Stress tolerance enhancement

Trichoderma and its role in biological control of plant fungal and nematode disease

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Trichoderma is a beneficial fungus that can protect crops from diseases and pests while promoting healthier plant growth, without harmful chemical pesticides. It works through multiple strategies: competing with harmful fungi for nutrients, producing natural toxins that kill pathogens, directly parasitizing disease-causing organisms, and strengthening the plant’s own immune system. This eco-friendly approach reduces chemical pollution while improving crop quality and yields, making it an ideal solution for sustainable farming.

Genome-Wide Characterization and Expression Profiling of Phytosulfokine Receptor Genes (PSKRs) in Triticum aestivum with Docking Simulations of Their Interactions with Phytosulfokine (PSK): A Bioinformatics Study

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This study mapped and analyzed receptor genes in wheat that respond to a natural plant hormone called phytosulfokine. Researchers identified 57 versions of these receptor genes distributed across wheat’s genome and found they are most active in roots and leaves at different growth stages. Computer modeling showed how the plant hormone binds to its receptors. These findings could help develop wheat varieties that grow better and handle stress more effectively.

Impacts of dietary sodium alginate as a prebiotic on the oriental river prawn (Macrobrachium nipponense): A comprehensive analysis of growth, physiology, immunity, antioxidant, and metabolism

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This study tested whether sodium alginate, a natural substance from brown seaweed, could improve the health and growth of freshwater prawns used in farming. After 60 days of feeding trials, prawns given the highest dose of sodium alginate (4.0 grams per kilogram of feed) showed significantly better growth, improved immune function, and stronger antioxidant defenses compared to control groups. The supplement also promoted beneficial bacteria in the prawns’ digestive systems and improved their overall body composition.

A review and case study of Rhododendron moulmainense highlights the feasibility and adaptation of evergreen Rhododendron plants to current environmental challenges

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This study examines Rhododendron moulmainense, a beautiful alpine flowering plant being adapted for urban gardens. Researchers discovered that special soil fungi living in the plant’s roots help it survive stress like drought and heat. The study details multiple ways to grow new plants through cuttings, tissue culture, and seeds, with success rates over 90%. Understanding this plant’s adaptation mechanisms provides strategies for introducing more alpine rhododendrons to lower-altitude cities while improving their resilience to climate challenges.

Aspergillus fumigatus dsRNA virus promotes fungal fitness and pathogenicity in the mammalian host

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Researchers discovered that a virus infecting the dangerous fungus Aspergillus fumigatus actually helps the fungus survive and cause worse infections in humans. By removing the virus from fungal strains, scientists found that the fungus became weaker and less able to cause disease in mice. Importantly, treating infected mice with an antiviral drug (ribavirin) reduced the viral load and helped the mice survive, suggesting a new approach to treating serious fungal infections.

Phytohormones and volatile organic compounds, like geosmin, in the ectomycorrhiza of Tricholoma vaccinum and Norway spruce (Picea abies)

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This research examines how a fungus (Tricholoma vaccinum) and spruce tree communicate through chemical signals. The fungus produces unique compounds including geosmin (the earthy smell of soil after rain), limonene (lemon scent), and plant hormones. These chemicals help the fungus and tree establish their beneficial partnership by affecting how the fungus grows and branches around the tree roots. The findings show that these chemical signals are crucial for successful formation of the mycorrhizal relationship.

Autophagy and the Mitochondrial Lon1 Protease Are Necessary for Botrytis cinerea Heat Adaptation

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Scientists studied how a fungus that causes gray mold disease adapts to heat stress by examining two key cellular processes: autophagy (cellular cleanup) and a mitochondrial protease called Lon1. They found that both processes work together to help the fungus survive high temperatures by removing damaged cellular components and maintaining healthy mitochondria. When either process was disrupted, the fungus became much more vulnerable to heat and could not survive as well.

Fungal Assemblages in Northern Elms—Impacts of Host Identity and Health, Growth Environment, and Presence of Dutch Elm Disease

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This study examined the different fungi living in elm tree shoots to understand why some elm species are more resistant to Dutch elm disease than others. Researchers found that healthy elms host fewer fungal species compared to diseased trees, and that fungal communities differ significantly between elm species and urban versus rural locations. Importantly, a fungus called Sphaeropsis ulmicola appears to be a significant emerging threat to elms in northern Europe, separate from the classic Dutch elm disease pathogen.

Endophytic Fungi Isolated from the Marine Macroalga Dictyopteris pacifica in Korea

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Researchers in Korea discovered three species of fungi living inside a brown seaweed called Dictyopteris pacifica. These fungi were previously unknown in Korea and were identified using genetic analysis. The fungi have mutualistic relationships with the seaweed and may produce compounds useful for medicines and treating diseases.

Genomic Insights into Vaccinium spp. Endophytes B. halotolerans and B. velezensis and Their Antimicrobial Potential

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Scientists discovered that wild berries like blueberries, cranberries, and lingonberries contain beneficial bacteria that can fight harmful fungi and bacteria. These bacteria produce natural antimicrobial compounds similar to how antibiotics work, making them promising candidates for protecting crops without chemical pesticides. The bacteria also help plants absorb nutrients and cope with stress, offering multiple benefits for sustainable agriculture.

therapeutic action: Stress tolerance enhancement