differential gene expression – Page 2

Antifungal efficacy and mechanisms of Bacillus licheniformis BL06 against Ceratocystis fimbriata

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Researchers discovered that a beneficial bacterium called Bacillus licheniformis BL06 can effectively prevent sweet potato black rot, a fungal disease that causes major crop losses worldwide. When applied to sweet potatoes, this bacterium reduces disease damage by interfering with the fungus’s ability to grow, form spores, and survive. The study reveals that the bacterium works by disrupting the fungus’s cell structure and energy production, making it a promising natural alternative to chemical fungicides.

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

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This research studied how salt concentration affects the production of ochratoxin A, a toxic substance produced by the fungus Aspergillus westerdijkiae that contaminates foods like coffee and grapes. Using advanced genetic analysis, scientists found that moderate salt levels (20 g/L) increase the fungus’s ability to produce this toxin by affecting specific genes. The findings help explain why OTA contamination is more common in salty foods like cured meats and suggest new ways to prevent this contamination and protect food safety.

Transcriptional response of mushrooms to artificial sun exposure

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As climate change causes more trees to die and forest canopies to open up, mushrooms on the forest floor are exposed to more intense sun and heat. Researchers exposed Shiitake mushrooms to artificial sunlight and found that the mushrooms activate protective molecular mechanisms, particularly heat-shock proteins, to cope with the stress. This suggests that mushrooms have built-in defenses against harsh sun exposure, though scientists are not yet sure if these defenses are strong enough to protect mushroom reproduction under real-world climate change conditions.

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

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Researchers discovered that a protein called RttA helps a common fungus called Aspergillus fumigatus resist azole medicines, which are used to treat serious fungal infections. By studying how this protein works and which genes it controls, scientists found that RttA could be a new target for developing better antifungal treatments. The findings are important because azole-resistant fungal infections are becoming more common worldwide and harder to treat.

Transcriptom Analysis of Auricularia auriculla-judae Fruit Body Treated with Gamma Radiation on Mycelium

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Researchers studied how the wood ear mushroom (Auricularia auricula-judae) responds to gamma radiation at the genetic level. They found that when exposed to radiation, the mushroom activates DNA repair mechanisms and eliminates damaged cells through cell death, rather than relying on antioxidant defenses like some other fungi. This research helps us understand how edible mushrooms naturally protect themselves from radiation damage.

Aspergillus terreus sectorization: a morphological phenomenon shedding light on amphotericin B resistance mechanism

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When Aspergillus terreus fungi are grown in laboratory conditions for extended periods, they sometimes undergo changes that make them look different and behave differently. Scientists found that these changed strains become more susceptible to amphotericin B, a common antifungal drug. By studying the genes and proteins in both the original and changed strains, researchers discovered that special proteins called P-type ATPases appear to be responsible for the fungus’s natural resistance to this drug, offering new targets for developing better antifungal treatments.

Omics approaches to investigate pre-symbiotic responses of the mycorrhizal fungus Tulasnella sp. SV6 to the orchid host Serapias vomeracea

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This study examines how a fungus called Tulasnella responds to orchids before they physically touch each other. Researchers grew the fungus near young orchid plants separated by a thin membrane and found that the fungus changed its genes and chemistry significantly, suggesting it somehow detected the orchid’s presence. The fungus increased production of proteins and fats, as if preparing for a partnership with the plant. These findings help us understand how plants and fungi communicate and begin their beneficial relationships.

UV-Induced Mutants of Metarhizium anisopliae: Improved Biological Parameters, Resistance to Stressful Factors, and Comparative Transcriptomic Analysis

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Scientists used UV light to create improved mutant strains of a fungus that naturally kills insect pests. The best mutant strain showed increased ability to survive harsh environmental conditions like heat and oxidative stress, while becoming more effective at infecting target pest insects. This improvement makes the fungus more practical for use as a natural pesticide in fields exposed to sunlight. Gene analysis revealed the mutant fungi enhanced certain protective proteins while reducing reliance on traditional antioxidant systems.

Inhibitory Effect and Mechanism of Dryocrassin ABBA Against Fusarium oxysporum

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Researchers found that dryocrassin ABBA, a compound from a traditional East Asian fern, can effectively kill the fungus that causes potato rot disease. The compound damages the fungus by increasing harmful reactive oxygen species and disrupting the fungus’s ability to break down plant cell walls. This natural substance could potentially replace synthetic chemical fungicides, offering a safer and more environmentally friendly way to protect potatoes from disease.

Transcriptomic and metabolomic analyses unravel the different pathogenic mechanisms of Ustilaginoidea virens in indica and japonica rice

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Rice is vulnerable to a fungal disease called false smut caused by Ustilaginoidea virens. Scientists found that this fungus attacks different rice varieties in different ways. By studying gene expression and chemical changes in infected rice, they discovered that the fungus uses different molecular pathways to infect indica rice versus japonica rice, explaining why these varieties have different levels of resistance to the disease.

Research Keyword: differential gene expression