Research Keyword: GNPS

Olive mill solid waste induces beneficial mushroom-specialized metabolite diversity revealed by computational metabolomics strategies

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This study shows how adding olive mill waste to mushroom growing substrate can increase beneficial compounds in mushrooms while reducing harmful toxins. Researchers grew two types of edible mushrooms (lion’s mane and king oyster) on substrate containing different amounts of olive mill waste and used advanced chemical analysis to identify how the waste affected the mushrooms’ medicinal compounds. Adding olive mill waste increased healthy compounds like hericenones and erinacerins while decreasing toxic enniatin compounds, potentially creating safer and more nutritious mushrooms for consumers.

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Molecular networking identifies an AHR-modulating benzothiazole from white button mushrooms (Agaricus bisporus)

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Researchers discovered a new compound in white button mushrooms called 2-amino-4-methylbenzothiazole that activates the aryl hydrocarbon receptor, which helps regulate gut health and immunity. Using a computational approach called molecular networking to compare mushroom compounds with known beneficial substances, scientists identified this previously unknown compound and confirmed its activity in laboratory cells. This discovery demonstrates how certain mushrooms may contribute to health through specific bioactive compounds and provides a faster method for finding similar compounds in other foods.

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Olive mill solid waste induces beneficial mushroom-specialized metabolite diversity revealed by computational metabolomics strategies

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Researchers studied how adding olive mill waste to mushroom growing substrate affects the beneficial compounds in two edible mushrooms. They used advanced computer analysis of chemical data to find that this waste product increases healthy compounds like hericenones while reducing potentially harmful mycotoxins. This discovery could help make mushroom farming more sustainable and produce safer, healthier mushrooms for consumers.

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Miniaturized high-throughput conversion of fungal strain collections into chemically characterized extract libraries for antimicrobial discovery

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Scientists developed a fast, automated method called FLECS-96 to screen hundreds of fungal species for antimicrobial compounds in a small 96-well plate format. The method combines fungal culture, chemical extraction, and analysis to identify promising candidates against resistant bacteria like Staphylococcus aureus. The team successfully identified two bioactive compounds from the fungi tested. This innovation could significantly speed up the discovery of new antibiotics to combat antibiotic-resistant infections.

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