Anti-inflammatory activity

Exploring the Therapeutic Potential of Ganoderma lucidum in Cancer

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Ganoderma lucidum, a mushroom used in traditional medicine for thousands of years, shows promise in fighting certain blood cancers like leukemia and lymphoma. The mushroom contains special compounds that can kill cancer cells in multiple ways—by triggering cancer cell death, boosting the immune system, and preventing cancer cell growth. While laboratory studies are very encouraging, more testing in humans is needed before it can be used as a standard cancer treatment.

The Anticancer Potential of Edible Mushrooms: A Review of Selected Species from Roztocze, Poland

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This review examines edible mushrooms found in Poland’s Roztocze region for their potential to fight cancer. These mushrooms contain natural compounds like polysaccharides and proteins that can kill cancer cells in laboratory studies through various mechanisms, including triggering cell death and boosting immune function. While promising, these findings from laboratory and animal studies need further development before becoming clinical treatments.

Characterization of Homeodomain Proteins at the Aβ Sublocus in Schizophyllum commune and Their Role in Sexual Compatibility and Development

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This study reveals how a split-gill mushroom called Schizophyllum commune controls its sexual reproduction and fruiting body development through specific protein interactions. Scientists identified four key proteins at a genetic locus that work together in pairs to enable sexual compatibility between different mushroom strains. Understanding these genetic mechanisms helps create improved varieties of this edible and medicinal mushroom with better nutritional and pharmaceutical properties.

Mechanism Underlying Ganoderma lucidum Polysaccharide Biosynthesis Regulation by the β-1,3-Glucosyltransferase Gene gl20535

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Researchers studied a gene called gl20535 in the medicinal mushroom Ganoderma lucidum that controls how the fungus makes beneficial polysaccharides. When they increased this gene’s activity, the mushroom produced significantly more polysaccharides with improved composition. The gene works by controlling sugar pathways and related enzyme production, and the mushroom compensates when this gene is reduced. These findings could help improve the production of medicinal mushroom products for food and health applications.

Therapeutic Effects of Natural Products on Liver Cancer and Their Potential Mechanisms

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This review examines how natural products from plants, fungi, and marine organisms can help treat liver cancer more safely and effectively than current drugs. These natural compounds work through multiple pathways such as triggering cancer cell death, stopping cell growth, and boosting the immune system. The research found that seven categories of natural products show promise, with sources ranging from ginseng and turmeric to mushrooms and seaweed, offering potential new treatment options that could reduce side effects and drug resistance.

Photoregulation of the biosynthetic activity of fungus Inonotus obliquus using colloidal solutions of biogenic metal nanoparticles and low-intensity laser radiation

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Scientists studied how to enhance the medicinal properties of chaga mushroom using tiny metal particles and laser light. They found that adding silver, iron, or magnesium nanoparticles to growing mushroom cultures increased biomass production. When combined with laser treatment, these nanoparticles dramatically boosted the production of beneficial compounds like polysaccharides, flavonoids, and melanin pigments that have health benefits including antioxidant and immune-boosting properties.

Biodiversity and biological applications of marine actinomycetes—Abu-Qir Bay, Mediterranean Sea, Egypt

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Researchers isolated bacteria called actinomycetes from the Mediterranean Sea in Egypt that naturally produce colorful pigments. They found that one specific bacterium (Streptomyces tunisiensis) produces a green pigment with promising anti-inflammatory properties similar to common pain relievers. By optimizing the growth conditions, the scientists increased pigment production by over 12 times, suggesting potential applications in medicine and industry.

Deciphering the formation of biogenic nanoparticles and their protein corona: State-of-the-art and analytical challenges

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Scientists have developed environmentally friendly methods to create tiny metal particles (nanoparticles) using living organisms like bacteria, fungi, and plants instead of toxic chemicals. These bioengineered nanoparticles are coated with natural biological molecules that make them safer and more stable. This review explains how these particles are made, what analytical tools scientists use to study them, and their potential uses in medicine, environmental cleanup, and agriculture.

The Effect of Supplementing Mushroom Growing Substrates on the Bioactive Compounds, Antimicrobial Activity, and Antioxidant Activity of Pleurotus ostreatus

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This study investigated how adding wheat bran to mushroom growing substrates affects oyster mushroom quality and medicinal properties. The researchers found that wheat bran supplementation increased mushroom yield but slightly decreased antioxidant power, while the mushrooms produced antimicrobial compounds effective against various bacteria and fungi. The mushrooms contained beneficial compounds like vitamin E and phenols, suggesting they could be developed as natural alternatives to synthetic antibiotics.

Nanoencapsulation of Biotics: Feasibility to Enhance Stability and Delivery for Improved Gut Health

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This review explores how tiny nanoparticles can protect beneficial bacteria and dietary compounds as they travel through the digestive system. These nanotechnologies help probiotics survive stomach acid and reach the intestines where they provide health benefits. The research shows promising results for treating digestive diseases and improving overall gut health through better delivery of microbiota-modulating substances.

therapeutic action: Anti-inflammatory activity