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Potatoes --- Potatoes --- Solanum tuberosum --- Solanum tuberosum --- Agricultural research --- Agricultural research --- Seedlings --- Seedlings --- Resistance to injurious factors --- Resistance to injurious factors --- Plant viruses --- Plant viruses --- Inoculation --- Inoculation --- Sprayers --- Sprayers --- Potato virus x --- Potato virus y --- Cip --- Research guide --- Potato virus x --- Potato virus y --- Cip --- Research guide
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Potato virus Y (PVY) infects a wide host range mainly within the Solanaceae and is distributed worldwide. PVY is transmitted by more than 40 aphid species in a non persistent manner. Isolates of the PVY species are highly variable at biological, serological and molecular levels. Epidemiological studies have highlighted the emergence of distinct potato PVY variants able to induce necroses on potato tubers. Due to the lack of efficient resistance to PVY isolates inducing necrotic symptoms in cultivated varieties and the plant-to-plant transmission of isolates through the daughter tubers, PVY has become the most economically important virus for the potato industry. The review offers an overview of several decades of research on PVY but also focuses on the latest data obtained by expert on PVY worldwide on the biological characteristics of PVY, interactions between aphids-hosts, its evolution and management. Identified knowledge gaps to understand further PVY biology will be discussed.
Virus diseases. --- Potato virus Y. --- Potato potyvirus Y --- Potato severe mosaic virus --- Potato Y potyvirus --- PVY (Plant virus) --- Viral diseases --- Viral infections --- Virus infections --- Life sciences. --- Virology. --- Agriculture. --- Plant pathology. --- Life Sciences. --- Plant Pathology. --- Communicable diseases --- Medical virology --- Pathogenic viruses --- Potyviruses --- Plant diseases. --- Medical virology. --- Medical microbiology --- Virology --- Virus diseases --- Farming --- Husbandry --- Industrial arts --- Life sciences --- Food supply --- Land use, Rural --- Botany --- Communicable diseases in plants --- Crop diseases --- Crops --- Diseases of plants --- Microbial diseases in plants --- Pathological botany --- Pathology, Vegetable --- Phytopathology --- Plant pathology --- Plants --- Vegetable pathology --- Agricultural pests --- Crop losses --- Diseased plants --- Phytopathogenic microorganisms --- Plant pathologists --- Plant quarantine --- Pathology --- Diseases and pests --- Diseases --- Wounds and injuries --- Microbiology
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Plants possess a rather complex and efficient immune system. During their evolutionary history, plants have developed various defense strategies in order to recognize and distinguishing between self and non-self, and face pathogens and animal pests. Accordingly, to study the plant innate immunity represents a new frontier in the plant pathology and crop protection fields. This book is structured in 6 sections. The first part introduces some basic and general aspects of the plant innate immunity and crop protection. Sections 2–5 focus on fungal and oomycete diseases (section 2), bacterial and phytoplasma diseases (section 3), virus diseases (section 4), and insect pests (section 5), with a number of case studies and plant–pathogen/pest interactions. The last section deals with plant disease detection and control. The book aims to highlight new trends in these relevant areas of plant sciences, providing a global perspective that is useful for future and innovative ideas.
Bakraee --- tomato gray mold --- Citrus sinensis --- CDPKs --- salicylic acid --- calmodulin --- glycerol-3-phosphate --- biotic stress responses --- negative regulator --- rice blast --- metabolomics --- hydroperoxide lyase --- Bromoviridae --- induced defense responses --- leaf transcriptome --- calcium signature --- “Candidatus Liberibacter” --- garden impatiens --- Chilo suppressalis --- plant defence --- plant–virus interactions --- spectral distribution of light --- Magnaporthe oryzae --- plant-virus interaction --- biological control --- ultrastructure --- pathogenicity --- disease resistance --- Potato virus Y --- symbiosis --- N-hydroxypipecolic acid --- VaHAESA --- priming --- plant–microbe interactions --- systemic and local movement --- immunity --- CaWRKY40b --- plant protection products --- hypersensitive response --- cellulose synthase --- herbivore-induced defense response --- Macrosiphum euphorbiae --- RTNLB --- ISR --- RNA silencing --- herbivore-induced plant defenses --- disease management --- sustainable crop protection --- WRKY networks --- Camellia sinensis --- RNA-Seq --- transcriptional modulation --- ETI --- pathogenesis related-protein 2 --- cell wall --- basal defense --- candidate disease resistance gene --- MTI --- grapevine --- defense-related signaling pathways --- wounding --- ethylene --- CMLs --- Prune dwarf virus --- Arabidopsis thaliana --- SAR signalling --- innate immunity --- agrochemicals --- OsGID1 --- Nilaparvata lugens --- tobacco --- tomato leaf mold --- Solanum lycopersicum --- downy mildew --- pipecolic acid --- chemical elicitors --- bismerthiazol --- pre-conditioning --- gibberellin --- “Candidatus Phytoplasma” --- dieback --- CaWRKY22 --- microbiota --- Sogatella furcifera --- PTI --- SAR --- Bacillus subtilis --- PRRs --- aphid resistance --- methyl salicylate --- regurgitant --- Myzus persicae --- Agrobacterium --- Ectropis obliqua --- Capsicum annuum --- polyphenol oxidase --- plant proteases --- plant immunity --- jasmonic acid --- calcium --- light dependent signalling --- Ralstonia solanacearum --- proteomics --- plant defense response --- Arabidopsis --- Lasiodiplodia theobromae --- azelaic acid --- citrus decline disease --- New Guinea impatiens --- replication process --- rice --- mango --- ?-3 fatty acid desaturase --- Ralstonia Solanacearum --- food security --- iTRAQ --- mitogen-activated protein kinase 4
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Plants possess a rather complex and efficient immune system. During their evolutionary history, plants have developed various defense strategies in order to recognize and distinguishing between self and non-self, and face pathogens and animal pests. Accordingly, to study the plant innate immunity represents a new frontier in the plant pathology and crop protection fields. This book is structured in 6 sections. The first part introduces some basic and general aspects of the plant innate immunity and crop protection. Sections 2–5 focus on fungal and oomycete diseases (section 2), bacterial and phytoplasma diseases (section 3), virus diseases (section 4), and insect pests (section 5), with a number of case studies and plant–pathogen/pest interactions. The last section deals with plant disease detection and control. The book aims to highlight new trends in these relevant areas of plant sciences, providing a global perspective that is useful for future and innovative ideas.
Bakraee --- tomato gray mold --- Citrus sinensis --- CDPKs --- salicylic acid --- calmodulin --- glycerol-3-phosphate --- biotic stress responses --- negative regulator --- rice blast --- metabolomics --- hydroperoxide lyase --- Bromoviridae --- induced defense responses --- leaf transcriptome --- calcium signature --- “Candidatus Liberibacter” --- garden impatiens --- Chilo suppressalis --- plant defence --- plant–virus interactions --- spectral distribution of light --- Magnaporthe oryzae --- plant-virus interaction --- biological control --- ultrastructure --- pathogenicity --- disease resistance --- Potato virus Y --- symbiosis --- N-hydroxypipecolic acid --- VaHAESA --- priming --- plant–microbe interactions --- systemic and local movement --- immunity --- CaWRKY40b --- plant protection products --- hypersensitive response --- cellulose synthase --- herbivore-induced defense response --- Macrosiphum euphorbiae --- RTNLB --- ISR --- RNA silencing --- herbivore-induced plant defenses --- disease management --- sustainable crop protection --- WRKY networks --- Camellia sinensis --- RNA-Seq --- transcriptional modulation --- ETI --- pathogenesis related-protein 2 --- cell wall --- basal defense --- candidate disease resistance gene --- MTI --- grapevine --- defense-related signaling pathways --- wounding --- ethylene --- CMLs --- Prune dwarf virus --- Arabidopsis thaliana --- SAR signalling --- innate immunity --- agrochemicals --- OsGID1 --- Nilaparvata lugens --- tobacco --- tomato leaf mold --- Solanum lycopersicum --- downy mildew --- pipecolic acid --- chemical elicitors --- bismerthiazol --- pre-conditioning --- gibberellin --- “Candidatus Phytoplasma” --- dieback --- CaWRKY22 --- microbiota --- Sogatella furcifera --- PTI --- SAR --- Bacillus subtilis --- PRRs --- aphid resistance --- methyl salicylate --- regurgitant --- Myzus persicae --- Agrobacterium --- Ectropis obliqua --- Capsicum annuum --- polyphenol oxidase --- plant proteases --- plant immunity --- jasmonic acid --- calcium --- light dependent signalling --- Ralstonia solanacearum --- proteomics --- plant defense response --- Arabidopsis --- Lasiodiplodia theobromae --- azelaic acid --- citrus decline disease --- New Guinea impatiens --- replication process --- rice --- mango --- ?-3 fatty acid desaturase --- Ralstonia Solanacearum --- food security --- iTRAQ --- mitogen-activated protein kinase 4
Choose an application
Plants possess a rather complex and efficient immune system. During their evolutionary history, plants have developed various defense strategies in order to recognize and distinguishing between self and non-self, and face pathogens and animal pests. Accordingly, to study the plant innate immunity represents a new frontier in the plant pathology and crop protection fields. This book is structured in 6 sections. The first part introduces some basic and general aspects of the plant innate immunity and crop protection. Sections 2–5 focus on fungal and oomycete diseases (section 2), bacterial and phytoplasma diseases (section 3), virus diseases (section 4), and insect pests (section 5), with a number of case studies and plant–pathogen/pest interactions. The last section deals with plant disease detection and control. The book aims to highlight new trends in these relevant areas of plant sciences, providing a global perspective that is useful for future and innovative ideas.
Bakraee --- tomato gray mold --- Citrus sinensis --- CDPKs --- salicylic acid --- calmodulin --- glycerol-3-phosphate --- biotic stress responses --- negative regulator --- rice blast --- metabolomics --- hydroperoxide lyase --- Bromoviridae --- induced defense responses --- leaf transcriptome --- calcium signature --- “Candidatus Liberibacter” --- garden impatiens --- Chilo suppressalis --- plant defence --- plant–virus interactions --- spectral distribution of light --- Magnaporthe oryzae --- plant-virus interaction --- biological control --- ultrastructure --- pathogenicity --- disease resistance --- Potato virus Y --- symbiosis --- N-hydroxypipecolic acid --- VaHAESA --- priming --- plant–microbe interactions --- systemic and local movement --- immunity --- CaWRKY40b --- plant protection products --- hypersensitive response --- cellulose synthase --- herbivore-induced defense response --- Macrosiphum euphorbiae --- RTNLB --- ISR --- RNA silencing --- herbivore-induced plant defenses --- disease management --- sustainable crop protection --- WRKY networks --- Camellia sinensis --- RNA-Seq --- transcriptional modulation --- ETI --- pathogenesis related-protein 2 --- cell wall --- basal defense --- candidate disease resistance gene --- MTI --- grapevine --- defense-related signaling pathways --- wounding --- ethylene --- CMLs --- Prune dwarf virus --- Arabidopsis thaliana --- SAR signalling --- innate immunity --- agrochemicals --- OsGID1 --- Nilaparvata lugens --- tobacco --- tomato leaf mold --- Solanum lycopersicum --- downy mildew --- pipecolic acid --- chemical elicitors --- bismerthiazol --- pre-conditioning --- gibberellin --- “Candidatus Phytoplasma” --- dieback --- CaWRKY22 --- microbiota --- Sogatella furcifera --- PTI --- SAR --- Bacillus subtilis --- PRRs --- aphid resistance --- methyl salicylate --- regurgitant --- Myzus persicae --- Agrobacterium --- Ectropis obliqua --- Capsicum annuum --- polyphenol oxidase --- plant proteases --- plant immunity --- jasmonic acid --- calcium --- light dependent signalling --- Ralstonia solanacearum --- proteomics --- plant defense response --- Arabidopsis --- Lasiodiplodia theobromae --- azelaic acid --- citrus decline disease --- New Guinea impatiens --- replication process --- rice --- mango --- ?-3 fatty acid desaturase --- Ralstonia Solanacearum --- food security --- iTRAQ --- mitogen-activated protein kinase 4 --- Bakraee --- tomato gray mold --- Citrus sinensis --- CDPKs --- salicylic acid --- calmodulin --- glycerol-3-phosphate --- biotic stress responses --- negative regulator --- rice blast --- metabolomics --- hydroperoxide lyase --- Bromoviridae --- induced defense responses --- leaf transcriptome --- calcium signature --- “Candidatus Liberibacter” --- garden impatiens --- Chilo suppressalis --- plant defence --- plant–virus interactions --- spectral distribution of light --- Magnaporthe oryzae --- plant-virus interaction --- biological control --- ultrastructure --- pathogenicity --- disease resistance --- Potato virus Y --- symbiosis --- N-hydroxypipecolic acid --- VaHAESA --- priming --- plant–microbe interactions --- systemic and local movement --- immunity --- CaWRKY40b --- plant protection products --- hypersensitive response --- cellulose synthase --- herbivore-induced defense response --- Macrosiphum euphorbiae --- RTNLB --- ISR --- RNA silencing --- herbivore-induced plant defenses --- disease management --- sustainable crop protection --- WRKY networks --- Camellia sinensis --- RNA-Seq --- transcriptional modulation --- ETI --- pathogenesis related-protein 2 --- cell wall --- basal defense --- candidate disease resistance gene --- MTI --- grapevine --- defense-related signaling pathways --- wounding --- ethylene --- CMLs --- Prune dwarf virus --- Arabidopsis thaliana --- SAR signalling --- innate immunity --- agrochemicals --- OsGID1 --- Nilaparvata lugens --- tobacco --- tomato leaf mold --- Solanum lycopersicum --- downy mildew --- pipecolic acid --- chemical elicitors --- bismerthiazol --- pre-conditioning --- gibberellin --- “Candidatus Phytoplasma” --- dieback --- CaWRKY22 --- microbiota --- Sogatella furcifera --- PTI --- SAR --- Bacillus subtilis --- PRRs --- aphid resistance --- methyl salicylate --- regurgitant --- Myzus persicae --- Agrobacterium --- Ectropis obliqua --- Capsicum annuum --- polyphenol oxidase --- plant proteases --- plant immunity --- jasmonic acid --- calcium --- light dependent signalling --- Ralstonia solanacearum --- proteomics --- plant defense response --- Arabidopsis --- Lasiodiplodia theobromae --- azelaic acid --- citrus decline disease --- New Guinea impatiens --- replication process --- rice --- mango --- ?-3 fatty acid desaturase --- Ralstonia Solanacearum --- food security --- iTRAQ --- mitogen-activated protein kinase 4
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