lignocellulose degradation – Page 2

Organic Nitrogen Supplementation Increases Vegetative and Reproductive Biomass in a Versatile White Rot Fungus

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Researchers studied how adding nitrogen from plant litter affects the growth and mushroom production of a wood-rotting fungus called Cyclocybe aegerita. They found that adding the organic compound adenosine—which naturally occurs in plant litter—significantly boosted both the fungus’s vegetative growth and the production of mushrooms. The results suggest that fungi living in wood benefit from being able to absorb nitrogen-rich compounds from nearby plant material, which improves their ability to grow and reproduce.

Exogenous MnSO4 Improves Productivity of Degenerated Volvariella volvacea by Regulating Antioxidant Activity

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This study shows that adding manganese sulfate to degenerated mushroom strains can restore their ability to grow and produce fruit bodies. The treatment works by improving the mushrooms’ natural defense systems against damaging free radicals and enhancing enzymes that break down the growing medium. Results showed significantly improved growth rates, shorter production times, and even allowed severely damaged strains to produce mushrooms again.

The Microbial Community Succession Drives Stage-Specific Carbon Metabolic Shifts During Agaricus bisporus Fermentation: Multi-Omics Reveals CAZymes Dynamics and Lignocellulose Degradation Mechanisms

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This research examines how different bacteria in mushroom compost work together to break down agricultural waste during the growing process. Scientists tracked microbial communities over 15 days of fermentation, finding that early stages use bacteria specialized in breaking down plant fibers, while later stages shift to bacteria that handle more complex compounds. Understanding these microbial changes helps optimize mushroom cultivation and reduce agricultural waste.

Characterization of Self-Growing Biomaterials Made of Fungal Mycelium and Various Lignocellulose-Containing Ingredients

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Scientists developed environmentally-friendly foam-like materials by growing mushroom mycelium (the root-like network of fungi) on agricultural waste like hemp and sawdust. These natural composites are strong, biodegradable, and can be used for packaging or insulation instead of plastic foam. However, they absorb water easily and can develop mold if exposed to moisture, so they need protective coatings for some applications.

Optimization of substrate formulation for Hericium erinaceus by replacing wood by straw and their effect on enzyme activities

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Researchers developed an improved growing formula for lion’s mane mushrooms using agricultural waste materials like rice straw and corn cob instead of wood chips. This new formula grew mushrooms faster, with better harvest yields (89% biological efficiency), and produced mushrooms with higher nutritional value including more protein and beneficial minerals. The innovation helps solve resource conflicts with the forestry industry while reducing cultivation costs and environmental waste.

Efficient conversion of tea residue nutrients: Screening and proliferation of edible fungi

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Researchers developed an environmentally friendly method to convert tea waste into nutritious fungal protein using edible mushrooms. By testing six different fungal species, they found that Monascus kaoliang B6 was most efficient at breaking down the complex fiber structures in tea residue and converting them into fungal biomass. This sustainable process eliminates the need for chemical treatments and harsh conditions, turning agricultural waste into valuable food ingredients.

Biochar Composite with Enhanced Performance Prepared Through Microbial Modification for Water Pollutant Removal

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Scientists created a special type of charcoal (biochar) by using fungi to break down agricultural waste before processing it. This fungal-treated biochar is much better at removing pollutants like dyes, antibiotics, and heavy metals from water compared to regular biochar. The material can be reused many times, making it practical and cost-effective for cleaning contaminated water.

First Report of Trametes hirsuta, Causal Agent White Rot in Avocado Trees Grown in the State of Michoacán, México

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Researchers discovered that a wood-decay fungus called Trametes hirsuta is causing serious damage to avocado trees in Michoacán, México, the world’s largest avocado-producing region. The fungus infects tree trunks and branches, causing white rot that eventually kills the trees. About 60% of surveyed avocado trees showed signs of infection. Laboratory experiments confirmed that this fungus, previously known only as a decomposer of dead wood, can actively infect and destroy living avocado trees through wounds in the bark.

Enhancing the Yield of Pleurotus ostreatus Through the Addition of Nucleotides and Nucleosides

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Researchers discovered that adding nucleotides and nucleosides to oyster mushroom growing medium significantly increases mushroom yield and nutritional value. These compounds enhanced the dietary fiber and amino acid content while helping the mushrooms break down tough plant materials more efficiently. The study suggests that nucleosides are particularly effective and could provide a simpler, safer alternative to traditional mushroom cultivation methods that involve lengthy composting processes.

Modulation of Abortiporus biennis Response to Oxidative Stress by Light as a New Eco-Friendly Approach with a Biotechnological Perspective

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Researchers studied how different colored lights and a chemical called menadione affect a white rot fungus called Abortiporus biennis. They found that combining red light with menadione significantly increased the fungus’s metabolic activity and production of useful compounds like laccase, an enzyme with industrial and medical applications. The study shows that using simple, eco-friendly stressors like colored light could help boost the fungus’s beneficial properties for practical use.

Research Keyword: lignocellulose degradation