amino acid metabolism

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 research study examined how Lyophyllum decastes mushrooms develop and accumulate their valuable nutrients and flavor compounds. Scientists found that amino acids and polysaccharides reach their highest levels when the mushroom is mature, ready for harvesting. By analyzing the genes and chemical changes during mushroom growth, researchers identified the specific pathways responsible for producing these beneficial compounds. This knowledge helps improve mushroom cultivation and confirms its value as a healthy functional food.

Cystathionine Gamma-Lyase Regulate Psilocybin Biosynthesis in Gymnopilus dilepis Mushroom via Amino Acid Metabolism Pathways

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Researchers studying the ‘magic mushroom’ Gymnopilus dilepis discovered that a specific enzyme called CTH plays a crucial role in producing psilocybin, the compound with potential antidepressant effects. By blocking this enzyme, they reduced psilocybin production, but adding a related compound called L-cysteine restored it. This finding suggests that controlling amino acid metabolism could help increase psilocybin production for medical use.

Non-Targeted Metabolomics Analysis Reveals Metabolite Profiles Change During Whey Fermentation with Kluyveromyces marxianus

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Scientists fermented whey (a dairy byproduct) using a special yeast called Kluyveromyces marxianus to create a nutrient-rich food. Using advanced analysis, they found that fermentation breaks down large proteins and fats into smaller, more beneficial compounds including amino acids and omega-3 fatty acids. The fermented whey showed significant increases in health-promoting substances that could help reduce inflammation, prevent disease, and improve overall nutrition.

Effects of Rhizopus oligosporus-Mediated Solid-State Fermentation on the Protein Profile and α-Glucosidase Inhibitory Activity of Selenium-Biofortified Soybean Tempeh

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Researchers used a fungus called Rhizopus oligosporus to make selenium-enriched tempeh, a traditional soybean food. The selenium-enriched tempeh had better protein breakdown, higher amino acid levels, and was better at controlling blood sugar than regular tempeh. This research suggests that selenium-biofortified tempeh could be a healthy functional food for people looking to manage blood sugar levels naturally.

Transcriptomic and metabolomic analyses unravel the different pathogenic mechanisms of Ustilaginoidea virens in indica and japonica rice

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Rice is vulnerable to a fungal disease called false smut caused by Ustilaginoidea virens. Scientists found that this fungus attacks different rice varieties in different ways. By studying gene expression and chemical changes in infected rice, they discovered that the fungus uses different molecular pathways to infect indica rice versus japonica rice, explaining why these varieties have different levels of resistance to the disease.

Effects of Rhizopus oligosporus-Mediated Solid-State Fermentation on the Protein Profile and α-Glucosidase Inhibitory Activity of Selenium-Biofortified Soybean Tempeh

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Researchers developed a special tempeh (traditional soybean food) enriched with selenium using a fungus called Rhizopus oligosporus. The selenium-enriched tempeh had improved protein quality with more amino acids and demonstrated strong ability to slow down sugar absorption in the digestive system, similar to diabetes medications. This makes selenium-biofortified tempeh a promising natural functional food for managing blood sugar levels while providing essential selenium nutrients that many people lack.

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.

Transcriptomic profiling revealed important roles of amino acid metabolism in fruiting body formation at different ripening times in Hypsizygus marmoreus

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Researchers studied why the marbled puffball mushroom takes such a long time to produce fruit bodies by analyzing gene expression at different growth stages. They found that genes involved in amino acid processing and lignin breakdown are particularly important during fruiting body formation. By understanding these molecular processes, scientists can potentially develop ways to shorten cultivation time and improve mushroom farming efficiency.

Research Keyword: amino acid metabolism