A unified mechanism of action for volatile isoprenoids in plant abiotic stress.
about
Effects of Abiotic Factors on HIPV-Mediated Interactions between Plants and ParasitoidsRecent Advances in the Emission and Functions of Plant Vegetative VolatilesWhy only some plants emit isopreneTrapping toxins within lipid droplets is a resistance mechanism in fungi.Enhancement of oxidative and drought tolerance in Arabidopsis by overaccumulation of antioxidant flavonoidsIsoprene synthesis in plants: lessons from a transgenic tobacco modelDrought 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 formationBiosynthesis of the diterpenoid lycosantalonol via nerylneryl diphosphate in Solanum lycopersicumIsoprene emissions from downy oak under water limitation during an entire growing season: what cost for growth?Quantitative analysis of volatile organic compounds released and consumed by rat L6 skeletal muscle cells in vitroComparative Transcriptomic Approaches Exploring Contamination Stress Tolerance in Salix sp. Reveal the Importance for a Metaorganismal de Novo Assembly Approach for Nonmodel PlantsDetection of plant volatiles after leaf wounding and darkening by proton transfer reaction "time-of-flight" mass spectrometry (PTR-TOF)Green Leaf Volatile Emissions during High Temperature and Drought Stress in a Central Amazon RainforestForests and ozone: productivity, carbon storage, and feedbacks.Isoprene improves photochemical efficiency and enhances heat dissipation in plants at physiological temperatures.Elevated atmospheric CO2 concentration leads to increased whole-plant isoprene emission in hybrid aspen (Populus tremula × Populus tremuloides).Plant volatiles and the environment.Uncovering the volatile nature of tropical coastal marine ecosystems in a changing world.Climate change alters leaf anatomy, but has no effects on volatile emissions from Arctic plants.Biologically Based Methods for Pest Management in Agriculture under Changing Climates: Challenges and Future DirectionsIsolation of isoprene degrading bacteria from soils, development of isoA gene probes and identification of the active isoprene-degrading soil community using DNA-stable isotope probing.Variation in short-term and long-term responses of photosynthesis and isoprenoid-mediated photoprotection to soil water availability in four Douglas-fir provenancesChronic Drought Decreases Anabolic and Catabolic BVOC Emissions of Quercus pubescens in a Mediterranean Forest.Volatile metabolites.Regulation of the cholesterol biosynthetic pathway and its integration with fatty acid biosynthesis in the oleaginous microalga Nannochloropsis oceanica.Moderate Drought Stress Induces Increased Foliar Dimethylsulphoniopropionate (DMSP) Concentration and Isoprene Emission in Two Contrasting Ecotypes of Arundo donax.Ectopic terpene synthase expression enhances sesquiterpene emission in Nicotiana attenuata without altering defense or development of transgenic plants or neighbors.The timing of herbivore-induced volatile emission in black poplar (Populus nigra) and the influence of herbivore age and identity affect the value of individual volatiles as cues for herbivore enemies.EssOilDB: a database of essential oils reflecting terpene composition and variability in the plant kingdomBidirectional exchange of biogenic volatiles with vegetation: emission sources, reactions, breakdown and deposition.Reactive short-chain leaf volatiles act as powerful inducers of abiotic stress-related gene expressionThe future of isoprene emission from leaves, canopies and landscapes.Chemical fingerprint and simultaneous determination of alkaloids and flavonoids in aerial parts of genus Peganum indigenous to China based on HPLC-UV: application of analysis on secondary metabolites accumulation.Isoprenoids and phenylpropanoids are part of the antioxidant defense orchestrated daily by drought-stressed Platanus × acerifolia plants during Mediterranean summers.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 StressesAboveground Whitefly Infestation Modulates Transcriptional Levels of Anthocyanin Biosynthesis and Jasmonic Acid Signaling-Related Genes and Augments the Cope with Drought Stress of MaizeStabilization of thylakoid membranes in isoprene-emitting plants reduces formation of reactive oxygen speciesPhysiological significance of isoprenoids and phenylpropanoids in drought response of Arundinoideae species with contrasting habitats and metabolism.Plant communication: mediated by individual or blended VOCs?
P2860
Q26770726-7006D40F-1728-4493-9D42-AB9942F23555Q26775151-F2C109F3-B09F-48EB-8EEF-21FC40A5083CQ26830037-EAF1575F-9473-449D-B771-161FC7CA05CEQ27308587-2FE3A3F5-C9C4-4F99-A686-2B058122947BQ28302695-D6F9AE7A-50CD-47B6-9A1D-362BE77E3BC5Q28306881-485014FC-0BD1-46EE-BF1D-2B92A090CEB1Q28534747-36CF36EA-A998-4513-84D3-0CB4864B9E6EQ28542616-C23D0817-73E7-46ED-8F15-5BD6935523F4Q28544476-6BCD01E2-0978-4F5A-A2DE-947B9C528232Q28544829-01292540-4205-451F-A094-DF7D22596ADAQ28601030-A39769AE-55FD-4671-9D24-27F1E284C55BQ28603342-BE77E82F-5269-4AC5-A39A-C95BE6F97D25Q28744236-047B4016-2FF9-4833-A1DB-CB6FB746C182Q28834255-07E40A1B-2B27-421A-9E74-F796B4D33950Q30277298-3812FF99-C31F-4DF6-97ED-39A92A9B7099Q30574741-AA240FC8-CD4F-4345-BC16-65937C22FD35Q30594543-2E805B62-1A65-4285-B5CF-23073FD5DEB9Q30817417-2735C272-DCA6-43FB-9B80-693F7A749563Q30859960-FE38E922-EAFF-46CE-B124-4876F2CC1A7FQ30903574-94E4CB07-2BA8-4251-A343-26019A1443F9Q31004952-AA673824-D62D-434E-962C-B3DF1666E836Q31082810-A99C763E-C5B0-4672-A538-3AE68BFA11EDQ31153896-CC40FF2D-C5F2-4A7F-ABA6-2B93D1D942D2Q31164940-2044C42C-E2D2-4AC3-93C8-F09D384D5B0DQ33575930-D4D94EA7-2DBF-4675-9F19-EE79EFE440E2Q33738188-E57417D8-88AB-4424-AB34-AB9D72C7F107Q33790360-6356E7DF-31E5-41A6-B98D-1D8AD83ACF68Q34310018-B168FF10-FF16-4183-866E-5C784943FE1FQ34676810-2F959185-B02E-4E3E-BDB8-A7B410525356Q34751589-7B373F57-2AB4-4D05-9431-1CDA60E36E1BQ34903341-2A57F7B7-EF20-4C06-918A-C16F02CCDA4FQ35011919-79B3DF94-05AB-4264-9901-DE6D0110BC9BQ35086376-8C324F15-DB8F-4A78-B863-14A04E5BF255Q35180227-FB19947D-6F5D-4275-8438-7404F8C6AEF7Q35580095-F5F8CAE5-C3B1-4A15-83F8-7C213CD31ADCQ35648221-1D6EBBE6-D6EF-486D-A166-AB4B136A34BCQ35858932-FE8AD96E-C78A-40B1-A660-57439DFD0674Q35976970-105DC286-400B-43E0-B4EA-9F0673F02B00Q36063196-3E6401CE-88C2-430E-B424-DF2F35E6FC4DQ36119039-D822DA8A-F3EF-479E-B0F0-3968E79F01B9
P2860
A unified mechanism of action for volatile isoprenoids in plant abiotic stress.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 17 April 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
A unified mechanism of action for volatile isoprenoids in plant abiotic stress.
@en
A unified mechanism of action for volatile isoprenoids in plant abiotic stress.
@nl
type
label
A unified mechanism of action for volatile isoprenoids in plant abiotic stress.
@en
A unified mechanism of action for volatile isoprenoids in plant abiotic stress.
@nl
prefLabel
A unified mechanism of action for volatile isoprenoids in plant abiotic stress.
@en
A unified mechanism of action for volatile isoprenoids in plant abiotic stress.
@nl
P50
P356
P1476
A unified mechanism of action for volatile isoprenoids in plant abiotic stress.
@en
P2093
Francesco Loreto
P2888
P304
P356
10.1038/NCHEMBIO.158
P577
2009-04-17T00:00:00Z
P5875
P6179
1011004499