Research Keyword: microbial inoculants

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.

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Actinorhizal plants and Frankiaceae: The overlooked future of phytoremediation

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Actinorhizal plants are special trees and shrubs that team up with beneficial bacteria called Frankiaceae to clean up polluted and degraded soils. This natural partnership helps these plants survive harsh conditions like salty or heavy metal-contaminated soil while also cleaning up the environment. The bacteria help the plants by providing essential nitrogen and improving their ability to tolerate pollution, making them an inexpensive and sustainable solution for restoring degraded farmland.

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Emerging Role of Arbuscular Mycorrhizal Fungi in Sustainable Agriculture: From Biology to Field Application

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Arbuscular mycorrhizal fungi are microscopic fungi that naturally partner with plant roots to help them grow stronger and healthier. These fungi can improve crop productivity without chemical fertilizers by helping plants absorb water and nutrients, resist drought and salty soils, and fight off diseases. Scientists are now developing commercial products containing these beneficial fungi to help farmers grow crops more sustainably and organically.

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Dual benefits of Lysinibacillus xylanilyticus strain GIC41 in mitigating Pythium root rot and enhancing plant growth across cultivation systems

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Scientists tested a bacteria strain called Lysinibacillus xylanilyticus (GIC41) to fight a destructive plant disease called Pythium root rot. In both soil and water-based growing systems, this bacteria significantly reduced disease symptoms in spinach and tomato plants while also making the plants grow bigger and stronger. The bacteria works by producing enzymes and possibly triggering the plant’s natural defenses, without directly poisoning the disease-causing pathogen.

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Arbuscular Mycorrhizal and Trichoderma longibrachiatum Enhance Soil Quality and Improve Microbial Community Structure in Albic Soil Under Straw Return

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Researchers found that combining two beneficial soil fungi—arbuscular mycorrhizal fungi and Trichoderma longibrachiatum—significantly improved poor quality albic soils when straw was returned to fields. The combined treatment increased soil pH, nutrients, and enzyme activity while promoting beneficial bacteria like Sphingomonas. This microbial approach offers farmers a sustainable, environmentally friendly way to restore degraded soils and improve agricultural productivity in regions with challenging soil conditions.

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In Vitro Mycorrhization for Plant Propagation and Enhanced Resilience to Environmental Stress: A Review

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This review explains how scientists are using special laboratory techniques to grow fungal partnerships with plants that boost plant health and stress tolerance. By combining plant propagation with beneficial fungi in controlled conditions, researchers can produce stronger plants that survive droughts, diseases, and other environmental challenges. These techniques offer promise for sustainable farming and addressing food security concerns as climate change impacts agriculture.

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