Sclerotinia sclerotiorum

In Vitro and Field Effectiveness of the Combination of Four Trichoderma spp. Against Sclerotinia sclerotiorum and Its Impact on Potato (Solanum tuberosum L.) Crop Production

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This study tested whether four types of beneficial fungi (Trichoderma species) could control white mold disease on potato plants in Mexico. Both laboratory tests and field trials showed these fungi were very effective at killing the disease pathogen and stopping mold formation. Potatoes treated with the fungal mixture produced higher yields than those treated with chemical fungicides alone, suggesting this natural approach could replace many chemical pesticides.

Control effects and mechanisms of metabolites from Streptomyces ahygroscopicus var. gongzhulingensis strain 769 on sclerotinia rot in sunflowers

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Scientists discovered that a beneficial soil bacterium called Streptomyces can effectively control sunflower rot disease caused by a harmful fungus. When applied to soil or roots, this bacterium reduced disease severity by over 50% and improved plant root health and seed quality. The treatment works by both directly killing the pathogenic fungus and strengthening the plant’s natural defense systems.

Chemical profile and bioactivity of essential oils from five Turkish thyme species against white mold fungal disease agent Sclerotinia sclerotiorum

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Researchers tested essential oils from five different thyme species grown in Turkey against a common plant fungus that causes white mold disease. They found that oils rich in carvacrol, particularly from Thymbra spicata and Satureja cilicica, were very effective at stopping fungal growth. These natural oils could be used as environmentally friendly alternatives to chemical pesticides in farming.

Xylem Sap Mycobiota in Grapevine Naturally Infected with Xylella fastidiosa: A Case Study: Interaction of Xylella fastidiosa with Sclerotinia sclerotiorum

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Researchers studied the fungi living inside grapevine water-conducting tissues in Mallorca, Spain, where a bacterial disease called Pierce’s disease is spreading. They found both helpful and harmful fungi living alongside the disease-causing bacteria. When they tested what happens when both the bacteria and a fungal pathogen infect grapevines together in controlled conditions, the plants became much more severely damaged than with either pathogen alone, suggesting these microorganisms work together to harm the plant.

Putative Transcriptional Regulation of HaWRKY33-AOA251SVV7 Complex-Mediated Sunflower Head Rot by Transcriptomics and Proteomics

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Sunflower head rot caused by a fungus is a major problem for farmers worldwide. Scientists studied how sunflower plants defend themselves against this fungus by examining a special protein called HaWRKY33. They found that this protein works with another protein (AOA251SVV7) to help sunflowers resist the disease. By identifying the specific parts of these proteins that are important for fighting off the fungus, researchers have provided tools for developing sunflower varieties that are naturally resistant to this damaging disease.

Research Keyword: Sclerotinia sclerotiorum

In Vitro and Field Effectiveness of the Combination of Four Trichoderma spp. Against Sclerotinia sclerotiorum and Its Impact on Potato (Solanum tuberosum L.) Crop Production

Control effects and mechanisms of metabolites from Streptomyces ahygroscopicus var. gongzhulingensis strain 769 on sclerotinia rot in sunflowers

Chemical profile and bioactivity of essential oils from five Turkish thyme species against white mold fungal disease agent Sclerotinia sclerotiorum

Xylem Sap Mycobiota in Grapevine Naturally Infected with Xylella fastidiosa: A Case Study: Interaction of Xylella fastidiosa with Sclerotinia sclerotiorum

Putative Transcriptional Regulation of HaWRKY33-AOA251SVV7 Complex-Mediated Sunflower Head Rot by Transcriptomics and Proteomics