Lentinula edodes – Page 20

Biodiversity of Bacteria Associated with Eight Pleurotus ostreatus (Fr.) P. Kumm. Strains from Poland, Japan and the USA

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Oyster mushrooms grown in different parts of the world carry diverse communities of bacteria living inside or on their cells. Researchers identified over 34 different types of bacteria in eight oyster mushroom strains from Poland, Japan, and the USA. These bacteria likely help the mushrooms break down wood and may protect them from diseases. This discovery shows that oyster mushrooms are not solitary organisms but rather complex ecosystems hosting beneficial bacterial partners.

Pleurotus eryngii Culture Filtrate and Aqueous Extracts Alleviate Aflatoxin B1 Synthesis

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This research demonstrates that extracts from oyster mushrooms (Pleurotus eryngii) can effectively reduce dangerous aflatoxin contamination in food and feed by up to 94%. Aflatoxins are toxic compounds produced by mold fungi that can cause serious health problems including cancer. The study shows that mushroom compounds work through multiple mechanisms including antioxidant activity and enzyme production, offering a natural and environmentally friendly alternative to harmful synthetic chemicals for protecting our food supply.

LC/MS- and GC/MS-based metabolomic profiling to determine changes in flavor quality and bioactive components of Phlebopus portentosus under low-temperature storage

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This research examines what happens to black bolete mushrooms when stored in the refrigerator. Scientists used advanced chemical analysis to track how the mushroom’s flavor and nutritional compounds change over a two-week period. They discovered that an earthy smell compound called geosmin builds up during storage, which affects how the mushroom tastes. The findings suggest that cold storage alone is not ideal, and better preservation methods need to be developed.

The Transformation and Protein Expression of the Edible Mushroom Stropharia rugosoannulata Protoplasts by Agrobacterium-tumefaciens-Mediated Transformation

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Researchers successfully developed a method to genetically modify the edible mushroom Stropharia rugosoannulata using Agrobacterium tumefaciens bacteria. This technique allows scientists to insert and express foreign genes in the mushroom, providing tools to study how specific genes control mushroom growth and the production of health-promoting compounds. The study demonstrates that both artificial and natural resistance markers can be used to identify successfully transformed mushrooms, offering a foundation for improving mushroom cultivation and breeding.

Whole Genome Sequence of an Edible Mushroom Stropharia rugosoannulata (Daqiugaigu)

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Scientists have decoded the complete genetic blueprint of the wine cap mushroom (Stropharia rugosoannulata), a popular edible mushroom grown worldwide. The research identified over 12,000 genes and discovered the mushroom contains powerful enzymes that break down plant material, explaining why it grows so well on straw and corn stalks. The study also revealed that different parts of the mushroom (cap and stem) have different functions, with stems focusing on energy production and caps on growth and development.

Impact of bottom ash addition on Pleurotus ostreatus cultivation on coffee ground substrate

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This study investigated growing oyster mushrooms on a mixture of used coffee grounds and coal plant bottom ash. The researchers found that adding small amounts of bottom ash (1-5%) slowed mushroom growth slightly but actually reduced harmful heavy metals in the final mushrooms compared to using only coffee grounds. The leftover substrate after mushroom harvest could be used as a fertilizer for poor soils, creating a complete recycling system that turns industrial and food waste into useful products.

Transcriptome Analysis Reveals Critical Genes Involved in the Response of Stropharia rugosoannulata to High Temperature and Drought Stress

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This study examined how a type of edible mushroom called Stropharia rugosoannulata responds to high heat and dry conditions by analyzing which genes become active. Researchers found that under stress, the mushroom activates specific genes that help it survive, particularly through a cellular communication pathway called MAPK. They identified 15 key genes that could be useful for breeding mushroom varieties that better withstand harsh growing conditions, which could improve mushroom farming efficiency.

The Fungus Among Us: Innovations and Applications of Mycelium-Based Composites

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Mycelium-based composites are eco-friendly building materials made by growing mushroom fungus on agricultural waste like sawdust and straw. These materials are lightweight, provide excellent insulation and soundproofing, and are much more sustainable than synthetic alternatives. However, they absorb water easily and aren’t strong enough for load-bearing structures, making them best suited for insulation and non-structural panels.

Exploring the Mechanisms of Amino Acid and Bioactive Constituent Formation During Fruiting Body Development in Lyophyllum decastes by Metabolomic and Transcriptomic Analyses

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This study examined how Lyophyllum decastes mushrooms develop and build up their nutritious compounds. Researchers tracked amino acids and polysaccharides across four growth stages and identified which genes control their production. The mature mushrooms contained the highest levels of beneficial compounds, with amino acids reaching 45,107.39 μg/g and polysaccharides at 13.66 mg/g. These findings help explain why these mushrooms are nutritious and suggest ways to grow them better for maximum health benefits.

Study on the Properties and Design Applications of Polyester–Cotton Matrix Mycelium Composite Materials

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Scientists have developed a new eco-friendly material by growing mushroom mycelium on polyester-cotton textile waste, creating a biodegradable composite that could replace plastic foams. The best results came from a blend of 65% polyester and 35% cotton, which provided a good balance of strength, moisture resistance, and the ability to break down naturally in soil. This innovation offers a promising solution to the massive problem of textile waste, which currently piles up in landfills around the world.

Fungal Species: Lentinula edodes