Genomics – Page 2 – mycolab.ai

Whole genome sequencing and annotations of Trametes sanguinea ZHSJ

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Scientists have completely mapped the genetic code of Trametes sanguinea, a medicinal mushroom used in traditional Chinese medicine. They identified over 10,000 genes and analyzed how this mushroom produces compounds that fight tumors, boost immunity, protect the heart, and fight viruses. This genetic map will help researchers understand how to produce these beneficial compounds and develop new medicines from this mushroom.

Genetic variation among progeny shapes symbiosis in a basidiomycete with poplar

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This research examines how different genetic variations within a single fungal species affect its ability to form beneficial partnerships with poplar tree roots. Scientists studied 40 genetically distinct fungal strains derived from the same parent and found that they varied greatly in their success at colonizing tree roots, ranging from complete failure to excellent colonization. By analyzing the genes and gene expression of these strains, the team identified specific genetic regions that influence symbiosis formation and discovered that genetic diversity within this fungal species plays an important role in how effectively forest ecosystems function.

Research on the Action and Mechanism of Pharmacological Components of Omphalia lapidescens

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Omphalia lapidescens, a medicinal fungus used in traditional Chinese medicine, contains multiple bioactive compounds with promising health benefits. These compounds can fight parasitic infections, inhibit cancer cell growth, reduce inflammation, and provide antioxidant protection. While clinical use shows benefits especially for gastric cancer when combined with chemotherapy, more research is needed to understand how these compounds work and to improve cultivation and production methods.

Genomic characterization and fermentation study of the endophyte Stemphylium sp. (Aa22), a producer of bioactive alkyl-resorcinols

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Scientists have studied a beneficial fungus called Stemphylium sp. Aa22 that lives inside wormwood plants and produces natural insect-repelling compounds called alkyl-resorcinols. By reading the complete genetic code of this fungus, researchers identified the gene responsible for making these compounds and found that growing the fungus in liquid culture produces more of the desired compounds than growing it on solid rice. This research could lead to developing natural, environmentally-friendly pesticides to protect crops from aphids and other pests.

Revealing the metabolic potential and environmental adaptation of nematophagous fungus, Purpureocillium lilacinum, derived from hadal sediment

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Scientists discovered a special fungus living in the deepest part of the ocean (Mariana Trench) that can survive extreme pressure and produce compounds with disease-fighting properties. This fungus, Purpureocillium lilacinum, showed promise against bacteria, cancer cells, and parasitic worms. The research revealed how this fungus adapts to survive in one of Earth’s most extreme environments, potentially opening new sources for developing medicines and biological pest control.

The endophytic fungus Cosmosporella sp. VM-42 from Vinca minor is a source of bioactive compounds with potent activity against drug-resistant bacteria

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Scientists discovered a fungus living inside a medicinal plant called Vinca minor that produces compounds capable of killing drug-resistant bacteria like MRSA. They isolated the main active compound, nectriapyrone, and found it effectively stops the growth of these dangerous bacteria in laboratory tests. The fungus appears to be a promising source of new antibacterial drugs that could help combat the growing problem of antibiotic-resistant infections.

Activation of Secondary Metabolism and Protease Activity Mechanisms in the Black Koji Mold Aspergillus luchuensis through Coculture with Animal Cells

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Researchers found that growing koji mold (Aspergillus luchuensis) alongside mouse immune cells in the laboratory significantly increases the production of valuable bioactive compounds. The mold releases enzymes called proteases that break down proteins from the animal cells, which the fungus then uses as building blocks to create medicinal compounds. This discovery shows that coculturing microorganisms with animal cells is an effective strategy to unlock hidden chemical production capabilities in fungi, which could lead to new medicines and useful compounds.

Biology and Application of Chaetomium globosum as a Biocontrol Agent: Current Status and Future Prospects

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Chaetomium globosum is a fungus that can protect crops from various plant diseases by producing toxic compounds and parasitizing harmful pathogens. It also helps plants defend themselves naturally and improves soil health by promoting beneficial microorganisms. This makes it a promising alternative to chemical pesticides for sustainable farming, though more research is needed to optimize its effectiveness in real field conditions.

Genomic Insights of Candida krusei, an Emerging Fungal Pathogen With Intrinsic Antifungal Resistance

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Candida krusei is a yeast that causes serious bloodstream infections, particularly in people with weakened immune systems. Unlike many other fungi, it naturally resists common antifungal drugs like fluconazole, making infections hard to treat. The organism can form protective biofilms and has multiple genetic mechanisms that help it survive antifungal treatment. Researchers are exploring new drugs and treatment strategies to combat this growing health threat, especially in hospitals.

Genome Sequencing of Hericium coralloides by a Combination of PacBio RS II and Next-Generation Sequencing Platforms

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Scientists successfully sequenced the complete genome of Hericium coralloides, a medicinal mushroom used in traditional Chinese medicine for treating heart disease, cancer, and stomach problems. Using advanced sequencing technology combining long-read and short-read methods, they assembled the 55 million base pair genome containing over 11,700 genes. This genetic blueprint reveals the mushroom contains genes for producing beneficial enzymes and compounds with therapeutic potential. This milestone opens the door for future research to develop new medicines based on this mushroom’s natural bioactive properties.

Research Keyword: Genomics