plant growth promotion

Innovative fungal bioagents: producing siderophores, IAA, and HCN to support plants under salinity stress and combat microbial plant pathogens

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Scientists discovered two beneficial fungi that help wheat plants survive in salty soil and resist diseases. These fungi work by producing growth-promoting substances and natural compounds that fight harmful plant pathogens. When used to treat wheat seeds, these fungi significantly improved plant growth even under high salt stress conditions, offering a natural alternative to chemical fertilizers and pesticides for farming in salt-affected areas.

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.

Impact of energy metabolism pathways in promoting phytoremediation of cadmium contamination by Bacillus amyloliquefaciens Bam1

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Researchers developed genetically modified bacteria (Bacillus amyloliquefaciens) that produce more energy to better survive in cadmium-contaminated soil. These enhanced bacteria can then help tomato plants absorb and remove cadmium pollution from the soil more effectively. The best-performing modified strain increased cadmium accumulation in tomatoes by nearly 1.9 times compared to the original bacteria, offering a promising biological solution for cleaning contaminated agricultural soils.

Isolation of Bacteria from Lead-Contaminated Soil and Bacterial Interaction Test with Plant Growing on Lead-Amended Media

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Researchers discovered special bacteria from lead-contaminated soil that can accumulate and neutralize lead while also producing a plant hormone called IAA. When these bacteria were added to three ornamental plants growing in lead-contaminated soil, the plants grew better and absorbed less lead. This discovery offers a promising natural and sustainable way to clean up lead-polluted environments by combining bacteria and plants.

Development and Transfer of Microbial Agrobiotechnologies in Contrasting Agrosystems: Experience of Kazakhstan and China

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Microbial consortia—communities of beneficial microorganisms—offer promising solutions to modern agriculture’s challenges by enhancing plant growth, improving stress tolerance, and restoring soil health. China has successfully integrated these microbial products into farming through strong government support and research infrastructure, while Kazakhstan has the scientific knowledge but faces funding and implementation challenges. This comparative study shows that adopting these technologies requires both scientific advancement and practical support systems tailored to each country’s specific needs.

Recent Advances and Developments in Bacterial Endophyte Identification and Application: A 20-Year Landscape Review

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Bacterial endophytes are beneficial bacteria living inside plants that help them grow stronger, resist diseases, and even clean up polluted soil. Scientists have studied these helpful microbes for 20 years and discovered they can be identified using both traditional laboratory methods and advanced DNA technologies. These bacteria show promise for making farming more sustainable by reducing the need for chemical pesticides and helping crops survive droughts and other stressors.

Response of Chaetomium sp. to Nitrogen Input and Its Potential Role in Rhizosphere Enrichment of Lycium barbarum

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Goji berries grow better when treated with a beneficial fungus called Chaetomium, especially when combined with proper nitrogen management. This fungus helps regulate nitrogen cycling in the soil and promotes plant growth more effectively than nitrogen fertilizer alone. The research suggests that farmers can reduce nitrogen fertilizer use while maintaining or improving crop productivity by using this fungal inoculant, which is better for the environment.

Synergistic effects of beneficial microbial inoculants and SMS-amendments on improving soil properties and Pinus seedling growth in degraded soils

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This study shows how mixing beneficial bacteria with mushroom waste can improve poor soil quality. The bacteria help break down the mushroom waste into nutrients that plants need, while also creating a healthier soil environment full of beneficial microbes. When this treated mushroom waste was added to degraded soil and used to grow pine seedlings, the plants grew taller with thicker stems and more leaves than in untreated soil. This approach offers a practical way to recycle agricultural waste while restoring damaged soils.

Research Keyword: plant growth promotion