gene expression – Page 8

Upregulation of ACC deaminase gene in Bacillus velezensis UTB96 improved yield and shelf Life of Agaricus bisporus

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Researchers discovered that adding a beneficial bacteria called Bacillus velezensis UTB96 to mushroom growing substrates significantly improves both the amount of mushrooms produced and how long they stay fresh. When this bacteria was grown in a medium containing calcium chloride, it produced more of an enzyme called ACC deaminase that breaks down ethylene, a gas that causes mushrooms to age and brown. Mushrooms treated with this specially-prepared bacteria stayed fresher for three weeks in the refrigerator with minimal browning, and overall mushroom yield increased by up to 23%.

Integration of fungal transcriptomics and metabolomics provides insights into the early interaction between the ORM fungus Tulasnella sp. and the orchid Serapias vomeracea seeds

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This research explores how orchid fungi recognize and respond to orchid seeds before even touching them. Scientists used advanced molecular techniques to track changes in fungal genes and chemical compounds during the early stages of this symbiotic partnership. The findings show that the fungus actively prepares itself to penetrate the seed’s protective barriers, producing special enzymes and metabolites that facilitate this critical interaction for orchid survival.

Overexpression of efflux pump and biofilm associated genes in itraconazole resistant Candida albicans isolates causing onychomycosis

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Researchers studied why some fungal nail infections caused by Candida albicans stop responding to the antifungal drug itraconazole. They found that resistant fungal cells have higher activity of genes that pump the drug out of cells and produce slimy protective coatings called biofilms. These resistant fungi also formed less dense biofilms when the drug was present from the start. Understanding these resistance mechanisms could help develop new treatments by targeting the pump systems or breaking down the protective biofilm layers.

Anoectochilus roxburghii Extract Extends the Lifespan of Caenorhabditis elegans through Activating the daf-16/FoxO Pathway

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Researchers studied a traditional Asian orchid plant (Anoectochilus roxburghii) and found it can extend the lifespan of laboratory worms by about 16% and help them resist stress from UV light and heat. The plant works by activating a specific genetic pathway that increases the worm’s natural antioxidant defenses, protecting cells from damage. These findings suggest the plant could potentially be developed into anti-aging products for humans.

Volatile Metabolome and Transcriptomic Analysis of Kosakonia cowanii Ch1 During Competitive Interaction with Sclerotium rolfsii Reveals New Biocontrol Insights

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Researchers found that a bacterium called K. cowanii produces special gases (volatile organic compounds) that kill fungal plant diseases like those caused by Sclerotium rolfsii. When grown together with this fungus, the bacterium produces these toxic gases which inhibit fungal growth by up to 80%. The study identified specific genes the bacteria activate to produce these antifungal compounds, offering a natural alternative to chemical fungicides for protecting crops.

Inhibitive effect of Urginea epigea methanolic extract and silver/zinc oxide nanoparticles on Aspergillus and aflatoxin production

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Scientists tested a plant called Urginea epigea and special tiny particles made of silver and zinc to stop a dangerous fungus called Aspergillus flavus from growing and producing aflatoxins, which are harmful poisons found in food. When used at the right concentration, the plant extract completely stopped the fungus from growing. The treatment worked by turning off the fungus’s ability to make the poison by reducing the activity of specific genes. This natural approach could offer a safer alternative to chemical fungicides for protecting our food supply.

Expression of a novel NaD1 recombinant antimicrobial peptide enhances antifungal and insecticidal activities

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Scientists created a new genetically modified tobacco plant that produces a powerful natural pest-fighting protein called NaD1. By attaching special chitin-binding components to this protein, they made it stick better to fungal pathogens and insect digestive systems. When tested, these enhanced proteins killed fungi more effectively and caused higher mortality rates in crop-damaging insects, offering a promising natural alternative to chemical pesticides.

Molecular Regulation of Carotenoid Accumulation Enhanced by Oxidative Stress in the Food Industrial Strain Blakeslea trispora

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Researchers studied how stressful conditions can make a fungus called Blakeslea trispora produce more carotenoids, which are natural pigments used to color food products. When exposed to chemical stressors like rose bengal or hydrogen peroxide, the fungus produced significantly more carotenoids – up to four times more in some cases. The study identified specific genes and cellular pathways responsible for this increased production, which could help food companies produce natural food colorants more efficiently.

Development of a molecular genetics and cell biology toolbox for the filamentous fungus Diplodia sapinea

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Scientists have developed new tools to study a fungus called Diplodia sapinea that damages pine trees around the world. They created a method to genetically modify this fungus and tag its cell nuclei with a red fluorescent marker so they can track the infection process. They also developed a simple way to test infections using young pine seedlings in the laboratory instead of large greenhouse setups. Using these new tools together, researchers can now watch in real-time how the fungus grows inside infected pine plants, which will help develop better ways to protect forests.

Transcriptome analysis of Ochratoxin a (OTA) producing Aspergillus westerdijkiae fc-1 under varying osmotic pressure

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A fungus called Aspergillus westerdijkiae produces a toxic substance called Ochratoxin A (OTA) that commonly contaminates foods like coffee, grapes, and wheat. Researchers used advanced gene analysis techniques to understand how salt concentration affects the fungus’s ability to produce this toxin. They found that moderate salt levels actually increase OTA production, while very high salt levels activate defense mechanisms that reduce it. These findings could help develop better strategies to prevent this dangerous contamination in our food supply.

Research Keyword: gene expression