KEGG pathway analysis – Page 2

In vitro and in vivo inhibitory effects and transcriptional reactions of graphene oxide on Verticillium dahliae

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Scientists discovered that graphene oxide, a nanomaterial, can effectively kill or inhibit the growth of Verticillium dahliae, a harmful fungus that causes wilt disease in cotton and other crops. The graphene oxide works by damaging the fungus’s cell membranes and disrupting its ability to grow and spread. When applied to cotton plants infected with this fungus, graphene oxide treatment reduced disease symptoms and prevented the fungus from multiplying. This research suggests graphene oxide could become a valuable alternative to chemical fungicides for controlling this destructive plant disease.

Local Fungi Promote Plant Growth by Positively Affecting Rhizosphere Metabolites to Drive Beneficial Microbial Assembly

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Researchers tested local fungal species from the Qinghai-Tibet Plateau to help plants grow in damaged mining areas at extremely high altitudes. The local fungi were more effective than commercial bacterial products at promoting plant growth and creating healthy soil microbiomes. These fungi work by producing special chemicals that attract beneficial microorganisms while preventing harmful fungi from growing, making them ideal for restoring ecosystems in cold, high-altitude mining regions.

Genetic Ablation of the Conidiogenesis Regulator Enhances Mycoprotein Production

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Researchers created genetically modified versions of a fungus (Fusarium venenatum) used to make mycoprotein, a meat alternative. By removing a gene controlling spore formation, they increased fungal growth by 22%, which could significantly reduce production costs. The modified fungus also contained more amino acids and showed no safety concerns in lab tests, making it a promising advancement for sustainable food production.

Comparative metabolic profiling of the mycelium and fermentation broth of Penicillium restrictum from Peucedanum praeruptorum rhizosphere

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Researchers studied a fungus called Penicillium restrictum found in the roots of QianHu, a traditional Chinese medicine plant. Using advanced chemical analysis, they discovered that this fungus produces important medicinal compounds called coumarins, with peak production around day 4 of growth. The fungus appears to produce even more types of these beneficial compounds than the plant itself, suggesting it could be used to manufacture these medicines more efficiently.

Transcriptome and Metabolome Integration Reveals the Impact of Fungal Elicitors on Triterpene Accumulation in Sanghuangporus sanghuang

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Researchers studied how special fungal compounds called elicitors can boost the production of healing substances in a medicinal mushroom called Sanghuangporus sanghuang. By analyzing genes and metabolites, they found that adding elicitors increased beneficial compounds like betulinic acid and 2-hydroxyoleanolic acid by up to 114-fold. These findings suggest a practical way to produce more medicinal compounds from this mushroom for health applications.

Transcriptome and metabolome profiling reveal the inhibitory effects of food preservatives on pathogenic fungi

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This research tested three common food preservatives to see how well they stop harmful molds from growing on fruits and vegetables. Scientists found that all three preservatives worked well at different concentrations, with sec-butylamine being particularly effective. By studying the genes and chemical changes in treated fungal cells, they discovered that these preservatives work by damaging the mold’s cell walls and disrupting how it processes sugars, essentially starving and weakening the fungal cells.

Transcriptome Reveals the Key Genes Related to the Metabolism of Volatile Sulfur-Containing Compounds in Lentinula edodes Mycelium

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Researchers studied how shiitake mushroom mycelium develops its characteristic sulfur-containing flavor during early growth stages. They found that the first 15 days of mycelial growth produce the most volatile flavor compounds, similar to those found in mature mushrooms. Using advanced genetic analysis and computer modeling, they identified two key genes (Leggt3 and Lecsl3) responsible for producing these flavor compounds. This research suggests that mushroom mycelium could be cultivated as an efficient source for producing shiitake flavor compounds for use in food additives and flavorings.

Transcriptomic Profiling of Thermotolerant Sarcomyxa edulis PQ650759 Reveals the Key Genes and Pathways During Fruiting Body Formation

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Researchers studied how a special strain of Sarcomyxa edulis (a tasty edible mushroom from Northeast China) develops fruiting bodies by analyzing which genes are turned on and off during this process. By comparing immature mycelium with developing fruiting bodies, they identified key genes responsible for cell division, DNA repair, and energy metabolism that control fruiting body formation. This knowledge can help mushroom farmers improve yield and quality through better understanding of how mushrooms grow. The findings provide a foundation for developing better cultivation techniques and selecting superior mushroom strains for commercial production.

Modulating effects of Phellinus linteus polysaccharides on antioxidant capacity, immune function, intestinal function and microbiota in lipopolysaccharide-challenged broilers

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Researchers studied how a medicinal mushroom extract called Phellinus linteus polysaccharides could help broiler chickens recover from immune stress caused by bacterial toxins. The supplement improved the chickens’ growth, reduced harmful inflammatory responses, and promoted beneficial gut bacteria while reducing harmful ones. The treatment strengthened the intestinal barrier and restored the chickens’ natural antioxidant defenses. This suggests the mushroom supplement could be a natural alternative to antibiotics for improving poultry health on farms.

Epigenome-wide association study of BMI and waist-to-hip ratio and their associations with dietary patterns in Korean adults

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This research examined how different types of obesity (overall body weight versus belly fat) are associated with changes in DNA methylation patterns in Korean adults. The study found that certain DNA regions become less methylated in obese individuals, and that these epigenetic changes are linked to different dietary patterns. The findings suggest that specific foods may influence these epigenetic modifications differently depending on whether someone has overall obesity or more belly fat, opening new possibilities for using diet to prevent or manage obesity.

Research Keyword: KEGG pathway analysis