sameAs
Common Motifs in the Response of Cereal Primary Metabolism to Fungal Pathogens are not Based on Similar Transcriptional ReprogrammingEndophytic life strategies decoded by genome and transcriptome analyses of the mutualistic root symbiont Piriformospora indicaThe endophytic fungus Piriformospora indica reprograms barley to salt-stress tolerance, disease resistance, and higher yield.Bacteria-triggered systemic immunity in barley is associated with WRKY and ETHYLENE RESPONSIVE FACTORs but not with salicylic acid.An image classification approach to analyze the suppression of plant immunity by the human pathogen Salmonella Typhimurium.Nitric oxide generation in Vicia faba phloem cells reveals them to be sensitive detectors as well as possible systemic transducers of stress signals.The Abundance of Endofungal Bacterium Rhizobium radiobacter (syn. Agrobacterium tumefaciens) Increases in Its Fungal Host Piriformospora indica during the Tripartite Sebacinalean Symbiosis with Higher Plants.Transcriptome and metabolome profiling of field-grown transgenic barley lack induced differences but show cultivar-specific variancesThe Salmonella effector protein SpvC, a phosphothreonine lyase is functional in plant cells.Conserved nematode signalling molecules elicit plant defenses and pathogen resistance.An RNAi-Based Control of Fusarium graminearum Infections Through Spraying of Long dsRNAs Involves a Plant Passage and Is Controlled by the Fungal Silencing Machinery.Systemic Induction of NO-, Redox-, and cGMP Signaling in the Pumpkin Extrafascicular Phloem upon Local Leaf Wounding.Adaptation of aphid stylectomy for analyses of proteins and mRNAs in barley phloem sap.Insect peptide metchnikowin confers on barley a selective capacity for resistance to fungal ascomycetes pathogens.New wind in the sails: improving the agronomic value of crop plants through RNAi-mediated gene silencing.Constitutively activated barley ROPs modulate epidermal cell size, defense reactions and interactions with fungal leaf pathogens.Production, amplification and systemic propagation of redox messengers in plants? The phloem can do it all!Non-pathogenic Rhizobium radiobacter F4 deploys plant beneficial activity independent of its host Piriformospora indica.Matrix metalloproteinases operate redundantly in Arabidopsis immunity against necrotrophic and biotrophic fungal pathogens.The Piriformospora indica effector PIIN_08944 promotes the mutualistic Sebacinalean symbiosis.Phytoplasma infection in tomato is associated with re-organization of plasma membrane, ER stacks, and actin filaments in sieve elementsThanatin confers partial resistance against aflatoxigenic fungi in maize (Zea mays).Silencing the expression of the salivary sheath protein causes transgenerational feeding suppression in the aphid Sitobion avenae.N-acyl-homoserine lactones-producing bacteria protect plants against plant and human pathogensOHMS**: Phytoplasmas dictate changes in sieve-element ultrastructure to accommodate their requirements for nutrition, multiplication and translocation.The GHKL ATPase MORC1 Modulates Species-Specific Plant Immunity in Solanaceae.Corrigendum: Systemic Induction of NO-, Redox-, and cGMP Signaling in the Pumpkin Extrafascicular Phloem upon Local Leaf Wounding.Piriformospora indica mycorrhization increases grain yield by accelerating early development of barley plants.Phytohormones in plant root-Piriformospora indica mutualism.MORC Proteins: Novel Players in Plant and Animal Health.Manipulation of plant innate immunity and gibberellin as factor of compatibility in the mutualistic association of barley roots with Piriformospora indica.Karyotype analysis, genome organization, and stable genetic transformation of the root colonizing fungus Piriformospora indica.Systemic resistance in Arabidopsis conferred by the mycorrhizal fungus Piriformospora indica requires jasmonic acid signaling and the cytoplasmic function of NPR1.Systemic and local modulation of plant responses by Piriformospora indica and related Sebacinales species.N-Acyl-Homoserine Lactone Primes Plants for Cell Wall Reinforcement and Induces Resistance to Bacterial Pathogens via the Salicylic Acid/Oxylipin Pathway.Over-expression of the cell death regulator BAX inhibitor-1 in barley confers reduced or enhanced susceptibility to distinct fungal pathogens.Detection and identification of bacteria intimately associated with fungi of the order Sebacinales.Further analysis of barley MORC1 using a highly efficient RNA-guided Cas9 gene editing system.Cross-kingdom RNA trafficking and environmental RNAi-nature's blueprint for modern crop protection strategies.Interactive signal transfer between host and pathogen during successful infection of barley leaves by Blumeria graminis and Bipolaris sorokiniana
P50
Q21129221-5091F512-B951-4E9B-ACA3-E9C51D1F6FF6Q21131407-8D170387-7F30-4A0F-831D-9AE7587694ECQ24531281-E5333CA7-3AFE-4D01-90A7-0406948A92D0Q30317010-FE8F90F2-317C-4833-BA08-F6F1BA16A3A4Q30529664-6BB862A6-B48A-4042-B415-C77AF3BFB85BQ33321935-174A55BE-3404-420C-A09A-599A753E35D4Q33559363-61056238-A22C-4839-977A-1639AB405C18Q33778636-0A24D036-AEC3-47F0-97DE-45C372807533Q34360129-4F5225A7-8F90-40EB-9FC9-8FFC643AABDEQ35916993-72AD087B-484A-4A3F-93CC-0DA9AB005374Q36162988-FD77A1AA-6B54-47EC-B422-A85C901104F2Q36574068-F022157A-0B82-4EEE-B270-8A46825A4323Q36862303-F83B793C-4AE0-4BA0-B992-15677CCCF739Q37370097-32387E1B-150C-4353-9A49-EA2A70FE959AQ38231474-B95D19E0-B39C-4EB5-A2E6-528287908247Q38287473-2CE7D469-E036-492B-B2D7-56A6BCD10D07Q39065373-A03D064E-DA7D-48FB-BA5C-7604D8B47E71Q39132646-E439216E-E6E9-4FCD-8939-2CA797ACF230Q40074018-02AF9EC6-683C-46B8-A207-697ADA1C7B5FQ40309930-C14ADCB0-9701-4DE0-BAEA-406CD46636C3Q41011081-24E007E4-D990-418D-9CAD-95991FD6B991Q41163913-4D3712FA-AA10-401D-93C8-0B9F10E07A5FQ41586739-387F6D96-8F43-4D00-88B6-357AD18BEB8DQ41734054-229B7555-2668-4C3F-9299-234B9279AA3CQ42244044-ACE0228C-1AB0-4A57-81D3-C79A6F840857Q42474900-7785ABFD-CD3B-4410-914E-A691C8AF5554Q42650936-CA9EF319-D060-4EB7-9869-505B56822E15Q42757604-A44E4CEE-D780-4DD5-B28D-A986E27784FDQ43093675-101CF3F2-72DB-4E4E-8B25-F449ABF15EADQ43122065-E7CF2944-9165-4541-8D98-EE549C113FADQ45489462-F89859A8-E2CE-4D5F-A32F-CC1BCFCAD8A8Q46058339-0004599B-FC9A-417F-8E64-A9D1BD8C3731Q46325608-B3736E77-369B-4015-B8E2-1DA37925A2E4Q46887026-CB7FA42C-DB71-4B27-AF3F-2A63B86651D6Q48298696-6B1B11A9-2E77-4078-9FE1-61BDB150697DQ50616260-C1249897-B9D4-4B2D-A916-4C6C174AAFE7Q51683430-C0003951-F403-4900-871A-6634CF51BF4AQ52431010-AC20C22A-703E-4B7A-8052-AAE6BCB934D8Q54254321-BD162376-C34B-4A17-95ED-2D19868587BCQ81373832-17A4F9B7-B6AE-4A8F-8D2C-415C0D319F94
P50
description
botanicus
@nl
deutscher Pflanzenbiotechnologe
@de
hulumtues
@sq
researcher
@en
հետազոտող
@hy
name
Karl-Heinz Kogel
@ast
Karl-Heinz Kogel
@de
Karl-Heinz Kogel
@en
Karl-Heinz Kogel
@es
Karl-Heinz Kogel
@nl
Karl-Heinz Kogel
@sl
type
label
Karl-Heinz Kogel
@ast
Karl-Heinz Kogel
@de
Karl-Heinz Kogel
@en
Karl-Heinz Kogel
@es
Karl-Heinz Kogel
@nl
Karl-Heinz Kogel
@sl
prefLabel
Karl-Heinz Kogel
@ast
Karl-Heinz Kogel
@de
Karl-Heinz Kogel
@en
Karl-Heinz Kogel
@es
Karl-Heinz Kogel
@nl
Karl-Heinz Kogel
@sl
P19
P21
P31
P496
0000-0003-1226-003X
P569
1956-01-08T00:00:00Z