How plants sense wounds: damaged-self recognition is based on plant-derived elicitors and induces octadecanoid signaling
about
Extraordinary Adaptive Plasticity of Colorado Potato Beetle: "Ten-Striped Spearman" in the Era of Biotechnological WarfareThe dendritic cell response to classic, emerging, and homeostatic danger signals. Implications for autoimmunityComparison between the Amount of Environmental Change and the Amount of Transcriptome ChangeCharacterization and Comparative Expression Profiling of Browning Response in Medinilla formosana after CuttingUnderstanding of anesthesia - Why consciousness is essential for life and not based on genes.Early physiological consequences of fire as an abiotic stressor in metabolic source and sink of young Brutian pine (Pinus brutia Ten.).Life histories of hosts and pathogens predict patterns in tropical fungal plant diseases.Differential activation of sporamin expression in response to abiotic mechanical wounding and biotic herbivore attack in the sweet potatoPrickly poppies can get pricklier: ontogenetic patterns in the induction of physical defense traitsJasmonate-triggered plant immunityJasmonate-dependent induction of polyphenol oxidase activity in tomato foliage is important for defense against Spodoptera exigua but not against Manduca sexta.Methanol and ethanol modulate responses to danger- and microbe-associated molecular patternsDanger signals - damaged-self recognition across the tree of life.Damaged-self recognition in common bean (Phaseolus vulgaris) shows taxonomic specificity and triggers signaling via reactive oxygen species (ROS).Extracellular ATP activates MAPK and ROS signaling during injury response in the fungus Trichoderma atroviride.Specific pools of endogenous peptides are present in gametophore, protonema, and protoplast cells of the moss Physcomitrella patens.Defensive changes in maize leaves induced by feeding of Mediterranean corn borer larvae.Transcriptome analysis of symptomatic and recovered leaves of geminivirus-infected pepper (Capsicum annuum).Wounding, insect chewing and phloem sap feeding differentially alter the leaf proteome of potato, Solanum tuberosum L.Application of an improved proteomics method for abundant protein cleanup: molecular and genomic mechanisms study in plant defense.Sweet immunity in the plant circadian regulatory network.ER stress, autophagy and immunogenic cell death in photodynamic therapy-induced anti-cancer immune responses.Glutamate receptor-like channels in plants: a role as amino acid sensors in plant defence?Sucrose and invertases, a part of the plant defense response to the biotic stresses.Extracellular ATP acts as a damage-associated molecular pattern (DAMP) signal in plantsRoot symbionts: Powerful drivers of plant above- and belowground indirect defenses.Physiological function and ecological aspects of fatty acid-amino acid conjugates in insects.Specific polyphenols and tannins are associated with defense against insect herbivores in the tropical oak Quercus oleoides.Bacterial phytopathogen infection disrupts belowground plant indirect defense mediated by tritrophic cascade.Plant intelligence and attention.Insect herbivores selectively suppress the HPL branch of the oxylipin pathway in host plants.Damaged-self recognition as a general strategy for injury detection.Editorial: Wound Recognition across the Tree of Life.Growth and molecular responses to long-distance stimuli in poplars: bending vs flame wounding.Extracellular ATP acts on jasmonate signaling to reinforce plant defense.Kojic acid-mediated damage responses induce mycelial regeneration in the basidiomycete Hypsizygus marmoreus.Herbivore perception decreases photosynthetic carbon assimilation and reduces stomatal conductance by engaging 12-oxo-phytodienoic acid, mitogen-activated protein kinase 4 and cytokinin perception.A crosstalk between extracellular ATP and jasmonate signaling pathways for plant defense.Trading direct for indirect defense? Phytochrome B inactivation in tomato attenuates direct anti-herbivore defenses whilst enhancing volatile-mediated attraction of predators.Frontiers in chemical ecology and coevolution.
P2860
Q28072588-FD9D7AB3-A8E6-44EF-933A-3418D83F448DQ28384138-D83F25E5-1594-4E27-8157-835BC726A252Q28551497-ABCA34CC-1752-456E-B363-FC6A4260E48EQ28818764-20742387-A0D6-4279-B430-E3BFDDB25DC2Q30396974-E8131A83-6ACA-4A54-BF68-926032BD233EQ30872299-4ED50F03-098F-4F05-9D13-BC67073BD1EDQ31142522-031526DA-7D90-4250-857D-D786E05AE96EQ33358328-4927B60D-1967-4A44-A157-4E8B8ECCF19DQ33573481-4BF9467F-3FE1-41DB-B302-6F96DE891593Q34086685-D7196F14-E962-4E6A-8627-D65395F538A1Q34305771-8951DBE0-887C-44FA-8DF3-A321764F31F0Q34342037-F8F35FB0-0DC0-4C11-A86F-C405660D3B89Q34433019-38731E8C-4E0D-4C5A-A9FA-25128BB22499Q34433042-FC1829F0-A3EA-4E8D-8CC3-4A3C1CDDC6B0Q34554838-351ABEF0-0272-4FE3-843B-463F2F003FB3Q35194147-BDCAF3CF-5E8D-4F2F-8F33-19D22CAA4272Q36281684-7BE629A6-3D66-44B0-8667-8627984B2E76Q36539083-648F2DBA-4C39-468E-8F1F-D7AE96BCF5BEQ36585081-B6805414-7CD8-482A-9782-2C9750E0842EQ37289468-24F40175-F902-46F3-ADCD-CE9F38C49D53Q38097028-D58F16E2-CE6C-4E16-891D-4DB93CBE5109Q38184935-D56ED364-D82C-4B45-80A1-1EB545D6F008Q38225870-BACC2892-A109-453A-AD6D-77E128D4D39DQ38227166-5A46848C-2A3D-46FE-B216-EF5C0F7CEF36Q38251630-BCFE7595-DE9C-410D-BBD5-F25133B383C3Q38735372-31AFEA6A-B9C6-4979-A849-AEFE62F9E907Q38759963-07503564-45FC-4C0D-8809-7C0FEAF7FBABQ39196302-BA25E50C-814D-4FAB-90AA-F7CC781C929CQ40142328-E12FD719-EDCE-4F1F-9683-95912EDEA1C9Q41859221-808ED686-D71D-4B8A-AC88-F4E9B7EAF228Q42010971-9570F7D1-5E85-46C9-B63B-41A80B59F24DQ42275953-AB56DFFD-8108-4AA6-A634-5E80A92D4E32Q42398997-261BC68C-C9F1-4528-A310-3A4757DE0031Q44933190-D5A8E6B0-3206-4147-B73A-0324B4361C86Q46253308-88EEDA98-7180-4C0E-BFB8-0DA4DE18D95EQ46265698-5010BF82-EB48-46B3-8F0F-CD6CE4BF8F1EQ46449479-6BE466F1-DCC4-4B6E-98CB-C8972EF5FF7BQ49689585-EC3F9FC3-14C4-411B-8AB1-44868CD095ECQ50227953-2EB1C064-0A9A-4D94-AFD2-583ECD509843Q51162272-8B784820-72DE-48D5-8F63-ECC76B732A98
P2860
How plants sense wounds: damaged-self recognition is based on plant-derived elicitors and induces octadecanoid signaling
description
2012 nî lūn-bûn
@nan
2012 թուականի Փետրուարին հրատարակուած գիտական յօդուած
@hyw
2012 թվականի փետրվարին հրատարակված գիտական հոդված
@hy
2012年の論文
@ja
2012年学术文章
@wuu
2012年学术文章
@zh-cn
2012年学术文章
@zh-hans
2012年学术文章
@zh-my
2012年学术文章
@zh-sg
2012年學術文章
@yue
name
How plants sense wounds: damag ...... induces octadecanoid signaling
@ast
How plants sense wounds: damag ...... induces octadecanoid signaling
@en
How plants sense wounds: damag ...... induces octadecanoid signaling
@nl
type
label
How plants sense wounds: damag ...... induces octadecanoid signaling
@ast
How plants sense wounds: damag ...... induces octadecanoid signaling
@en
How plants sense wounds: damag ...... induces octadecanoid signaling
@nl
prefLabel
How plants sense wounds: damag ...... induces octadecanoid signaling
@ast
How plants sense wounds: damag ...... induces octadecanoid signaling
@en
How plants sense wounds: damag ...... induces octadecanoid signaling
@nl
P2093
P2860
P1433
P1476
How plants sense wounds: damag ...... induces octadecanoid signaling
@en
P2093
Enrique Ibarra-Laclette
Enrique Ramirez-Chávez
Jorge Molina-Torres
Martin Heil
Rosa M Adame-Álvarez
P2860
P304
P356
10.1371/JOURNAL.PONE.0030537
P407
P577
2012-02-09T00:00:00Z