gray mold – mycolab.ai

Endophytic Beauveria spp. Enhance Tomato Growth and Resistance to Botrytis cinerea via Transcriptomic Regulation

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Researchers tested five types of beneficial fungi from the Beauveria genus to see if they could help tomato plants grow better and resist gray mold disease. They found that all five species could live inside tomato plants and help them grow taller. Most importantly, the fungus Beauveria brongniartii completely protected plants from gray mold infection. By examining which genes were activated in the plants, scientists discovered that these fungi boost the plant’s natural defense systems while also improving photosynthesis.

The Biological Product Agricultural Jiaosu Enhances Tomato Resistance to Botrytis cinerea

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Agricultural Jiaosu is a fermented product made from plant waste that effectively controls gray mold disease in tomatoes through two mechanisms: it directly kills the fungus with organic acids, and it strengthens the plant’s natural defenses. When applied as a spray to tomato leaves once a week, it reduced disease by 55%, made plants grow taller and stronger, and boosted the plants’ protective enzymes. This natural alternative to chemical fungicides offers a sustainable and safe way to protect tomato crops while maintaining environmental health.

Terpinen-4-ol triggers autophagy activation and metacaspase-dependent apoptosis against Botrytis cinerea

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Terpinen-4-ol, a natural compound from tea tree oil, effectively kills gray mold fungus that spoils fruits and vegetables after harvest. The compound works by damaging fungal cell membranes, creating harmful reactive molecules inside fungal cells, and triggering the fungal cells’ self-destruction pathways. When tested on tomatoes and strawberries, terpinen-4-ol successfully reduced mold growth and disease spread, suggesting it could be a safe, eco-friendly alternative to chemical fungicides for protecting fresh produce.

An Efficient Microwave Synthesis of 3-Acyl-5-bromoindole Derivatives for Controlling Monilinia fructicola and Botrytis cinerea

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Scientists developed new chemical compounds called indole derivatives that can kill harmful fungi that destroy fruit crops like stone fruits and grapes. These compounds were made using microwave heating, which is faster and more efficient than traditional methods. Testing showed that some of these new compounds were even better at fighting these fungal diseases than current commercial fungicides, offering promise for protecting crops in agriculture.

Green Synthesized Copper-Oxide Nanoparticles Exhibit Antifungal Activity Against Botrytis cinerea, the Causal Agent of the Gray Mold Disease

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Scientists have developed tiny copper particles using environmentally friendly methods with beneficial fungi to fight gray mold, a devastating disease in vineyards and crops. These green-synthesized nanoparticles were more effective at stopping the fungus than commercial fungicides currently in use. The research shows this approach could be a sustainable alternative that reduces harmful chemicals used in agriculture while protecting crops more effectively.

Comparison and Analysis of the Genomes of Three Strains of Botrytis cinerea Isolated from Pomegranate

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Researchers compared three strains of gray mold fungus (Botrytis cinerea) that infect pomegranate fruits from different regions in Mexico. Using DNA sequencing and laboratory tests, they found that the MIC strain from Hidalgo was more aggressive at infecting fruit and breaking down plant tissues than the other two strains from the State of Mexico. These differences appear related to each strain’s genetic makeup and where they originated, which could help farmers develop better strategies to prevent gray mold disease on pomegranates.

Mechanism Analysis of Amphotericin B Controlling Postharvest Gray Mold in Table Grapes

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This research shows that amphotericin B, a natural compound produced by bacteria, can effectively prevent gray mold from spoiling table grapes after harvest. The compound works by damaging the mold’s cell membranes and also activates the grapes’ own defense systems. At a treatment level of 200 mg/L, it completely prevented mold growth on grapes over a three-day storage period, offering a safer, more environmentally friendly alternative to synthetic fungicides.

Green Synthesized Copper-Oxide Nanoparticles Exhibit Antifungal Activity Against Botrytis cinerea, the Causal Agent of the Gray Mold Disease

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Scientists developed tiny copper oxide particles using fungi to create a natural fungicide that fights gray mold, a disease that damages grapes and other crops worldwide. These bio-based nanoparticles work better than conventional copper fungicides, offering farmers a more environmentally friendly option. However, the particles showed some toxicity to human cells in laboratory tests, suggesting they need careful handling before field use.

Mechanism Analysis of Amphotericin B Controlling Postharvest Gray Mold in Table Grapes

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Researchers discovered that amphotericin B, a natural compound produced by soil bacteria, effectively prevents gray mold disease on table grapes. The compound works by directly damaging the fungus’s cell membranes and also boosts the grape’s own defense mechanisms. This natural solution could replace harmful synthetic fungicides while extending the shelf life of grapes during storage and transport.

Improved Protoplast Production Protocol for Fungal Transformations Mediated by CRISPR/Cas9 in Botrytis cinerea Non-Sporulating Isolates

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Scientists have developed a better method to isolate protoplasts (fungal cells without cell walls) from non-sporulating varieties of gray mold fungus. By optimizing the incubation time, culture container, and enzyme used, they produced more viable protoplasts that can regenerate and be genetically modified. This advancement allows researchers to use CRISPR gene-editing technology to understand and potentially control gray mold, which causes significant crop losses worldwide.

Research Keyword: gray mold