Inhibition of fungal mycelial growth

Bacteria from the Amphibian Skin Inhibit the Growth of Phytopathogenic Fungi and Control Postharvest Rots

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Researchers discovered that bacteria living on frog skin can effectively prevent fungal diseases that rot fruits after harvest. These bacteria work by producing toxic compounds and releasing protective gases that stop fungi like green mold from growing. When applied to citrus, tomatoes, and blueberries, the bacteria significantly reduced fruit rot, offering an eco-friendly alternative to chemical fungicides for food preservation.

Green synthesis of silver nanoparticles using fermentation extracts from a mangrove soil bacterium: morphological characterization, and antifungal activities against rice blast fungus

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Researchers developed tiny silver particles made from bacteria found in mangrove soil that effectively kill the fungus causing rice blast disease. These nanoparticles work better than current chemical fungicides and are much safer for the environment and aquatic life. The particles stop the fungus from growing and spreading in rice plants, offering farmers a sustainable alternative to traditional chemical pesticides.

Synthesis of silver nanoparticles employing Polyalthia longifolia leaf extract and their in vitro antifungal activity against phytopathogen

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Scientists successfully created tiny silver particles using leaves from the Polyalthia longifolia plant, an evergreen tree native to India. These silver nanoparticles proved highly effective at stopping the growth of Alternaria alternata, a fungus that damages crops and causes leaf spot disease. The method is inexpensive, environmentally friendly, and the particles remain stable for months, making them a promising natural alternative to chemical fungicides for protecting plants.

Cinchona-based liquid formulation exhibits antifungal activity through Tryptophan starvation and disruption of mitochondrial respiration in Rhizoctonia Solani

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Scientists tested a plant-based extract from Cinchona bark as a natural fungicide against a serious fungus that damages rice crops. The active ingredient, quinine, works by two methods: it blocks the fungus from getting the amino acid tryptophan it needs to survive, and it damages the fungus’s energy-producing structures. When researchers added tryptophan back to the treated fungus, it recovered, confirming this is how the treatment works. This natural fungicide could offer farmers an eco-friendly alternative to chemical pesticides.

Identifying Key Pathogens and Effective Control Agents for Astragalus membranaceus var. mongholicus Root Rot

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Astragalus (a valuable traditional Chinese herb) often develops root rot disease caused by harmful fungi. Researchers identified the specific fungi causing this disease and tested various chemical fungicides and beneficial bacteria to control it. Carbendazim fungicide and a biocontrol bacterium called KRS006 proved most effective, suggesting a combination approach could protect this important medicinal plant from disease.

Evaluation of the Effects of Epicoccum nigrum on the Olive Fungal Pathogens Verticillium dahliae and Colletotrichum acutatum by 1H NMR-Based Metabolic Profiling

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Researchers studied how a beneficial fungus called Epicoccum nigrum can fight two harmful fungi that damage olive trees. Using advanced chemical analysis called NMR spectroscopy, they discovered that when the beneficial fungus encounters disease-causing pathogens, it changes its metabolism and produces compounds that stress the harmful fungi. This study suggests that Epicoccum nigrum could be a natural, environmentally-friendly alternative to chemical fungicides for protecting olive crops.

In vitro activity of seven antifungal agents against Fusarium oxysporum and expression of related regulatory genes

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Researchers tested seven different antifungal medications to find the best treatment for a fungal disease that damages corn crops. Epoxiconazole worked best as a single treatment, but combining pyraclostrobin and difenoconazole together was even more effective. These medications work by interfering with the fungus’s ability to survive and infect corn, making them promising options for protecting corn crops.

Antifungal Volatile Organic Compounds from Talaromyces purpureogenus CEF642N: Insights from One Strain Many Compounds (OSMAC) Strategy for Controlling Verticillium dahliae in Cotton

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Scientists discovered that a beneficial fungus called Talaromyces purpureogenus can produce powerful antifungal compounds that kill cotton wilt disease. By growing this fungus on different nutrient media, researchers identified two main antifungal compounds: 3-octanol and 2-octenal. These natural compounds completely or nearly completely stopped the growth of the cotton wilt pathogen in laboratory tests, offering a promising green alternative to chemical pesticides for protecting cotton crops.

Cell Wall-Mediated Antifungal Activity of the Aqueous Extract of Hedera helix L. Leaves Against Diplodia corticola

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Scientists discovered that extract from ivy leaves can effectively kill a fungus called Diplodia corticola that damages cork oak trees. The extract works by damaging the fungus’s protective cell wall rather than interfering with its internal chemistry. This natural alternative to chemical fungicides could help protect cork production worldwide while being safer for human health and the environment.

therapeutic action: Inhibition of fungal mycelial growth