therapeutic action: growth promotion

The Structural and Functional Diversities of Bacteria Inhabiting Plant Woody Tissues and Their Interactions with Fungi

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Bacteria living in tree wood work together with fungi to break down wood and nutrients, which is important for forest health. Some bacteria can protect trees from harmful fungi by fighting them off, making them useful for controlling plant diseases. Understanding how bacteria and fungi interact in wood can help us grow healthier plants, manage tree diseases better, and improve wood decomposition processes.

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Leucocalocybe mongolica inoculation enhances rice growth by reallocating resources from flavonoid defense to development via MYB/bHLH/WRKY networks

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A fungal strain called Leucocalocybe mongolica (LY9) can help rice plants grow bigger and healthier by improving how they use nutrients and sunlight. Interestingly, when plants grow better with this fungus, they produce fewer defensive compounds called flavonoids, but they still maintain some protective molecules. This research shows that the fungus helps plants decide to invest more energy in growth rather than defense, making it a promising natural fertilizer for farming.

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Isolation and characterization of a new Leptobacillium species promoting tomato plant growth

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Scientists discovered a new type of beneficial fungus living inside tomato plant roots that helps the plants grow better and produce more nutritious fruit. This fungus, called Leptobacillium sp., makes plant hormones and special compounds that help tomato plants absorb nutrients more effectively. When tomato seeds were treated with this fungus, the plants grew taller and produced fruits with higher levels of lycopene, a beneficial compound. This discovery could help farmers grow better tomatoes using nature’s own microorganisms instead of relying on chemical treatments.

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Identification of Trichoderma spp., Their Biomanagement Against Fusarium proliferatum, and Growth Promotion of Zea mays

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Researchers isolated and tested special fungi called Trichoderma that can fight crop disease-causing fungi and promote plant growth. When applied to maize plants infected with disease-causing Fusarium, the Trichoderma fungi completely eliminated the disease and made the plants grow healthier and larger. This natural approach offers farmers a chemical-free alternative to protect crops while improving plant health.

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The green shield: Trichoderma’s role in sustainable agriculture against soil-borne fungal threats

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This research demonstrates that Trichoderma fungi, naturally found in soil, can effectively control harmful plant-killing fungi without toxic chemicals. Scientists isolated these beneficial fungi from Kashmir soil samples and tested them against 12 destructive fungal pathogens, finding they successfully inhibited pathogen growth. The study shows promise for farmers to use these natural biocontrol agents as an environmentally friendly alternative to chemical pesticides.

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Development of a granular bioformulation of Achromobacter xylosoxidans AX77 16S for sustainable onion white rot management and growth enhancement

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Scientists discovered a beneficial bacterium living inside onion seeds that can fight a serious fungal disease called white rot and help seeds grow better. They turned this bacterium into an easy-to-use granular product that lasts up to a year, offering farmers an environmentally friendly alternative to chemical fungicides. The product not only prevents the fungal disease but also improves seed germination and plant growth, making it a promising sustainable solution for onion farming.

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Endophytic Alternaria alternata Culture-Derived Elicitor Promotes Growth and Antibacterial Activity in Kalanchoe laetivirens

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Researchers cultivated medicinal Kalanchoe plants in controlled laboratory conditions and exposed them to a powdered form of a beneficial fungus (Alternaria alternata). The plants treated with this fungal extract grew larger, developed more roots, and produced greater amounts of antibacterial compounds compared to untreated plants. The treated plants were especially effective at stopping the growth of two common disease-causing bacteria (E. coli and S. aureus). This approach could lead to more efficient production of plant-based medicines.

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