plant pathogen – Page 2

Complete genome sequence analysis of Boeremia exigua, a fungal pathogen causing leaf spot disease of Panax notoginseng

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Panax notoginseng, a valuable traditional Chinese medicinal plant, has been affected by a fungal leaf spot disease caused by Boeremia exigua. Researchers sequenced the complete genome of this fungal pathogen for the first time, discovering important genes responsible for its ability to infect plants, including enzymes that break down plant cell walls and proteins that help it evade plant defenses. This genetic information provides a foundation for developing better strategies to protect these valuable medicinal plants from disease.

Hidden treasures of herbaria – even small collections contain a wealth of diversity: the powdery mildews of the North Carolina State Larry F. Grand Mycological Herbarium

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This study examined a collection of powdery mildew fungi preserved in a university herbarium and used DNA analysis to identify which specimens had been misidentified over the years. The researchers found that about 83% of the specimens had incorrect identifications and discovered four completely new species that look very similar to known species but are genetically distinct. The findings show that old museum collections are valuable resources for discovering hidden biodiversity and that we should preserve these collections rather than discard them.

Inhibitory Effects and Mechanisms of Perilla Essential Oil and Perillaldehyde against Chestnut Pathogen Botryosphaeria dothidea

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Chestnuts often rot during storage due to fungal infection. This study found that oil extracted from perilla leaves, particularly a compound called perillaldehyde, effectively prevents the fungus Botryosphaeria dothidea from growing. The antifungal compounds work by breaking down the protective layers of the fungal cells, causing them to leak and die. When applied to stored chestnuts, this natural oil significantly extends their shelf life without harming human health.

Saprotrophic Arachnopeziza Species as New Resources to Study the Obligate Biotrophic Lifestyle of Powdery Mildew Fungi

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Scientists have created a new way to study powdery mildew fungus, which causes widespread plant disease but cannot normally be studied in the laboratory. They identified a related fungus species (Arachnopeziza) that can grow in culture and can be genetically modified. By sequencing the DNA of these two Arachnopeziza species and developing methods to alter their genes, researchers have created a practical tool to understand how powdery mildew becomes dependent on its plant host, potentially leading to better disease control strategies.

First Report of Fusarium avenaceum Causing Blight on Juniperus formosana in China: Morphological and Molecular Characterization

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Juniperus formosana is a beautiful ornamental plant used in landscaping. In October 2024, researchers discovered that a fungus called Fusarium avenaceum was causing a blight disease on these plants in Kaili City, China, making the needles turn yellow and wither. Through detailed examination of the fungus under a microscope and DNA testing, scientists confirmed this is the first time this particular fungus has been found causing this disease on Juniperus formosana in China.

Bacillus subtilis ED24 Controls Fusarium culmorum in Wheat Through Bioactive Metabolite Secretion and Modulation of Rhizosphere Microbiome

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A beneficial bacteria called Bacillus subtilis ED24 was found to effectively protect wheat plants from a destructive fungal disease called Fusarium culmorum. When applied to wheat seeds, this bacteria improved seed germination and plant growth better than a commercial chemical fungicide, while also promoting helpful microorganisms in the soil around the plant roots. The bacteria works by producing special chemical compounds that kill the harmful fungus and by enriching the soil microbiome with beneficial organisms.

Exploring fungal pathogens to control the plant invasive Rubus niveus on Galapagos Island San Cristobal

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Hill raspberry is a highly invasive plant that has taken over approximately 30,000 hectares of the Galapagos Islands, threatening native plant species. Traditional control methods like manual removal and herbicide spraying are expensive and ineffective. Researchers identified five species of fungal pathogens that naturally occur on infected Hill raspberry plants and can cause disease on healthy plants, offering promise as biological control agents to suppress this invasive species.

Genome resource of Phlyctema vagabunda strain 19EL15, a pathogen of post-harvest bull’s eye rot of apple

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Scientists sequenced the complete genetic blueprint of a fungus called Phlyctema vagabunda that causes serious damage to apples and pears after harvest, particularly creating brown spots called bull’s eye rot. The fungus is found across Europe and North America and costs farmers significant money in crop losses. This genetic information will help researchers better understand how the fungus works and develop better ways to prevent or manage the disease.

Complete genome sequence of Diaporthe vaccinii Shear, a fungal isolated from blueberry

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Scientists have sequenced the complete genetic blueprint of a fungus called Diaporthe vaccinii that causes serious disease in blueberry plants. Using advanced DNA sequencing technology, they created a high-quality map of the fungus’s 60.2 million base pair genome. This genetic information will help researchers understand how the fungus causes disease and potentially develop better ways to protect blueberry crops from this costly plant pathogen.

Inhibition of RNase to Attenuate Fungal-Manipulated Rhizosphere Microbiome and Diseases

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Fusarium fungi cause major crop diseases by using a protein called Fg12 that kills helpful bacteria in plant roots, making it easier for the fungus to infect crops. Scientists discovered that a compound called GMP blocks Fg12’s harmful activity and restores beneficial bacteria, reducing disease symptoms in soybeans and alfalfa by 47-75%. This discovery offers a new chemical strategy to protect crops from fungal infections by disarming this key fungal weapon.

Research Keyword: plant pathogen