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Mycoses --- Drug development. --- Antifungal agents --- Treatment. --- Therapeutic use.
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Mycoses --- Drug development. --- Antifungal agents --- Treatment. --- Therapeutic use. --- Anti-fungal agents --- Antimycotics --- Fungal inhibitory agents --- Inhibitory agents, Fungal --- Therapeutic fungicides --- Anti-infective agents --- Fungicides --- Development of drugs --- Drugs --- New drug development --- Pharmacology --- Pharmacy --- Fungal diseases --- Fungal infections --- Fungous diseases --- Mycosis --- Mycotic diseases --- Mycotic infections --- Medical mycology --- Development
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Mycoses. --- Veterinary mycology. --- Fungous diseases in animals --- Medical mycology --- Veterinary microbiology --- Fungal diseases --- Fungal infections --- Fungous diseases --- Mycosis --- Mycotic diseases --- Mycotic infections --- Micosi --- Micologia veterinària --- Malalties fúngiques en els animals --- Micologia animal --- Microbiologia veterinària --- Infeccions fúngiques --- Infeccions produïdes per fongs --- Malalties fúngiques en l'home --- Malalties produïdes per fongs --- Malalties infeccioses --- Aspergil·losi --- Candidiasi --- Dermatomicosi --- Fongs patògens --- Medicaments antifúngics --- Micologia mèdica
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Although many insects successfully live in dangerous environments exposed to diverse communities of microbes, they are often exploited and killed by specialist pathogens. In the process of the co-evolution of insects and entomopathogenic microorganisms, they develop various adaptive systems that determine the sustainable existence of dynamic host–parasite interactions at both the organismic and population levels.
field production --- sustainable management --- pest control --- soil properties --- microbial community --- biological activity --- soil DNA analyses --- α-cypermethrin --- insects --- mycoses --- spontaneous bacterioses --- fungal–bacteria interactions --- Cordyceps militaris --- antimicrobial peptides --- Woronin body --- conidiation --- stress response --- appressorium formation --- virulence --- Metarhizium robertsii --- mycotoxins --- entomopathogen --- arthropods --- CYP450 --- gut-histology --- non-toxicity --- nematophagous fungi --- cross-kingdom interactions --- food-web cycling --- phytophagous nematodes --- soilborne fungal pathogens --- entomopathogenic fungi --- resistant triatomines --- biological control --- bassianolide --- beauvericin --- limpet --- dual gene expression --- genomics --- host defense --- immunity --- next generation sequencing --- transcriptome --- two-spotted field crickets --- immune defense --- immunocompetence --- pathogens --- sex --- Tenebrio molitor --- Buxus --- invasive pests --- alkaloids --- antimicrobial activity --- Geometridae --- Hypocreales --- mortality --- moth --- larva --- pupa --- Chilo suppressalis --- isolation --- identification --- pathogenicity --- n/a --- fungal-bacteria interactions
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Although many insects successfully live in dangerous environments exposed to diverse communities of microbes, they are often exploited and killed by specialist pathogens. In the process of the co-evolution of insects and entomopathogenic microorganisms, they develop various adaptive systems that determine the sustainable existence of dynamic host–parasite interactions at both the organismic and population levels.
Research & information: general --- field production --- sustainable management --- pest control --- soil properties --- microbial community --- biological activity --- soil DNA analyses --- α-cypermethrin --- insects --- mycoses --- spontaneous bacterioses --- fungal-bacteria interactions --- Cordyceps militaris --- antimicrobial peptides --- Woronin body --- conidiation --- stress response --- appressorium formation --- virulence --- Metarhizium robertsii --- mycotoxins --- entomopathogen --- arthropods --- CYP450 --- gut-histology --- non-toxicity --- nematophagous fungi --- cross-kingdom interactions --- food-web cycling --- phytophagous nematodes --- soilborne fungal pathogens --- entomopathogenic fungi --- resistant triatomines --- biological control --- bassianolide --- beauvericin --- limpet --- dual gene expression --- genomics --- host defense --- immunity --- next generation sequencing --- transcriptome --- two-spotted field crickets --- immune defense --- immunocompetence --- pathogens --- sex --- Tenebrio molitor --- Buxus --- invasive pests --- alkaloids --- antimicrobial activity --- Geometridae --- Hypocreales --- mortality --- moth --- larva --- pupa --- Chilo suppressalis --- isolation --- identification --- pathogenicity --- field production --- sustainable management --- pest control --- soil properties --- microbial community --- biological activity --- soil DNA analyses --- α-cypermethrin --- insects --- mycoses --- spontaneous bacterioses --- fungal-bacteria interactions --- Cordyceps militaris --- antimicrobial peptides --- Woronin body --- conidiation --- stress response --- appressorium formation --- virulence --- Metarhizium robertsii --- mycotoxins --- entomopathogen --- arthropods --- CYP450 --- gut-histology --- non-toxicity --- nematophagous fungi --- cross-kingdom interactions --- food-web cycling --- phytophagous nematodes --- soilborne fungal pathogens --- entomopathogenic fungi --- resistant triatomines --- biological control --- bassianolide --- beauvericin --- limpet --- dual gene expression --- genomics --- host defense --- immunity --- next generation sequencing --- transcriptome --- two-spotted field crickets --- immune defense --- immunocompetence --- pathogens --- sex --- Tenebrio molitor --- Buxus --- invasive pests --- alkaloids --- antimicrobial activity --- Geometridae --- Hypocreales --- mortality --- moth --- larva --- pupa --- Chilo suppressalis --- isolation --- identification --- pathogenicity
Choose an application
Although many insects successfully live in dangerous environments exposed to diverse communities of microbes, they are often exploited and killed by specialist pathogens. In the process of the co-evolution of insects and entomopathogenic microorganisms, they develop various adaptive systems that determine the sustainable existence of dynamic host–parasite interactions at both the organismic and population levels.
Research & information: general --- field production --- sustainable management --- pest control --- soil properties --- microbial community --- biological activity --- soil DNA analyses --- α-cypermethrin --- insects --- mycoses --- spontaneous bacterioses --- fungal–bacteria interactions --- Cordyceps militaris --- antimicrobial peptides --- Woronin body --- conidiation --- stress response --- appressorium formation --- virulence --- Metarhizium robertsii --- mycotoxins --- entomopathogen --- arthropods --- CYP450 --- gut-histology --- non-toxicity --- nematophagous fungi --- cross-kingdom interactions --- food-web cycling --- phytophagous nematodes --- soilborne fungal pathogens --- entomopathogenic fungi --- resistant triatomines --- biological control --- bassianolide --- beauvericin --- limpet --- dual gene expression --- genomics --- host defense --- immunity --- next generation sequencing --- transcriptome --- two-spotted field crickets --- immune defense --- immunocompetence --- pathogens --- sex --- Tenebrio molitor --- Buxus --- invasive pests --- alkaloids --- antimicrobial activity --- Geometridae --- Hypocreales --- mortality --- moth --- larva --- pupa --- Chilo suppressalis --- isolation --- identification --- pathogenicity --- n/a --- fungal-bacteria interactions
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