postharvest disease – mycolab.ai

Identification, Characterization, Pathogenicity, and Fungicide Sensitivity of Postharvest Fungal Diseases in Culinary Melon from Northern Thailand

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Researchers in Thailand identified four different fungi causing diseases in culinary melons after harvest. They found that three fungus species cause damage to stored melon fruits, significantly reducing their quality and value. By testing various fungicides, they determined which chemical treatments effectively stop each fungus type, helping farmers protect their crops and reduce losses.

Effects of Thifluzamide Treatment on the Production of Cell Wall Degrading Enzymes in Rhizoctonia solani and Phenylpropane Metabolism in Pear Fruit

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A new fungicide called thifluzamide was tested on pear fruits infected with a fungus that causes rot. The fungicide works in two ways: it stops the fungus from producing enzymes that break down plant cell walls, and it boosts the pear’s natural defense system by increasing protective compounds like flavonoids and phenolic acids. This dual action makes thifluzamide a promising treatment for preventing fruit rot during storage and transport.

Context-Dependent Fitness Trade-Offs in Penicillium expansum Isolates Resistant to Multiple Postharvest Fungicides

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This research examines how apples and pears get a fungal disease called blue mold and how the fungus develops resistance to commonly used fungicides. Scientists tested fungus samples that resist different fungicides to see if this resistance makes them weaker. They found that resistant fungus strains do struggle more under stressful laboratory conditions, but remain dangerous during long-term cold storage of fruit, especially when fungicides are present.

Transcriptome Analysis of Dimethyl Fumarate Inhibiting the Growth of Aspergillus carbonarius

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Researchers studied how a chemical called dimethyl fumarate stops the growth of a dangerous fungus (Aspergillus carbonarius) that damages grapes and produces a toxin called ochratoxin A. By analyzing which genes were turned on and off when the fungus was exposed to this chemical, they found that it works by damaging the fungus’s cell walls and disrupting its normal development. This discovery could help protect fruit crops and food safety by providing a natural and non-toxic way to prevent mold growth.

Isolation and Identification of Postharvest Rot Pathogens in Citrus × tangelo and Their Potential Inhibition with Acidic Electrolyzed Water

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Tangelo fruits suffer from fungal rot during storage caused primarily by two fungi: Penicillium citrinum and Aspergillus sydowii. Researchers tested acidic electrolyzed water (AEW), a safe and environmentally friendly treatment, and found it effectively kills these fungi by damaging their cell membranes and causing them to leak their contents. This treatment could replace harmful chemical fungicides while keeping tangelo fruits fresh and safe for consumers.

Study on the inhibitory mechanism of fig leaf extract against postharvest Fusarium in melon

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Researchers discovered that fig leaves contain natural compounds that can prevent fruit rot caused by Fusarium fungus in melons. When applied to infected melons, the fig leaf extract kills the fungus by damaging its cell membranes and overwhelming it with harmful molecules called reactive oxygen species. This natural treatment could replace chemical fungicides that harm the environment and leave residues on food, offering a safer way to preserve melons during transport and storage.

Essential Oils as an Antifungal Alternative to Control Several Species of Fungi Isolated from Musa paradisiaca: Part II

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This research tested six common culinary essential oils to see if they could prevent fungi from growing on bananas after harvest. Scientists identified four types of harmful fungi that cause banana rot and tested how well oregano, rosemary, clove, thyme, cinnamon, and basil oils could stop them. The results showed that cinnamon, clove, and oregano oils were most effective at stopping fungal growth, offering a natural alternative to chemical fungicides that consumers want to avoid.

Metabolic profiling of endophytic fungi acting as antagonists of the banana pathogen Colletotrichum musae

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Scientists found three special fungi living inside rainforest plants in the Philippines that can fight the fungus causing banana rot. These endophytic fungi produce chemical compounds that stop the disease-causing fungus from growing, offering a natural alternative to traditional fungicides. The researchers found that the type of growing medium affects which compounds these fungi produce, and two promising strains could potentially be used to reduce fruit losses during storage and transport.

Terpinen-4-ol triggers autophagy activation and metacaspase-dependent apoptosis against Botrytis cinerea

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Terpinen-4-ol, a natural compound from tea tree oil, effectively kills gray mold fungus that spoils fruits and vegetables after harvest. The compound works by damaging fungal cell membranes, creating harmful reactive molecules inside fungal cells, and triggering the fungal cells’ self-destruction pathways. When tested on tomatoes and strawberries, terpinen-4-ol successfully reduced mold growth and disease spread, suggesting it could be a safe, eco-friendly alternative to chemical fungicides for protecting fresh produce.

Essential Oils as an Antifungal Alternative to Control Several Species of Fungi Isolated from Musa paradisiaca: Part III

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Researchers tested six essential oils from common culinary herbs to control fungal diseases that damage bananas after harvest. Thyme, cinnamon, and oregano oils were most effective at preventing fungal growth at concentrations between 600-1000 parts per million. These natural oils could replace synthetic fungicides in banana storage facilities, providing a safer, more environmentally friendly approach to preserving fruit quality.

Research Keyword: postharvest disease