Reprint
Plant Innate Immunity 2.0
Edited by
April 2019
386 pages
- ISBN978-3-03897-580-9 (Paperback)
- ISBN978-3-03897-581-6 (PDF)
This is a Reprint of the Special Issue Plant Innate Immunity 2.0 that was published in
Biology & Life Sciences
Chemistry & Materials Science
Medicine & Pharmacology
Summary
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.
Format
- Paperback
License and Copyright
© 2019 by the authors; CC BY-NC-ND license
Keywords
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/a