exhibit diverse lifestyles, ranging from saprophytes to opportunistic pathogens. To improve understanding of Aspergillus species diversity, identify key environmental factors influencing their geographic distributions, and estimate the impact of future climate change, we trained a random forest machine learning classifier on 30,542 terrestrial occurrence records for 176 species (~40% of known species in the genus) and 96 environmental variables. We found that regions with high species diversity are concentrated in temperate forests, which suggests that areas with mild seasonal variation may serve as diversity hotspots. Species range estimates revealed extensive variability, both within and across taxonomic sections; while some species are cosmopolitan, others have more restricted ranges. Furthermore, range overlap between species is generally low. The top predictors of mean species richness were the index of cumulative human impact and five bioclimatic factors, such as temperature and temperate vs non-temperate ecoregions. Our future climate analyses revealed considerable variation in species range estimates in response to changing climates; some species ranges are predicted to expand (e.g., the food spoilage and mycotoxin-producing Aspergillus versicolor), and others are predicted to contract or remain stable. Notably, the predicted range of the major pathogen Aspergillus fumigatus was predicted to decrease in response to climate change, whereas the range of the major pathogen Aspergillus flavus was predicted to increase and gradually decrease. Our findings reveal how both natural and human factors influence Aspergillus species ranges and highlight their ecological diversity, including the diversity of their responses to changing climates, which is of relevance to pathogen and mycotoxin risk assessment.

Lactic Acid Bacteria As Biological Control Agent For Controlling Aspergillus Growth and Aflatoxin Production: A Review

: Aspergillus sp., a ubiquitous filamentous fungus, poses significant challenges to the food industry as a common spoilage and mycotoxin producing organism. The conventional use of chemical preservatives to control Aspergillus contamination raises concerns about potential health risks and environmental impacts. Therefore, alternative approaches, such as the utilization of natural biopreservatives, as inexpensive, safe, and promising mycotoxin decontamination strategies are being explored. Lactic acid bacteria have gained considerable attention as potential candidates due to their antimicrobial properties and long-standing safe use in food fermentation. This review provides a thorough summary of the potential of lactic acid bacteria as biopreservatives against Aspergillus sp. The inhibitory mechanisms of lactic acid bacteria against the proliferation of Aspergillus and mycotoxin yield are explored, highlighting the role of organic acids, antimicrobial peptides, and other bioactive compounds. The versatile application of lactic acid bacteria based natural preservatives across a range of food matrices, storage conditions, etc. is also addressed. Further research is warranted to optimize lactic acid bacteria strains, explore synergistic combinations, and investigate their efficacy in real food systems. Implementing lactic acid bacteria based biopreservative strategies could significantly enhance food safety and quality by reducing Aspergillus contamination and mycotoxin risks.

Fumigaclavines K−M, undescribed ergot alkaloids from the mangrove-derived fungus Aspergillus sp. DVXT-221 with cytotoxic and NO inhibitory activities

Fumigaclavines K−M, undescribed ergot alkaloids from the mangrove-derived fungus Aspergillus sp. DVXT-221 with cytotoxic and NO inhibitory activities

Green synthesis and anticancer activity of titanium dioxide nanoparticles using the endophytic fungus Aspergillus sp.

Titanium dioxide nanoparticles (TiO2 NPs) have attracted significant attention for their unique physicochemical features and various applications. This study demonstrated the biosynthesis of TiO2 NPs using Aspergillus fungal extract that served as a green and eco-friendly reducing and stabilizing agent. The biosynthesized nanoparticles were analyzed using SEM and TEM to determine their morphology, size, and distribution, FTIR to determine functional groups, and Zeta potential to assess their surface charge and stability. An extensive review of the Protein Data Bank (PDB) and literature indicated that TiO2 could target various cancer-relevant matrix metalloproteinases. In vitro screening indicated promising anticancer effects against the MCF7 breast cancer cell line. To investigate the possible mode of action of TiO2 NPs as an anticancer agent, human matrix metalloproteinase-3 was highlighted as a protein inhibited by metallic ions like PtCl2. Therefore, we investigated whether TiO2 could similarly interact with the active site of MMP-3. We hypothesized that TiO2 could interact with the MMP-3 active site and replace PtCl2 with modelled TiO2 in its co-crystallized binding site. A 100 ns-long MDS, binding free energy (ΔGBinding) of PtCl2 and TiO2 within MMP-3 binding site indicated that TiO2's enhanced binding affinity and stability, as evidenced by a ΔGBinding of −7.23 kcal/mol and average RMSD of 0.89 Å, compared to PtCl2's lower affinity. In conclusion, endophytic fungi can be used efficiently in the biosynthesis of nanoparticles. Our study indicated TiO2 NPs have a potential anticancer effect, suggesting TiO2 binds to MMP3, potentially offering comparable inhibitory effects on the enzyme's activity.

Assessment of myco-fabricated Al2O3 NPs toxicity on cancer cells and pathogenic microbes by suppression of bacterial metabolic key enzymes

There has been a recent change in global attention towards addressing antimicrobial resistance (AMR) as a result of the concerning increase in mortality rates. Nanomaterials have become highly favorable options for a wide range of industrial and biological uses. The objective of this study was to produce aluminum oxide nanoparticles (Al2O3 NPs) using a crude extract from the fungus Aspergillus sp. WAH23, and then analyze the nanoparticles using UV-analysis, electron microscopy (TEM and SEM), and (FT-IR) and X-ray diffraction (XRD). Results revealed that formed nanoparticles are spherical with an average size of 8.5 nm. XRD analysis confirmed the crystalline nature of the synthesized Al2O3 NPs. The Al2O3 nanoparticles exhibited antibacterial properties against a wide range of pathogenic microbes. The antibacterial efficacy of these nanoparticles on the examined bacterial strains was exhibited through their ability to hinder several metabolic processes, including phosphofructokinase (PFK), enolase, and glutamine synthetase. Additionally, the nanoparticles increased the activity of NADH-oxidase, the content of MDA, and the formation of H2O2. The study also examined the anticancer properties of Al2O3 nanoparticles on various types of cancer cells.

The epidemiological characteristics of invasive pulmonary aspergillosis and risk factors for treatment failure: a retrospective study

ObjectiveThe incidence of invasive pulmonary aspergillosis (IPA) is increasing gradually. This study analysed the epidemiological characteristics and prognostic factors of patients with IPA and explored the risk factors affecting prognosis.Materials and methodsThe clinical data and treatment of 92 patients with IPA were retrospectively analysed, and the patients were followed for 12 weeks. Patients were divided into an effective treatment group and an ineffective treatment group, and the risk factors affecting prognosis were discussed.ResultsA total of 92 patients met the IPA inclusion criteria, and the most common genus of Aspergillus was Aspergillus fumigatus. The incidence of IPA was highest in patients with malignant tumours. IPA often coexisted with infections caused by other pathogens. We divided the patients into an effective treatment group and an ineffective treatment group according to prognosis. Compared with those in the effective treatment group, the procalcitonin (PCT) level, lactate dehydrogenase-to-albumin ratio (LDH/ALB) and neutrophil-to-lymphocyte ratio (NLR) in the ineffective treatment group were greater, the serum albumin level was lower, and the imaging findings revealed less nodules and bronchial wall thickening (P < 0.05). Among these factors, a decrease in the serum albumin concentration, an increase in the PCT level, coinfection and less bronchial wall thickening on imaging were independent risk factors for aspergillosis treatment failure.ConclusionA decreased albumin level, an elevated PCT level, coinfection, and less bronchial wall thickening were independent risk factors for treatment failure in patients with IPA. Attention should be given to the albumin level, coinfection status and imaging findings of patients.

Successful treatment of aspergillosis in a 63-years old female patient with a SIOOT protocol of oxygen-ozone autohemotherapy: A case report

BackgroundInfections caused by the Aspergillus genus are relatively uncommon and typically associated with hospitalization, while only a few cases are linked to environmental exposure to filamentous moulds. These infections can significantly impact pulmonary function, and antifungal therapy may further compromise lung physiology, especially if fungal nodules develop. Consequently, many cases of aspergillosis are not directly treated to avoid additional lung damage. In this case report, we explore a novel approach using ozone therapy to improve clinical outcomes in a patient with pulmonary aspergillosis. To our knowledge, no previous data on the use of this procedure in treating Aspergillus infections have been published in the scientific literature. Case presentationA 63-year-old Caucasian female physician presented with persistent cough, mild fever, mucous sputum, fatigue, and general discomfort. After extensive laboratory analyses, she was initially suspected of having a Mycobacterium tuberculosis infection but was later accurately diagnosed with Aspergillus fumigatus. Allergy tests, thyroid function assessments, total-body PET, and maxillofacial imaging did not yield any findings to suggest alternative diagnoses. Aside from mild neutropenia and a positive antinuclear antibody (ANA) test, which appeared to be laboratory artifacts, the patient showed no significant inflammatory biomarkers, thyroid dysfunction, or signs of allergy. Chest CT revealed Aspergillus nodules with only mild obstructive respiratory impairment, which did not worsen upon administration of salbutamol. Following a period of mild symptoms, her health declined in the summer of 2022, prompting her to pursue ozone therapy at a colleague’s recommendation. After twelve oxygen-ozone treatments, her symptoms—including mild fever, cough, discomfort, and fatigue—fully resolved, and a follow-up chest CT showed a reduction in the presence of Aspergillus. ConclusionOxygen-ozone therapy administered through autohemotherapy proved to be a promising treatment for nodular aspergillosis in the lung, highlighting the need for further exploration of the mechanisms behind this positive outcome. This report is particularly relevant for physicians trained in ozone therapy, as it requires specialized professional expertise. This is the first documented case showing a successful outcome of ozone therapy in treating nodular Aspergillus fumigatus lung infection with mild obstructive pulmonary impairment. The favourable results should encourage physicians to consider this therapeutic approach in the future.

Hydrophobins from Aspergillus mediate fungal interactions with microplastics.

Microplastics pose serious ecological and human health effects by introducing pathogens and toxins into animal and human food chains. Many pathogenic microorganisms preferentially form biofilms on microplastic particles that are then ingested. Here, we demonstrate that hydrophobins, highly hydrophobic, cell surface proteins, enable microplastic binding and colonization by the opportunistic pathogen Aspergillus fumigatus and other fungi within the Aspergillus genus. Our work recognizes a novel role for hydrophobin proteins, identifying potential strategies for pathogen control and protein-based microplastics recovery.

Exploring Aspergillus biomass for fast and effective Direct Black 22-dye removal

Azo dyes are widely used in the textile industry due to their stability and resistance. These properties also make them recalcitrant xenobiotics, toxic, mutagenic, and carcinogenic, even at low concentrations. Considered emerging pollutants, there is an urgency to address mechanisms capable of remediating these contaminants, with Aspergillus fungi standing out as an effective solution. Fifteen strains of Aspergillus were investigated for the decolorization of the tetra azo dye Direct Black 22. The influence of different culture media was evaluated on fungi biomass production, dye concentrations (50–300 mg/L), biomass concentrations (1–5g), and the reuse of biomass in continuous batches. The strains that stood out the most were Aspergillus japonicus URM 5620, Aspergillus niger URM 5741, and A. niger URM 5838. Obtaining biomass in less nutrient-rich medium favored decolorization by forming more organized pellets. The live biomass of these fungi was 59% more efficient than the dead biomass. The decolorization efficiency was not affected at lower dye concentrations, showing a decrease in decolorization only when the concentration reached 300 mg/L. Increasing the amount of biomass resulted in proportionally greater decolorization. Even with just 1 g of biomass, the three fungi could remove more than 90% of the dye in less than 60 minutes, and with 5 g, the dye was completely removed in 10 minutes. Thebiomass was reused in three consecutive decolorization cycles, and the fungus that best withstood the cycles was A. niger URM 5741. These results demonstrate the potential of the genus Aspergillus fungi tested in this study as sustainable and efficient biosorbents for the remediation of azo dyes such as Direct Black 22, with potential for colored industrial effluent treatment.

Diversity of Fungi that Play a Role in Decomposing Rhizophora mucronata Leaf Litter in the Lower Deli River

Abstract Fungi are microorganisms that function as decomposers of R. mucronata leaf litter since they can produce enzymes that can break down cellulose and lignin, which are the main components of leaf and stem cell walls. The study’s goal was to evaluate the decomposition rate of R. mucronata leaves, carbohydrate and protein content, and the kind of fungi that were discovered in the leaf litter. The research procedures included site selection based on salinity levels, collection leaf litter of R. mucronata in the field, data gathering every 15 days, laboratory equipment sterilization used, making PDA media for culturing fungi, and isolation of fungi, identification of fungi. Levels of protein and carbohydrates in degraded R. mucronata litter were analyzed. This study was conducted between August 2023 and January 2024. The following categories of fungi are involved in the rate at which R. mucronata litter decomposes: Penicillium sp, Aspergillus sp, Aspergillus flavus, Aspergillus niger, Trichoderma sp. The diversity index value of fungi that play a role in the decomposition rate of R. mucronata litter is 1.32. R. mucronata litter decomposes at a rate of 9.09 grams/year. The average protein composition of R. mucronata litter is 6.046%, while the average carbohydrate content is 9.412%.

Studies on Secondary Metabolites and Biological Activities of Fungus Aspergillus sp. PQJ-1 from Sphagneticola trilobata

Studies on Secondary Metabolites and Biological Activities of Fungus Aspergillus sp. PQJ-1 from Sphagneticola trilobata

New diketopiperazine dimers and 4-hydroxyphenylacetates from an endolichenic fungus Aspergillus sp.

Two novel diketopiperazine dimers (1 and 2) and two new 4-hydroxyphenylacetates (5 and 6), along with two previously known diketopiperazine dimers were isolated from the culture of the endolichenic fungus Aspergillus sp. CPCC 400810. Their structures were determined through comprehensive spectroscopic analysis, including high-resolution electrospray ionization mass spectrometry (HRESIMS) and 1D and 2D nuclear magnetic resonance (NMR) data. The absolute configurations of the new compounds were confirmed using Marfey's method and chemical synthesis.

A PCR-Based Approach for Early Diagnosis of Head and Neck Aspergillosis: A Pilot Study.

Aspergillosis is a fungal disease caused by the inhalation of fungal spores of the genus Aspergillus spp. This fungus mainly affects the lungs but can spread and infect the maxillofacial region through the bloodstream or inoculation of the fungus after extraction or endodontic treatment, especially in the upper posterior teeth. The disease has nonspecific clinical manifestations that hinder its early diagnosis. Although the Polymerase Chain Reaction (PCR) technique holds promise as a diagnostic tool for aspergillosis, anatomopathological analysis services do not routinely adopt this method. Therefore, the present study aimed to evaluate the applicability of PCR and standardise the techniques of preparation of biological samples for the detection of the three species: Aspergillus niger, Aspergillus fumigatus and Aspergillus flavus. Methods: Six samples of formalin-fixed, paraffin-embedded tissue (FFPE) with a histopathological diagnosis suggestive of aspergillosis were investigated using PCR. As a positive control for the PCR reaction, morphologically and genetically characterized cultures were used, with their sequences deposited at NCBI under accession codes MW837777 (A. fumigatus) and MW837779 (A. niger). The A. flavus culture used is reference RC 2053. Four of the six samples evaluated were positive for Aspergillus spp., of which one was co-infected with A. fumigatus and A. flavus species, while two others were positive only for A. flavus, and one sample was positive only for A. fumigatus. These findings suggest that PCR can be used as an auxiliary method for diagnosing aspergillosis. However, this was a pilot study, and expansion of the sample size and the evaluation of PCR in comparison with other diagnostic tests for aspergillosis are essential to determine the accuracy of the method.

First Report of Leaf Spot on Lonicera japonica Caused by Aspergillus niger in China.

Honeysuckle (Lonicera japonica Thunb, LJ) is a common medicinal and edible plant (He et al. 2022). It has been utilized in various industries such as biomedicine, animal husbandry, and food production (Li et al. 2014; Su et al. 2020). In June 2023, a significant leaf lesion was observed on approximately 20% of honeysuckle "Juhua No.1" leaves in a 3.33-ha field at the base of Julu County, Hebei province, China. Almost all leaves were infected. Leaf spot disease occurred in the field honeysuckle throughout the flowering period, especially after picking. The disease mainly infected the leaves of honeysuckle, forming irregular spots on the edge of the leaf surface with black-brown edges, the midrib and lateral veins were affected (Figure S1A). In advanced stages, the entire leaf would become necrotic. For pathogen isolation, small pieces (4×4 mm) of the infected tissue from diseased leaves were surface sterilized with 75% ethanol and 5% sodium hypochlorite, rinsed with the sterile water, incubated on PDA. Finally, six isolated pathogens were obtained. Hyphae were white. The mycelium was multicellular, had diaphragm. Conidiophores protruded from the stroma, started as spherical structures and gradually developed into radial, black-brown formations. Spore acrosome was subglobose, bilayered pedicels covering acrosome, 40-60 µm in diameter, yellowish brown (Figures S1B, S1C). Based on morphological and cultural characteristics, the leaf spot disease fungus was tentatively identified as Aspergillus spp. (Wei 1979). To test the pathogenicity of pathogen, leaves of three healthy potted honeysuckle "Juhua No.1" plants were inoculated by sprayed with conidial suspensions (106 spores/ml) (Figure S1D). Negative controls were established by inoculating leaf with sterile distilled water. All plants were incubated in a greenhouse at 28 ± 2℃. The experiment was replicated three times. After 10 days, typical leaf spot symptoms were observed on inoculated leaves, whereas no symptoms were found on the control groups. The re-isolated fungus from the inoculated leaves displayed the same morphological traits (Figures S1E-S1H), again identified as Aspergillus spp., confirming Koch's postulates, designated as H2. To confirm the pathogen's identity, genomic DNA was extracted from the pathogenicity isolate H2. The 18S rDNA and the ITS genes were amplified and sequenced using primer pairs S1/S2 (Zhang et al. 2018) and ITS1/ITS4 (Zhang et al. 2023), respectively. Results of BLAST searches showed that the 18s rDNA and ITS sequences of H2 were highly homologous (>99%) with Aspergillus niger. The close genetic relationship indicated that H2 belonged to the genus Aspergillus (Figure S2a). We further sequenced the whole genome of H2. The sequence data were available in the NCBI GenBank (Accession number: PRJNA1117256). We also analyzed the ANI (Yoon et al. 2017) and digital DNA-DNA blotting (dDDH) (Figures S2b, S2c). The ANI values of H2 compared to Aspergillus niger CBS 554.65 and Aspergillus niger KJC3 were higher than 95%. The dDDH values of H2 compared to Aspergillus niger CBS 554.65 and Aspergillus niger KJC3 were higher than 70%. Above all results, honeysuckle leaf spot disease was identified as Aspergillus niger. This is the first report of leaf spot on Lonicera japonica caused by Aspergillus niger in China. Our findings expand the geographical range of A.niger-infected plants, also provide reference for scientific prevention and control of honeysuckle leaf spot disease.

Poultry farms as a One health priority for Aspergillus section Fumigati surveillance

Abstract In poultry production environments, particulate matter (PM) is considered one of the harmful air pollutants [2]. Considering potential biological pathogens, the genus Aspergillus in particular, Aspergillus fumigatus, is a widely recognized human and animal pathogen [3]. Hot-humid farm environments could contribute to the proliferation of these fungi [4]. Therefore, poultry production workers, besides animals [4], may be at a higher risk of inhaling fungi spores [4,5]. This study aimed to determine particulate matter (PM) contamination and analyze the prevalence of Aspergillus section Fumigati in air samples from poultry pavilions. Indoor and outdoor air samples were taken in the 1st, 2nd and 3rd weeks of birds growth cycle (n = 58). Air was collected through the impaction method (MAS-100) onto polycarbonate filters, set at 100 L/min, for 5 min. Followed by DNA extraction, and real-time PCR detection of Aspergillus section Fumigati. For PM evaluation, portable direct-reading equipment (Lighthouse, model 3016 IAQ) was used. Particle concentrations were measured (n = 67) at five distinct fractions during 5 min. Considering particles fractions, PM10 and PM5 where prevalent in 1st (58% PM10; 28% PM5), 2nd (63% PM10; 26% PM5) and 3rd (64% PM10; 25% PM5) weeks. These results evidence that coarse particles (between 2.5 and 10 µm) are the most relevant PM present in this setting. Regarding fungal detection, Aspergillus section Fumigati was widespread inside poultry pavilions (62%, 26 out of 42), highlighting this environment has a potential reservoir of microbial pathogens [7]. Furthermore, PM can act as a host of biological fragments [6]. Overall, in addition to molecular analysis, future studies should consider using culture-based methods to assess the viability of pathogenic microorganisms and their infection potential [3]. From a One Health perspective, quantitative and qualitative research is required to fully understand this environment. Key messages • This study evidence that coarse particles (between 2.5 and 10 µm) are the most relevant PM present and Aspergillus section Fumigati is widespread in poultry pavilions. • A One health intervention should be considered in future studies.

A preliminary study on the degradation of AFB1 by Tenebrio molitor, Rhizopus oryzae and Trichoderma reesei

Abstract Recently, genus Aspergillus, a fungus capable of producing aflatoxins, secondary highly toxic metabolites, has spread to new areas. These areas became suitable habitats due to the recent climate changes. The use of aflatoxin-contaminated crops is a cause of great concern in guaranteeing food safety and is responsible for major economic losses along the supply chain. For this reason, several strategies have been investigated to utilize these contaminated products as a possible food or feed resource by reducing or eliminating their aflatoxin content, but with limited relevant success. The presented study was aimed to evaluate a combination of biological processes to use aflatoxin B1 contaminated crops for their reintroduction into the production chain. The high tolerance to AFB1 and the apparent lack of accumulation in yellow mealworm larvae, reared on wheat bran substrates, spiked with increasing AFB1 concentration (0, 125, 250, 500 μg/kg) to obtain proteins of high biological value. Subsequently, the aflatoxin-degrading capacity of Rhizopus oryzae and Trichoderma reesei was applied to insect breeding waste (frass) in a fermentation process to ensure further utilization of biohazardous frass as soil conditioner. Individually, each process proven to be able to reduce the AFB1 present by about 80%, while the combination of the two approaches ensured the total degradation of aflatoxin B1-contaminated substrate and frass, which resulted in the possible production of biomass, that could be used for the feed and agricultural industry.

Genomic Localization Bias of Secondary Metabolite Gene Clusters and Association with Histone Modifications in Aspergillus.

Fungi are well-known producers of bioactive secondary metabolites (SMs), which have been exploited for decades by humankind for various medical applications like therapeutics and antibiotics. SMs are synthesized by biosynthetic gene clusters (BGCs)-physically co-localized and co-regulated genes. Because BGCs are often regulated by histone post-translational modifications (PTMs), it was suggested that their chromosomal location is important for their expression. Studies in a few fungal species indicated an enrichment of BGCs in sub-telomeric regions; however, there is no evidence that BGCs with distinct genomic localization are regulated by different histone PTMs. Here, we used 174 Aspergillus species covering 22 sections to determine the correlation between BGC genomic localization, gene expression, and histone PTMs. We found a high abundance and diversity of SM backbone genes across the Aspergillus genus, with notable unique genes within sections. Being unique or conserved in many species, BGCs showed a strong bias for being localized in low-synteny regions, regardless of their position in chromosomes. Using chromosome-level assemblies, we also confirmed a significantly biased localization in sub-telomeric regions. Notably, SM backbone genes in sub-telomeric regions and about half of those in low-synteny regions exhibit higher gene expression variability, likely due to the similar higher variability in H3K4me3 and H3K36me3 histone PTMs; while variations in histone H3 acetylation and H3K9me3 are not correlated to genomic localization and expression variation, as analyzed in two Aspergillus species. Expression variability across four Aspergillus species further supports that BGCs tend to be located in low-synteny regions and that regulation of expression in those regions likely involves different histone PTMs than the most commonly studied modifications.

Xerophilic Aspergillaceae Dominate the Communities of Culturable Fungi in the Mound Nests of the Western Thatching Ant (Formica obscuripes).

The nests of mound-building ants are unexplored reservoirs of fungal diversity. A previous assessment of this diversity in the nests of Formica ulkei suggested that water availability may be a determinant of the composition of this mycota. To investigate this question, we recovered 3594 isolates of filamentous Ascomycota from the nests of Formica obscuripes and adjacent, non-nest sites, employing Dichloran Rose Bengal agar (DRBA), Dichloran Rose Bengal agar containing glycerol (DRBAG), and malt extract agar containing sucrose (MEA20S). Higher numbers of fungi were isolated from the tops of mounds than from within mounds and non-mound sites. Mound nest soils were dominated by members of the family Aspergillaceae, and up to 50% of the colonies isolated on DRBAG belonged to the genus Aspergillus. Pseudogymnoascus pannorum and species of Talaromyces were also present in higher numbers in mound soils. Species of Penicillium were more abundant in non-nest soils, where they accounted for over 66% of isolates on DRBA. All Aspergillaceae assessed for xerotolerance on a medium augmented with glycerol or sucrose were xerophilic. These results, and our observation that the nests of F. obscuripes are low-water environments, indicate that water availability influences the structure of the fungal communities in these animal-modified habitats.

Isoechinulin B, a natural product from Antarctic fungus, attenuates acute liver injury by inhibiting excessive cell adhesion

Abnormal cell adhesion between leukocytes and endothelial cells is closely associated with the development of numerous inflammation-related diseases, with adhesion molecules playing a crucial role. The disruption of cell adhesion directly or indirectly inhibits excessive cell adhesion and thus produces a therapeutic effect. However, there are only a few clinically available antagonists of cell adhesion. One of the biggest challenges is the development of novel and efficient cell adhesion inhibitors. Recently, the anti-inflammatory pharmacological activity of natural products of microbial origin has also received increasing attention. Here, we obtained a potential cell adhesion inhibitor isoechinulin B, an indole diketopiperazine derivative, from the Antarctic fungus Aspergillus sp. CPCC 401072, which is active against cell adhesion. Isoechinulin B decreased the expression of vascular endothelial adhesion molecule 1 (VCAM-1) and intercellular adhesion molecule 1 (ICAM-1) by inhibiting the activation of the NF-κB signaling pathway, thereby inhibiting cell adhesion between leukocytes and endothelial cells to reduce macrophage infiltration in the liver and significantly attenuate lipopolysaccharide-induced acute liver injury in mice. ConclusionIsoechinulin B is a novel cell adhesion inhibitor derived from fungi found in extreme environments.

Assessment of the microbial contamination in "Do It Yourself" (DIY) stores - a holistic approach to protect workers' and consumers' health.

In "Do-It-Yourself" (DIY) stores, workers from the wood department are considered woodworkers. Given the health risks associated with woodworking, particularly from fungi and their metabolites, this study aims to assess microbial contamination and health risks for both workers and customers. The study was developed in 13 DIY stores in Lisbon Metropolitan Area, Portugal. It employed a comprehensive sampling approach combining active (MAS-100, Andersen six-stage, Coriolis μ, and SKC Button Aerosol Sampler) and passive (electrostatic dust collectors, surface swabs, e-cloths, settled dust, filters from vacuumed dust, filtering respiratory protection devices, and mechanical protection gloves) methods to assess microbial contamination. A Lighthouse Handheld Particle Counter HH3016- IAQ was used to monitor the particulate matter size, temperature, and humidity. The wood exhibition area presented the highest fungal load, while the payment area exhibited the highest bacterial load. MAS-100 detected the highest fungal load, and surface swabs had the highest bacterial load. Penicillium sp. was the most frequently observed fungal species, followed by Aspergillus sp. Mycotoxins, namely mycophenolic acid, griseofulvin, and aflatoxin G1, were detected in settled dust samples and one filter from the vacuum cleaner from the wood exhibition area. Cytotoxicity evaluation indicates the wood-cutting area has the highest cytotoxic potential. Correlation analysis highlights relationships between fungal contamination and particle size and biodiversity differences among sampling methods. The comprehensive approach applied, integrating numerous sampling methods and laboratory assays, facilitated a thorough holistic analysis of this specific environment, enabling Occupational and Public Health Services to prioritize interventions for accurate exposure assessment and detailed risk management.