enhanced nutrient uptake

A review on microbe–mineral transformations and their impact on plant growth

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Soil microorganisms are crucial partners that help plants access nutrients locked in soil minerals. Bacteria and fungi produce special acids and molecules that dissolve minerals, making nutrients like phosphorus, iron, and zinc available for plant roots to absorb. This natural process reduces the need for chemical fertilizers and helps plants grow stronger while cleaning up contaminated soils.

Biostimulant and Bioinsecticidal Effect of Coating Cotton Seeds with Endophytic Beauveria bassiana in Semi-Field Conditions

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Researchers coated cotton seeds with a beneficial fungus called Beauveria bassiana to improve plant growth and reduce insect pests. The treated cotton plants grew taller, had more leaves, and accumulated more biomass than untreated plants. Additionally, these coated seeds significantly reduced populations of aphids that naturally infested the plants, offering a chemical-free approach to pest management for cotton farming.

Leucocalocybe mongolica Fungus Enhances Rice Growth by Reshaping Root Metabolism, and Hormone-Associated Pathways

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Researchers discovered that a special fungus called Leucocalocybe mongolica, when added to soil, significantly improves rice plant growth without requiring chemical fertilizers. Plants grown in fungus-treated soil developed more branches (tillers), had longer roots, and contained more chlorophyll, making them greener and healthier. The study revealed that the fungus works by altering soil nutrients and triggering specific genes in rice roots that boost growth-promoting hormones and improve how plants process energy.

Plant–Fungi Mutualism, Alternative Splicing, and Defense Responses: Balancing Symbiosis and Immunity

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Fungi form beneficial partnerships with plant roots, helping plants absorb nutrients and resist stress. A key process called alternative splicing allows cells to make different versions of proteins from the same genes, fine-tuning how plants and fungi cooperate. This review explains how alternative splicing acts like a molecular switch that balances the plant’s immune system with accepting the beneficial fungus, and how understanding this could help farmers grow healthier crops with less chemical fertilizers.

Mycorrhizae and grapevines: the known unknowns of their interaction for wine growers’ challenges

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Arbuscular mycorrhizal fungi form beneficial partnerships with grapevine roots, helping plants absorb water and nutrients while improving stress tolerance. These fungi relationships begin in plant nurseries and continue in vineyards, but their effectiveness depends on the specific fungus species, vine variety, and farming practices like soil management and herbicide use. Using these fungi as biological stimulants could help grapevines cope with climate change challenges like drought and heat, though more field studies are needed to confirm their practical benefits.

Can the DSE Fungus Exserohilum rostratum Mitigate the Effect of Salinity on the Grass Chloris gayana?

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Researchers tested whether a beneficial fungus called Exserohilum rostratum could help a grass species called Rhodes grass survive in salty soil conditions. The fungus was found to tolerate salt well and helped the grass maintain better nutrient balance, but these benefits were limited and didn’t fully protect the grass from the negative effects of high salt levels. This suggests that while the fungus can be helpful, its effectiveness depends on specific conditions and salt concentrations.

Halotolerant Endophytic Fungi: Diversity, Host Plants, and Mechanisms in Plant Salt–Alkali Stress Alleviation

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Salty and alkaline soil is destroying farmland worldwide, but special fungi living inside plants can help crops survive these harsh conditions. These fungi work like a team with plants, producing protective substances and helping plants manage salt and reduce damage from stress. Scientists reviewed 150 studies and found these fungi boost crop yields by 15-40%, offering a natural way to farm on degraded land without more chemicals.

Can the DSE Fungus Exserohilum rostratum Mitigate the Effect of Salinity on the Grass Chloris gayana?

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Researchers tested whether a fungus called Exserohilum rostratum could help a forage grass called Rhodes grass survive in salty soil. The fungus did tolerate salt and helped the grass maintain better nutrient balance under salt stress, but it couldn’t fully protect the grass from severe salinity. The benefits were most noticeable under moderate salt conditions, suggesting the fungus works best in less extreme environments.

Bio-stimulants for plant growth promotion and sustainable management of Rhizoctonia Solani causing black scurf of potato tubers

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Researchers tested natural treatments called bio-stimulants to help potato plants fight black scurf disease caused by a fungus called Rhizoctonia solani. They found that combining mycorrhizal fungi with seaweed extract was the most effective at reducing disease and improving potato quality. These natural treatments can enhance plant growth and tuber yield while reducing the need for chemical fungicides, making them valuable for sustainable potato farming.

Bacillus subtilis ED24 Controls Fusarium culmorum in Wheat Through Bioactive Metabolite Secretion and Modulation of Rhizosphere Microbiome

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A beneficial bacteria called Bacillus subtilis ED24 was found to effectively protect wheat plants from a destructive fungal disease called Fusarium culmorum. When applied to wheat seeds, this bacteria improved seed germination and plant growth better than a commercial chemical fungicide, while also promoting helpful microorganisms in the soil around the plant roots. The bacteria works by producing special chemical compounds that kill the harmful fungus and by enriching the soil microbiome with beneficial organisms.

therapeutic action: enhanced nutrient uptake