Research Keyword: mycotoxin control

Citric acid impairs type B trichothecene biosynthesis of Fusarium graminearum but enhances its growth and pigment biosynthesis: transcriptomic and proteomic analyses

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Citric acid, a compound found in plant roots, has an interesting dual effect on a dangerous fungus called Fusarium graminearum that destroys grain crops worldwide. While citric acid helps the fungus grow better, it actually prevents the fungus from producing dangerous toxins called trichothecenes. This finding suggests that citric acid could potentially be used in farming to reduce the harmful toxins that contaminate wheat and corn while maintaining reasonable fungal control.

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Antagonistic Potential of Agro-Industrial Byproduct–Derived Lactic Acid Bacteria Against Mycotoxigenic Aspergillus flavus and Fusarium verticillioides

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Researchers discovered that certain lactic acid bacteria found in food waste products can effectively prevent the growth of harmful fungi and block the production of dangerous mycotoxins. These bacteria work through multiple mechanisms including acidification and production of protective compounds. The findings suggest these natural bacteria could be used as safe, sustainable alternatives to chemical fungicides in food preservation and safety.

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Comprehensive analysis of the mechanisms conferring resistance to phenamacril in the Fusarium species

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Fusarium fungi cause serious diseases in crops like wheat, rice, and vegetables worldwide, leading to significant food losses and contamination with harmful toxins. Phenamacril is a modern fungicide designed to fight these fungi by targeting a specific protein called myosin-5. However, the fungi have developed resistance to this fungicide through genetic changes and other mechanisms, making it less effective over time. Farmers need to use multiple strategies including crop rotation and resistant plant varieties rather than relying only on fungicides to successfully manage these diseases.

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Identification of an antifungal lipopeptide from Bacillus amyloliquefaciens HAU3 inhibiting the growth of Fusarium graminearum using preparative chromatography and 2D-NMR

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Researchers identified a soil bacterium called Bacillus amyloliquefaciens HAU3 that naturally produces fengycin, a powerful antifungal compound. This compound can kill disease-causing fungi like Fusarium graminearum that contaminate animal feed and produce harmful toxins. The bacteria also breaks down dangerous toxins called zearalenone, making it a potential natural solution for protecting livestock feed from fungal contamination.

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The role of Npt1 in regulating antifungal protein activity in filamentous fungi

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Researchers discovered how antifungal proteins work against a dangerous fungus (Aspergillus flavus) that damages crops and produces toxins. They found that these proteins break down the fungal cell wall and then interact with an internal fungal protein called Ntp1. By understanding exactly which part of Ntp1 the antifungal proteins bind to, scientists can now develop better treatments to protect food crops from fungal diseases.

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