Cordyceps militaris – Page 3

High-Yield-Related Genes Participate in Mushroom Production

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Scientists have identified specific genes that control how mushrooms grow and produce fruit bodies. By using advanced gene-editing technology like CRISPR-Cas9, researchers can now increase mushroom yields by 20-65%, offering a faster and more efficient alternative to traditional breeding methods. This breakthrough could help meet the world’s growing demand for mushrooms while making farming more sustainable and economical for growers globally.

Triacetin and a Mushroom Blend Restore Butyrate Production by IBS Microbiomes Ex Vivo, Thus Promoting Barrier Integrity

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Researchers tested two natural products—triacetin and a mushroom blend—to see if they could help people with IBS by improving their gut bacteria and strengthening their intestinal lining. Both products successfully increased beneficial short-chain fatty acids and improved barrier integrity, with triacetin having the added advantage of producing less uncomfortable gas. These findings suggest these products could offer a new dietary approach to managing IBS symptoms.

Light-responsive transcription factor CmOzf integrates conidiation, fruiting body development, and secondary metabolism in Cordyceps militaris

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Scientists studied a medicinal fungus called Cordyceps militaris and discovered that a protein called CmOzf acts as a master controller of several important processes. When light shines on the fungus, it activates CmOzf, which helps the fungus produce spores for reproduction through a specific genetic pathway. Interestingly, when CmOzf is blocked, the fungus produces fewer spores but makes more pigments and beneficial compounds. This discovery could help improve the production of medicinal compounds from this fungus and its use as a natural pest control agent.

Fungal Metabolomics: A Comprehensive Approach to Understanding Pathogenesis in Humans and Identifying Potential Therapeutics

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This review explains how scientists use metabolomics—a technique that identifies all chemical compounds in organisms—to understand how fungi cause disease and resist medicines. Fungi produce many different chemicals that help them attack our bodies and survive treatments, but these same chemicals could also be used to create new medicines. By studying these fungal chemicals, researchers can develop better antifungal drugs and understand how fungi manage to evade our immune system.

Optimization of Protoplast Preparation and Establishment of PEG-Mediated Genetic Transformation Method in Cordyceps cicadae

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Scientists successfully developed a method to genetically modify Cordyceps cicadae, a valuable medicinal fungus used in traditional Chinese medicine. By optimizing how to remove the fungus’s protective cell wall and introducing new genes using a technique called PEG-mediated transformation, researchers created a stable system for genetic manipulation. This breakthrough opens the door for improving medicinal compounds in this fungus and advancing its use in treating various health conditions.

Enokitake Mushroom and Its Active Component, Adenosine, Which Restores Testosterone Production in Impaired and Fatigued Mouse Models

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Enokitake mushrooms and their active compound adenosine can boost testosterone production in mice experiencing fatigue and aging-related decline. The study shows that consuming adenosine-rich mushrooms may help restore testicular function and provide anti-aging benefits. This finding suggests that commonly available edible mushrooms like enokitake could be a natural functional food for managing fatigue and age-related hormone decline. However, human studies are needed to confirm these effects.

The Inhibitory Effects of Cordyceps militaris ARA301 Extract on Lipopolysaccharide-Induced Lung Injury in vivo

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Researchers tested a mushroom extract from Cordyceps militaris to see if it could protect mice from lung injury caused by bacterial toxins. The extract successfully reduced inflammation, prevented excessive mucus production, and decreased immune cell buildup in the lungs. These findings suggest that this mushroom extract could potentially be used as a natural supplement to help prevent respiratory diseases and support lung health.

Effect of Cordyceps militaris Residue and Lactiplantibacillus plantarum on Fermentation Quality and Bacterial Community of Alfalfa Silage

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This research shows that waste leftover from growing medicinal mushrooms (Cordyceps militaris) can be effectively reused as an additive to improve the quality of stored animal feed (alfalfa silage). When the mushroom residue was added, it boosted beneficial bacteria that produce lactic acid, which preserved the feed better and reduced ammonia content. This finding offers an environmentally friendly way to reduce waste while simultaneously improving livestock feed quality.

The Potential of Naturally Derived Compounds for Treating Chronic Kidney Disease: A Review of Autophagy and Cellular Senescence

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This review explores how natural products from traditional Chinese medicine may help treat chronic kidney disease by targeting two key aging processes: autophagy (cellular self-cleaning) and cellular senescence (cellular aging). Common natural compounds like curcumin, green tea extract, and Astragalus have shown promise in protecting kidney function and reducing harmful inflammation. While these natural treatments show potential as complementary therapies alongside mainstream medicines, more clinical research is needed to confirm their effectiveness and determine optimal dosages.

Mitochondrial genome characterization, evolution and intron dynamics of the entomopathogenic genus Cordyceps

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This research examined the genetic instruction manuals (mitochondrial DNA) of seven different Cordyceps fungal species. Scientists found that these fungi have varying amounts of genetic material, primarily due to differences in introns—sections that can be inserted or removed from genes. By comparing their genomes, researchers clarified how different Cordyceps species are related to each other evolutionarily, providing better tools for identifying and classifying these medically valuable fungi.

Fungal Species: Cordyceps militaris