gene regulation – Page 2

Fungus-targeted nanomicelles enable microRNA delivery for suppression of virulence in Aspergillus fumigatus as a novel antifungal approach

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Researchers developed a new way to fight dangerous fungal infections caused by Aspergillus fumigatus, which increasingly resists standard antifungal drugs. They used tiny molecules called microRNAs packaged in even tinier delivery vehicles to turn off genes that help the fungus survive. When these microRNAs were introduced, the fungus became much more vulnerable to the body’s immune system and to stress. This novel approach could eventually help treat infections that are otherwise difficult to cure.

Orthrus: a Pumilio-family gene involved in fruiting body and dark stipe development in Coprinopsis cinerea

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Scientists studied a gene called ort2 in mushrooms that controls how fruiting bodies develop, especially the long structures called dark stipes that form in darkness. They found that when this gene is active, mushrooms make more of these elongated forms, while disabling it prevents dark stipe formation. This discovery could help improve mushroom cultivation for species where these elongated forms are commercially valuable.

Expression Profile of Laccase Gene Family in White-Rot Basidiomycete Lentinula edodes under Different Environmental Stresses

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Researchers studied how shiitake mushrooms control 14 different laccase genes in response to environmental changes like temperature, light, and food sources. Laccases are enzymes that help mushrooms break down wood and other tough plant materials. The study found that different genes activate under different conditions, helping the mushroom adapt and develop fruiting bodies efficiently. This research helps improve mushroom cultivation and understanding of how fungi survive in changing environments.

RttA, a Zn2-Cys6 transcription factor in Aspergillus fumigatus, contributes to azole resistance

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Researchers discovered that a fungal protein called RttA plays a key role in helping Aspergillus fumigatus resist azole antifungal drugs. By studying mutant strains, they found that RttA acts as a master switch controlling genes that reduce the effectiveness of antifungal medications. This finding is important because it could help develop new strategies to treat fungal infections that are becoming resistant to current medications.

The Zn(II)2-Cys6-type zinc finger protein AoKap7 is involved in the growth, oxidative stress and kojic acid synthesis in Aspergillus oryzae

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Scientists studied a protein called AoKap7 in a fungus (Aspergillus oryzae) that produces kojic acid, a substance used in cosmetics and medicine. When they removed this protein, the fungus grew faster but made less kojic acid and became more vulnerable to stress. The researchers found that AoKap7 controls several genes that help the fungus protect itself from harmful molecules and produce kojic acid efficiently.

Evolutionary Dynamics and Functional Bifurcation of the C2H2 Gene Family in Basidiomycota

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Researchers studied C2H2 genes, which are master regulators controlling important processes in fungal cells, across 30 different mushroom and fungal species. They found that these genes evolved differently depending on whether fungi were decomposers (saprotrophs) or pathogens, with decomposers maintaining more complex gene structures. During mushroom development in Sarcomyxa edulis, different C2H2 genes became active at different stages, controlling temperature adaptation, fruiting body formation, and other developmental processes.

A Zn2-Cys6 transcription factor, TgZct4, reprograms antioxidant activity in the fungus Trichoderma guizhouense to defend against oxidative stress

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Trichoderma guizhouense is a fungus used to protect plants from harmful pathogens. Researchers discovered that a special protein called TgZct4 acts like a master switch that activates the fungus’s defense system against harmful reactive oxygen molecules. When the fungus encounters stress, TgZct4 turns on genes that produce protective enzymes called catalases and superoxide dismutases, helping the fungus survive. This discovery could help scientists create even more effective biological pest control products.

Transcriptome analysis of Ochratoxin a (OTA) producing Aspergillus westerdijkiae fc-1 under varying osmotic pressure

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A fungus called Aspergillus westerdijkiae produces a toxic substance called Ochratoxin A (OTA) that commonly contaminates foods like coffee, grapes, and wheat. Researchers used advanced gene analysis techniques to understand how salt concentration affects the fungus’s ability to produce this toxin. They found that moderate salt levels actually increase OTA production, while very high salt levels activate defense mechanisms that reduce it. These findings could help develop better strategies to prevent this dangerous contamination in our food supply.

PRMT5 promotes cellulase production by regulating the expression of cellulase gene eg2 through histone methylation in Ganoderma lucidum

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Scientists discovered that a protein called PRMT5 in Ganoderma lucidum mushroom plays a key role in producing cellulase enzymes that break down plant cellulose. By controlling a specific gene (eg2) through a process called histone methylation, PRMT5 increases cellulase production. This finding could help develop more efficient ways to convert agricultural waste like corn straw into useful sugars for biofuels and other industrial products.

Global Analysis of microRNA-like RNAs Reveals Differential Regulation of Pathogenicity and Development in Fusarium oxysporum HS2 Causing Apple Replant Disease

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Apple replant disease is caused by a fungus that damages apple tree roots and reduces fruit production. Researchers discovered that this fungus uses special regulatory molecules called microRNA-like RNAs to control its growth and disease-causing abilities, especially during the spore stage. These findings could help scientists develop new ways to control the disease using RNA-based treatments.

Research Keyword: gene regulation