about
Effects of Abiotic Factors on HIPV-Mediated Interactions between Plants and ParasitoidsPlant Adaptation to Multiple Stresses during Submergence and Following DesubmergenceRecent Advances in the Emission and Functions of Plant Vegetative VolatilesBiogenic volatile organic compound emissions from vegetation firesMethanol may function as a cross-kingdom signalDrought and root herbivory interact to alter the response of above-ground parasitoids to aphid infested plants and associated plant volatile signalsOzone-induced responses in Croton floribundus Spreng. (Euphorbiaceae): metabolic cross-talk between volatile organic compounds and calcium oxalate crystal formationWhere do herbivore-induced plant volatiles go?Chemotypic variation in terpenes emitted from storage pools influences early aphid colonisation on tansyRepeated leaf wounding alters the colonization of Medicago truncatula roots by beneficial and pathogenic microorganisms.Understanding of anesthesia - Why consciousness is essential for life and not based on genes.Consequences of climate warming and altered precipitation patterns for plant-insect and multitrophic interactions.Off-season biogenic volatile organic compound emissions from heath mesocosms: responses to vegetation cuttingEffect of land-use change and management on biogenic volatile organic compound emissions--selecting climate-smart cultivars.Solar ultraviolet radiation and ozone depletion-driven climate change: effects on terrestrial ecosystems.Climate change-induced vegetation change as a driver of increased subarctic biogenic volatile organic compound emissions.Effects of heat and drought stress on post-illumination bursts of volatile organic compounds in isoprene-emitting and non-emitting poplarIntegrative Analyses of Nontargeted Volatile Profiling and Transcriptome Data Provide Molecular Insight into VOC Diversity in Cucumber Plants (Cucumis sativus).Drought-tolerance of wheat improved by rhizosphere bacteria from harsh environments: enhanced biomass production and reduced emissions of stress volatilesConfined direct analysis in real time ion source and its applications in analysis of volatile organic compounds of Citrus limon (lemon) and Allium cepa (onion).Interplant Aboveground Signaling Prompts Upregulation of Auxin Promoter and Malate Transporter as Part of Defensive Response in the Neighboring Plants.Chrysolina herbacea modulates terpenoid biosynthesis of Mentha aquatica L.Production of herbivore-induced plant volatiles is constrained seasonally in the field but predation on herbivores is not.Airborne signals from salt-stressed Arabidopsis plants trigger salinity tolerance in neighboring plants.Airborne signals from a wounded leaf facilitate viral spreading and induce antibacterial resistance in neighboring plantsEctopic terpene synthase expression enhances sesquiterpene emission in Nicotiana attenuata without altering defense or development of transgenic plants or neighbors.A robust, simple, high-throughput technique for time-resolved plant volatile analysis in field experiments.Direct Contact - Sorptive Tape Extraction coupled with Gas Chromatography - Mass Spectrometry to reveal volatile topographical dynamics of lima bean (Phaseolus lunatus L.) upon herbivory by Spodoptera littoralis Boisd.Utilizing associational resistance for biocontrol: impacted by temperature, supported by indirect defence.The Sesquiterpenes(E)-ß-Farnesene and (E)-α-Bergamotene Quench Ozone but Fail to Protect the Wild Tobacco Nicotiana attenuata from Ozone, UVB, and Drought StressesAbscisic acid transcriptomic signaling varies with grapevine organ.Phenotype Uniformity in Combined-Stress Environments has a Different Genetic Architecture than in Single-Stress Treatments.Plutella xylostella (L.) infestations at varying temperatures induce the emission of specific volatile blends by Arabidopsis thaliana (L.) Heynh.Elevated carbon dioxide reduces emission of herbivore-induced volatiles in Zea mays.Methods in plant foliar volatile organic compounds researchQuantitative patterns between plant volatile emissions induced by biotic stresses and the degree of damage.Physiological and transcriptomic analyses reveal a response mechanism to cold stress in Santalum album L. leaves.Plant volatiles: production, function and pharmacology.Plant odour plumes as mediators of plant-insect interactions.An overview of plant volatile metabolomics, sample treatment and reporting considerations with emphasis on mechanical damage and biological control of weeds.
P2860
Q26770726-B787668F-1EAC-4933-A105-BA56FEA352B1Q26773400-E85A9CD2-5B33-41A7-961E-EF131208D5C9Q26775151-4ECDA6B1-6B5F-4664-AC5A-D4C5BF8204F3Q27027767-A735CCEA-BA75-4096-86C0-61286CEFE0FDQ28482670-E77A51B3-64BF-4B63-8EF3-DF91AEF5DB2FQ28534747-98630A9D-E9BE-40B4-ACB7-1BAD9B762578Q28542616-44EF8CCC-3B31-428B-B3C2-8BB2814A0928Q28681615-14856E2E-7303-41BF-B4DC-9DF7F10DA692Q28818547-F2FD45C4-7A23-426E-B639-6FF5985D3E90Q30318184-D85DB5B8-A806-4913-9801-FF0C3110F6E9Q30396974-E1744EB1-E879-4EE9-8131-8B643D21D7FDQ30572363-20528912-DAC7-4641-8BE2-EA286662C847Q30662838-D4A58FA2-621C-481B-9513-387ABC103E3CQ30855182-641D83D7-C1BF-43AC-AC78-17980967AD68Q30872518-C44E8116-5717-4E9B-A18C-BC5E2F3EE78BQ30955535-2D82CCAE-B9F0-45DC-9354-660D0EAA4EB3Q30995044-1A8A2427-5A86-4C9C-B9EE-5D286A65A278Q31117469-97D55D9A-EE14-4D29-88E7-A12708298F29Q31160820-8EDD1041-4938-4A41-A6E9-0FC961ECD55CQ33454144-17E71A5F-8DF3-4ACF-AB77-FE31169229E6Q33575609-E9F30554-CAE4-42B7-B007-0E9EFFB151E3Q33847236-5E3FB978-6E4C-4E14-8C5D-8FD3E2573C8AQ33869975-2FE4A3F1-2052-46EB-A320-ABDC0838E95CQ33879984-495F86AE-C164-4BE2-8B5A-A284A0FDC2D6Q34229679-75316F29-D1AF-4322-9566-7A7606C7C49EQ34310018-A6402325-0BE0-49B6-A2E4-34A7A2B2E6C9Q34310329-74C7CE54-3333-42DA-9321-301A2276D2E1Q35556057-C91474BA-4C08-453D-B262-77E487E0D738Q35645709-38D1DEDA-2456-4CE8-BE78-9903B924709DQ35648221-48D287E7-CD43-4577-BCDB-E714D8EE1AFEQ35965472-EE56B6E0-94DE-4908-AFF9-92D16FD91255Q35970922-F15E062C-7C8F-480F-8E93-E01865A7DA0DQ36212715-8BF9B2BA-534E-4DA9-9460-B6BC450E1F42Q36354778-C8419D2C-FD73-44DE-88F6-2DAA62784615Q36381374-01D948AA-83A2-4CDC-837C-7A5E18D48784Q37034496-2D22D57C-38BA-4DF3-8C70-CFB676F1D6BFQ37627864-E67E6ED9-2E8C-45AE-A83A-76C63228CF4FQ37889127-A89853F7-8B0C-4D01-BE67-C0BCF3AC28B1Q38109950-A825C463-1B34-4589-B6B1-27F3590DEF0EQ38172039-4A25BF2A-B819-4644-B8F0-760AC65E582A
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 08 February 2010
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Multiple stress factors and the emission of plant VOCs.
@en
Multiple stress factors and the emission of plant VOCs.
@nl
type
label
Multiple stress factors and the emission of plant VOCs.
@en
Multiple stress factors and the emission of plant VOCs.
@nl
prefLabel
Multiple stress factors and the emission of plant VOCs.
@en
Multiple stress factors and the emission of plant VOCs.
@nl
P1476
Multiple stress factors and the emission of plant VOCs.
@en
P304
P356
10.1016/J.TPLANTS.2010.01.006
P577
2010-02-08T00:00:00Z