fungal pathogenicity

First Record of Clonostachys rosea as an Entomopathogenic Fungus of the Cephus fumipennis (Hymenoptera: Cephidae) in China

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Scientists in China discovered a fungus called Clonostachys rosea that naturally kills wheat stem sawfly larvae, a major pest damaging wheat crops. The fungus was isolated from infected larvae and tested for effectiveness against the pest. Laboratory tests showed the fungus can kill sawfly larvae at different concentrations, with the fastest effect at higher spore levels. This discovery offers a natural and environmentally friendly alternative to chemical pesticides for protecting wheat crops.

The phenol-2-monooxygenase FgPhm1 regulates DON synthesis, pathogenicity and environmental stress response in Fusarium graminearum

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Researchers studied a fungal protein called FgPhm1 in a wheat-infecting fungus that produces harmful toxins called DON. By deleting this gene, they found that the fungus became unable to infect plants and produce toxins, making it less dangerous. The protein also helps the fungus handle stress conditions, and removing it makes the fungus sensitive to oxidative stress while paradoxically tolerant to phenol.

CBC Complex Regulates Hyphal Growth, Sclerotial Quantity, and Pathogenicity in the Necrotrophic Fungus Botrytis cinerea

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Scientists studied how two proteins (BcCbp20 and BcCbp80) work together in gray mold fungus, which destroys crops worldwide. These proteins control how the fungus grows, makes spores, forms long-term survival structures, and causes disease. The findings show that BcCbp80 is more important for growth and infection, while BcCbp20 helps the fungus survive stress. Understanding these proteins could help develop new antifungal treatments.

Genomic insights reveal community structure and phylogenetic associations of endohyphal bacteria and viruses in fungal endophytes

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Fungi living inside healthy plant leaves contain communities of bacteria and viruses. Researchers studied these microbial passengers in fungi from American beech leaves and found that bacteria show patterns of preference for specific fungal types, while viruses are less diverse and mostly DNA-based rather than RNA-based. Understanding these microbial relationships helps explain how fungi interact with plants and could potentially improve biological control strategies.

Optimization of cultural conditions for pectinase production by Diaporthe isolate Z1-1N and its pathogenicity on kiwifruit

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Researchers studied how a fungus called Diaporthe causes soft rot in kiwifruit by producing special enzymes called pectinases that break down the fruit’s cell walls. They found the best conditions for growing these enzymes in the lab: a temperature of 28°C, neutral pH around 7.5, and 2-3 days of growth. When they extracted these pure enzymes and put them on fresh kiwifruit, the enzymes caused damage equivalent to about half the damage caused by the living fungus itself, proving these enzymes are important for disease development.

Structural and functional characterisation and regulatory mechanisms of SWI/SNF and RSC chromatin remodelling complexes in fungi

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This review examines special protein complexes called SWI/SNF and RSC that help fungi control their genes by rearranging DNA packaging. These complexes are important for fungal survival under stress and for causing disease. The researchers compared these complexes across different fungal species and found both similarities and differences that could help scientists develop new antifungal medicines.

Population structure in a fungal human pathogen is potentially linked to pathogenicity

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Researchers studied 300 strains of Aspergillus flavus, a fungus that causes serious infections in people and damages crops. They found that strains causing human infections are not randomly distributed but instead belong to specific genetic groups, particularly a newly identified group called population D. This discovery suggests that certain genetic traits make some strains more likely to infect humans, providing insights that could lead to better treatments and prevention strategies.

Genetic and Genomic Analysis Identifies bcltf1 as the Transcription Factor Coding Gene Mutated in Field Isolate Bc116, Deficient in Light Responses, Differentiation and Pathogenicity in Botrytis cinerea

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Researchers studied a weak strain of gray mold fungus found in Spanish vineyards to understand why it cannot infect plants when exposed to light. Using genetic analysis, they discovered that the weakness is caused by a mutation in a single gene called bcltf1, which normally helps the fungus sense light and decide when to grow or reproduce. By restoring this gene in mutant strains, scientists confirmed its importance for fungal virulence and light responses, providing insights that could eventually help develop better disease control strategies.

Morpho-Molecular Identification and Pathogenic Characterization of Fusarium and Colletotrichum Species Associated with Intercropped Soybean Pod Decay

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This study identified dangerous fungi causing soybean pod decay in Southwestern China’s intercropping farms. Researchers found 8 types of Fusarium and 6 types of Colletotrichum fungi infecting soybean pods, with some species being discovered as soybean pathogens for the first time. Laboratory tests showed that certain species like F. proliferatum and C. fructicola cause severe damage to both soybean pods and seeds, potentially reducing crop yields and seed quality significantly.

Fungal Argonaute proteins act in bidirectional cross-kingdom RNA interference during plant infection

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Scientists discovered that fungi and plants exchange genetic instructions called small RNAs to control each other during infection. A fungal pathogen called Botrytis cinerea uses special proteins called Argonautes to deliver these instructions into plant cells, which helps the fungus cause disease. Plants also send back their own genetic instructions to defend themselves. Understanding these molecular communications could lead to new ways to protect crops from fungal diseases.

Research Keyword: fungal pathogenicity