Research Keyword: KEGG pathway

A Combination of Transcriptome and Enzyme Activity Analysis Unveils Key Genes and Patterns of Corncob Lignocellulose Degradation by Auricularia heimuer under Cultivation Conditions

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Researchers investigated using corncob, a corn industry byproduct, as a growing medium for Auricularia heimuer mushrooms instead of expensive sawdust. By analyzing which genes the mushroom activates at different growth stages, they identified key enzymes responsible for breaking down corncob’s tough cellulose structure. The findings show the mushroom can effectively adapt to use corncob as a substrate, offering a sustainable and economical alternative for mushroom farming while reducing agricultural waste.

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The impact of continuous cultivation of Ganoderma lucidum on soil nutrients, enzyme activity, and fruiting body metabolites

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This study examined how growing Ganoderma lucidum (a medicinal mushroom) on the same land for two consecutive years affects the soil and the mushroom’s beneficial compounds. Researchers found that continuous cultivation depleted soil nutrients and reduced enzyme activity, particularly in the top layer of soil. The mushrooms grown in the first year had more beneficial compounds than those grown in the second year, with differences linked to changes in soil quality and microbial activity.

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Post-Harvest Quality Changes and Molecular Responses of Epidermal Wax in ‘Munage’ Grapes with Botrytis cinerea Infection

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‘Munage’ grapes from Xinjiang are susceptible to a fungus called Botrytis cinerea that causes gray mold during storage. The fungus dissolves the protective waxy coating on the grape surface, leading to faster deterioration. The study identified specific genes and proteins that control wax production, which could help scientists develop better storage methods and disease prevention strategies to keep grapes fresher longer.

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Dynamic succession of microbial compost communities and functions during Pleurotus ostreatus mushroom cropping on a short composting substrate

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Researchers studied how bacteria and fungi work together when growing oyster mushrooms on composted materials. They found that certain bacteria, particularly Actinomycetales, increase in abundance as mushrooms grow and help break down tough plant materials like cellulose. These bacteria actually help the mushroom grow better, suggesting a cooperative relationship rather than competition. This knowledge could help improve mushroom production efficiency.

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Screening of active components of Ganoderma lucidum and decipher its molecular mechanism to improve learning and memory disorders

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Researchers used computer analysis and laboratory experiments to understand how a medicinal mushroom called Ganoderma lucidum (reishi) helps improve memory and learning problems. They identified ten key active ingredients in the mushroom that work together to reduce inflammation in the brain and protect nerve cells. The most important ingredient appears to be a compound called β-sitosterol, which helps prevent memory loss similar to effects seen in Alzheimer’s disease.

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Transcriptome analysis of Ochratoxin A (OTA) producing Aspergillus westerdijkiae fc-1 under varying osmotic pressure

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Researchers studied how salt levels affect the production of Ochratoxin A (OTA), a harmful toxin made by a fungus commonly found in foods like coffee and dried meats. Using genetic analysis techniques, they found that different salt concentrations trigger different genes in the fungus, affecting how much toxin it produces. This research helps explain why OTA contamination is worse in high-salt foods and could lead to better ways to prevent food poisoning from this fungus.

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Transcriptome Analysis Explored the Differential Genes’ Expression During the Development of the Stropharia rugosoannulata Fruiting Body

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Researchers studied how S. rugosoannulata mushrooms grow and develop by analyzing which genes are active at different stages of fruit body formation. They found that the mushroom’s development relies heavily on glucose and amino acid metabolism, with special genetic processes called alternative splicing playing key roles in maturation. This is the first comprehensive genetic study of this edible mushroom’s development, providing valuable information for improving cultivation techniques and mushroom quality.

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Comparative transcriptome analysis reveals the genetic basis underlying the biosynthesis of polysaccharides in Hericium erinaceus

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Researchers studied six different strains of lion’s mane mushrooms to understand how they produce beneficial compounds called polysaccharides. Using advanced genetic analysis, they identified thirteen key genes responsible for making these health-promoting molecules. The study found that a strain called PZH-05 produced the most polysaccharides, and its genes were more active than in other strains. This research helps explain why lion’s mane mushrooms are effective for boosting immunity, fighting cancer, and managing blood sugar.

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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.

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