04079nam 22003493a 450 991076589800332120250203235431.09783038975816303897581810.3390/books978-3-03897-581-6(CKB)5400000000000414(ScCtBLL)6edc255a-2b38-4c5d-b963-2975de81ba05(OCoLC)1105775088(EXLCZ)99540000000000041420250203i20192019 uu enguru||||||||||txtrdacontentcrdamediacrrdacarrierPlant Innate Immunity 2.0Marcello IritiBasel, Switzerland :MDPI,2019.1 online resource (1 p.)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.dieback; disease management; Lasiodiplodia theobromae; mango; pathogenicity; Bromoviridae; plant-virus interactions; plant defense response; Prune dwarf virus; replication process; systemic and local movement; plant proteases; plant immunity; MTI; ETI; SAR; ISR; RNA silencing; RTNLB; Agrobacterium; biotic stress responses; calcium; calcium signature; calmodulin; CMLs; CDPKs; plant immunity; symbiosis; cell wall; cellulose synthase; hypersensitive response; pathogenesis related-protein 2; plant-virus interaction; Potato virus Y; ultrastructure; aphid resistance; Arabidopsis thaliana; hydroperoxide lyase; Macrosiphum euphorbiae; Myzus persicae; Solanum lycopersicum; ω-3 fatty acid desaturase; Arabidopsis; azelaic acid; glycerol-3-phosphate; light dependent signalling; methyl salicylate; N-hydroxypipecolic acid; pipecolic acid; salicylic acid; SAR signalling; spectral distribution of light; tobacco; rice; Chilo suppressalis; mitogen-activated protein kinase 4; jasmonic acid; salicylic acid; ethylene; herbivore-induced defense response; downy mildew; grapevine; PRRs; PTI; VaHAESA; bismerthiazol; rice; induced defense responses; chemical elicitors; Sogatella furcifera; defense-related signaling pathways; tomato gray mold; tomato leaf mold; Bacillus subtilis; biological control; Capsicum annuum; Ralstonia solanacearum; CaWRKY40b; immunity; negative regulator; transcriptional modulation; Capsicum annuum; CaWRKY22; immunity; Ralstonia Solanacearum; WRKY networks; metabolomics; plant defence; plant-microbe interactions; priming; pre-conditioning; citrus decline disease; Citrus sinensis; Bakraee; "Candidatus Liberibacter"; "Candidatus Phytoplasma"; microbiota; innate immunity; basal defense; rice blast; Magnaporthe oryzae; proteomics; iTRAQ; candidate disease resistance gene; disease resistance; downy mildew; garden impatiens; leaf transcriptome; New Guinea impatiens; RNA-Seq; polyphenol oxidase; Camellia sinensis; Ectropis obliqua; wounding; regurgitant; rice; OsGID1; gibberellin; herbivore-induced plant defenses; Nilaparvata lugens; plant protection products; agrochemicals; sustainable crop protection; food security; n/aIriti Marcello1311344ScCtBLLScCtBLLBOOK9910765898003321Plant Innate Immunity 2.03034299UNINA