Fusarium wilt – Page 3

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.

Investigating the activity of Bacillus subtilis and Trichoderma harzianum to mitigate Fusarium wilt disease of diverse cultivars of Vicia faba

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Fava beans are damaged by a fungus called Fusarium that causes wilting and crop loss. Scientists tested two beneficial microorganisms—Trichoderma harzianum and Bacillus subtilis—as natural alternatives to chemical fungicides. Trichoderma worked better, reducing disease by over 70% while also boosting plant health and bean production in two different fava bean varieties.

Flood Inoculation of Fusarium eumartii in Tomato Seedlings: Method for Evaluating the Infectivity of Pathogen Spores

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Scientists have developed a simple laboratory method to test how effectively a fungus called Fusarium eumartii infects young tomato plants. The technique involves growing tomato seedlings on special nutrient plates and then exposing them to fungal spores suspended in water, allowing researchers to measure how much damage occurs and how much fungus remains in the plant tissue. This method can be used to quickly test whether different compounds, like chitosan, can prevent fungal infections or help plants defend themselves naturally. The straightforward approach makes it useful for farmers and researchers developing better ways to protect tomato crops from fungal diseases.

Biocontrol of Fusarium oxysporum f. sp. cepae on Indonesian Local Garlic Plants (Lumbu Hijau) Using a Consortium of Bacillus amyloliquefaciens B1 and Arbuscular Mycorrhizal Fungi

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Researchers developed an effective biological solution to protect Indonesian garlic plants from a destructive fungal disease called Fusarium wilt. Using a combination of beneficial bacteria (Bacillus amyloliquefaciens) and fungi (arbuscular mycorrhizal fungi), they reduced disease damage by 39% while making plants grow larger and stronger. This natural approach offers a safer alternative to chemical fungicides and could help garlic farmers maintain healthy crops.

Automatic classification of fungal-fungal interactions using deep learning models

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Researchers developed a computer artificial intelligence system that can automatically analyze images of fungal interactions to identify strains that could help control harmful crop diseases. Instead of having humans manually examine thousands of fungal culture plates—a slow and subjective process—the AI system can now classify the interactions between beneficial fungi and plant pathogens with 95% accuracy. This breakthrough significantly speeds up the search for natural alternatives to synthetic pesticides, supporting sustainable agriculture and food security.

Tracking of Tobacco Mosaic Virus in Taxonomically Different Plant Fungi

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Scientists discovered that tobacco mosaic virus can infect and replicate inside some fungal pathogens like Botrytis and Verticillium, which are major crop diseases. Interestingly, when viruses infect these fungi, the fungi activate their own defense mechanisms to fight the virus, yet still maintain their ability to cause disease in plants. This discovery opens new possibilities for using plant viruses as tools to study and potentially control harmful fungal pathogens on crops.

In vitro and In silico investigation deciphering novel antifungal activity of endophyte Bacillus velezensis CBMB205 against Fusarium oxysporum

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Researchers isolated a beneficial bacteria called Bacillus velezensis from medicinal plants that can fight against a dangerous fungus causing banana wilt disease. Through laboratory and computer studies, they identified two natural compounds produced by this bacteria that stop the fungus from growing by damaging its cell walls. This discovery offers a promising eco-friendly alternative to chemical fungicides for protecting banana crops worldwide.

Antifungal activity of zinc oxide nanoparticles (ZnO NPs) on Fusarium equiseti phytopathogen isolated from tomato plant in Nepal

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Researchers in Nepal developed a natural way to fight tomato plant diseases by creating tiny zinc oxide nanoparticles from tea leaves. These nanoparticles successfully stopped the growth of a harmful fungus called Fusarium equiseti that was damaging tomato crops. Unlike chemical fungicides that can harm the environment, this eco-friendly approach damaged the fungus’s cell structures without posing risks to surrounding ecosystems, offering farmers a safer way to protect their crops.

Unveiling microRNA-like small RNAs implicated in the initial infection of Fusarium oxysporum f. sp. cubense through small RNA sequencing

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Researchers discovered specific small RNA molecules produced by the fungus that causes banana wilt disease. These molecular signals, particularly one called milR106, are critical for the fungus’s ability to infect and damage banana plants. By understanding how these molecules work, scientists can develop better strategies to protect banana crops from this devastating disease that threatens global banana production.

Transposons and accessory genes drive adaptation in a clonally evolving fungal pathogen

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Researchers studied how a fungal plant pathogen called Fusarium oxysporum rapidly adapts to new environments by analyzing genetic changes during repeated passages through tomato plants and laboratory media. They discovered that jumping genes (transposons) were responsible for most mutations driving adaptation, and surprisingly found that genes located in specialized ‘accessory’ regions of the fungus’s genome controlled important functions like growth and virulence. This research reveals how fungal pathogens can evolve quickly to become better competitors or invaders.

Disease: Fusarium wilt