proteomics – Page 4

Identification of Challenging Dermatophyte Species Using Matrix-Assisted Laser Desorption/Ionization Time-of-Flight Mass Spectrometry

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This study shows that MALDI-TOF mass spectrometry is an effective method for quickly identifying skin fungal infections caused by dermatophytes. By combining commercial reference databases with a custom library created from local isolates, researchers achieved 90.7% accurate identification compared to only 16.1% using the commercial database alone. This improved method could help doctors diagnose and treat fungal skin infections more quickly and accurately in clinical laboratories.

Aspergillus fumigatus dsRNA virus promotes fungal fitness and pathogenicity in the mammalian host

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A virus that infects the fungus Aspergillus fumigatus (which causes serious lung infections in humans) actually makes the fungus more dangerous by improving its ability to survive stress and spread disease. Scientists found that removing this virus from the fungus made infections less severe in mice. They also discovered that antiviral drugs like ribavirin could potentially be used to weaken these virus-infected fungi and improve patient survival.

Functions of the Three Common Fungal Extracellular Membrane (CFEM) Domain-Containing Genes of Arthrobotrys flagrans in the Process of Nematode Trapping

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Researchers studied three genes (CFEM1-3) in a fungus called Arthrobotrys flagrans that traps and kills parasitic worms. By deleting or increasing these genes, scientists found they control how the fungus makes sticky trap networks and how thick the trap walls are. This knowledge could help develop natural pest control products to protect plants and animals from harmful parasitic nematodes.

Breaking down biofilms across critical priority fungal pathogens: proteomics and computational innovation for mechanistic insights and new target discovery

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This comprehensive review examines how scientists are fighting dangerous fungal infections that form protective biofilms resistant to current antifungal drugs. Researchers are using advanced protein analysis techniques (proteomics) and artificial intelligence-based computational tools to identify new targets for drug development against four critical fungal pathogens that cause life-threatening infections like meningitis and lung infections. By combining these technologies, scientists can better understand how these fungal biofilms form and develop more effective treatments.

Functions of the Three Common Fungal Extracellular Membrane (CFEM) Domain-Containing Genes of Arthrobotrys flagrans in the Process of Nematode Trapping

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Researchers studied a special fungus called Arthrobotrys flagrans that traps and kills parasitic worms. They focused on three genes (AfCFEM1-3) that produce proteins important for making the sticky traps. When they removed two of these genes, the fungus became better at killing worms, while removing the third gene made it worse. The study shows these genes are crucial for the fungus to create effective sticky traps and could help develop better natural pest control products.

Saprotrophic Arachnopeziza Species as New Resources to Study the Obligate Biotrophic Lifestyle of Powdery Mildew Fungi

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Scientists have discovered that two types of fungi called Arachnopeziza species are the closest living relatives to powdery mildew fungi, which cause plant diseases. Unlike powdery mildews, these Arachnopeziza fungi can be easily grown in the lab and genetically modified. By studying these more manageable fungi, researchers can better understand how powdery mildew fungi became obligate parasites that must live on plants, potentially leading to better ways to control this widespread plant disease.

iTRAQ-Based Quantitative Proteomic Analysis Reveals Proteomic Changes in Mycelium of Pleurotus ostreatus in Response to Heat Stress and Subsequent Recovery

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This study examined how oyster mushrooms respond to high temperatures using advanced protein analysis techniques. Researchers found that when mushroom mycelium was exposed to 40°C heat, it damaged cell membranes and changed the levels of hundreds of proteins. However, when the temperature returned to normal, the mushrooms could repair the damage and recover. Key proteins including heat shock proteins and stress-response enzymes played important roles in protecting the mushroom cells and helping them survive heat stress.

Discovery of the antifungal compound ilicicolin K through genetic activation of the ilicicolin biosynthetic pathway in Trichoderma reesei

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Scientists used genetic engineering to activate a dormant gene cluster in the fungus Trichoderma reesei, enabling it to produce the antifungal compound ilicicolin H in high quantities. During this process, they discovered a new related compound called ilicicolin K that shows even stronger antifungal properties. These compounds could potentially overcome limitations of current antifungal treatments, especially against drug-resistant fungi like Candida auris.

Carabrone inhibits Gaeumannomyces tritici growth by targeting mitochondrial complex I and destabilizing NAD⁺/NADH homeostasis

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Researchers identified how carabrone, a natural compound from plants, kills a fungus that causes wheat disease. The compound works by blocking a key energy-producing system (complex I) inside the fungus’s cells, which prevents it from producing enough energy to survive. This discovery is important because many current fungicides are losing effectiveness due to resistance, and this compound offers a new way to attack fungi. The findings could help develop new and more effective fungicides for protecting crops.

Comparative proteomics reveals the mechanism of cyclosporine production and mycelial growth in Tolypocladium inflatum affected by different carbon sources

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Researchers studied how different sugars (fructose and sucrose) affect a fungus’s ability to produce cyclosporine A, an important drug used after organ transplants to prevent rejection. Using advanced protein analysis techniques, they found that fructose makes the fungus better at producing the drug, while sucrose makes it grow more mycelium (fungal threads). By identifying the specific proteins involved in each process, scientists can now develop better methods to produce more of this valuable medicine.

Research Keyword: proteomics