Volvariella volvacea – Page 2

Proteins from Edible Mushrooms: Nutritional Role and Contribution to Well-Being

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Mushrooms are nutritional powerhouses containing as much high-quality protein as meat and soybeans, with complete amino acid profiles needed for human health. Beyond basic nutrition, mushroom proteins possess remarkable healing properties including anti-cancer, immune-boosting, and blood pressure-lowering effects. These sustainable proteins are increasingly used in food fortification, sports supplements, and therapeutic medicines. Growing mushrooms as mycelium or using novel cultivation methods makes protein production faster, more efficient, and environmentally friendly.

Harnessing the Nutritional Value, Therapeutic Applications, and Environmental Impact of Mushrooms

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Mushrooms are nutritional powerhouses packed with proteins, vitamins, minerals, and special compounds that fight disease. They can help prevent and manage serious conditions like cancer, heart disease, and diabetes while supporting overall health and immunity. Beyond the kitchen, mushrooms are being developed into medicines and cosmetic products. Growing and using mushrooms also helps the environment by creating sustainable alternatives to traditional medicines and animal feeds.

Edible Mushrooms as Functional Ingredients for Development of Healthier and More Sustainable Muscle Foods: A Flexitarian Approach

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This comprehensive review explains how edible mushrooms can be added to meat and fish products to make them healthier and more environmentally friendly. Mushrooms are rich in protein, fiber, vitamins, and natural compounds that fight disease and prevent spoilage. By replacing part of the meat with mushrooms, food makers can create products with better nutrition, longer shelf-life, and reduced salt content, while supporting those pursuing flexitarian diets.

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.

Effects of Ganoderma lucidum Powder on the Growth Performance, Immune Organ Weights, Cecal Microbiology, Serum Immunoglobulins, and Tibia Minerals of Broiler Chickens

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Researchers tested whether powdered Ganoderma lucidum mushroom could replace antibiotic growth promoters in chicken farming. The study found that adding 0.2% mushroom powder to chicken feed improved weight gain and feed efficiency similar to antibiotics, while also promoting beneficial gut bacteria. The mushroom powder was safe and did not cause any disease, making it a promising natural alternative to antibiotics in poultry production.

Immune regulatory functions of biologically active proteins from edible fungi

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This research compared how proteins from 22 different edible mushrooms affect immune system cells called macrophages. The study found that all the mushroom proteins tested boosted immune function by making macrophages more active and productive. Interestingly, expensive rare mushrooms like cordyceps and ganoderma lucidum had stronger immune-boosting effects than common grocery store mushrooms like oyster and button mushrooms.

Exploring the Critical Environmental Optima and Biotechnological Prospects of Fungal Fruiting Bodies

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Fungal fruiting bodies like mushrooms develop best within specific environmental ranges, including proper temperature (15-27°C), humidity (80-95%), light, and nutrients. This comprehensive review identifies the exact environmental ‘sweet spots’ where mushrooms thrive and explains the biotechnological applications of these fungi in medicine, food production, and environmental cleanup. The research provides practical guidance for commercial mushroom cultivation and discusses how genetic engineering could further improve production.

Adaptive Changes and Genetic Mechanisms in Organisms Under Controlled Conditions: A Review

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Organisms adapt to their environments through changes in their genes and how genes are expressed, processes that can happen over many generations even in laboratory settings. Scientists study these adaptations in fungi, insects, and plants grown under controlled conditions to understand how evolution works over shorter timeframes. The research shows that both genetic mutations and modifications to how genes work (without changing DNA itself) drive these adaptive changes. Understanding these mechanisms helps scientists improve crop productivity, develop disease resistance, and address environmental challenges like climate change.

Green-Synthesized Nanomaterials from Edible and Medicinal Mushrooms: A Sustainable Strategy Against Antimicrobial Resistance

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Scientists are developing a new weapon against antibiotic-resistant bacteria using mushrooms. These special nanoparticles derived from edible and medicinal mushrooms can kill harmful bacteria in multiple ways without the toxic chemicals used in traditional manufacturing. The nanoparticles work by disrupting bacterial membranes, creating harmful molecules called free radicals, and even boosting your body’s natural immune response. This environmentally friendly approach could become an important tool in fighting dangerous infections that don’t respond to current antibiotics.

Integrated Transcriptomics and Metabolomics Provide Insight into Degeneration-Related Molecular Mechanisms of Morchella importuna During Repeated Subculturing

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Morel mushrooms are prized edible fungi that unfortunately degrade when repeatedly cultured in the laboratory, becoming slower-growing and less productive. Researchers used advanced genetic and chemical analysis to discover that degeneration occurs when the mushroom stops producing flavonoids, natural antioxidants that protect cells from damage. A specific gene called NR-PKS is responsible for making these protective flavonoids, and it shuts down in degraded strains. The study suggests that preservation methods using cold storage or adding antioxidants could help maintain healthy, productive morel cultures.

Fungal Species: Volvariella volvacea