The capacity for thermal protection of photosynthetic electron transport varies for different monoterpenes in Quercus ilex.
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Daily rhythm of mutualistic pollinator activity and scent emission in Ficus septica: ecological differentiation between co-occurring pollinators and potential consequences for chemical communication and facilitation of host speciationIsoprene emission from plants: why and howCyclic monoterpene mediated modulations of Arabidopsis thaliana phenotype: effects on the cytoskeleton and on the expression of selected genesChanges in floral bouquets from compound-specific responses to increasing temperatures.Facing the Future: Effects of Short-Term Climate Extremes on Isoprene-Emitting and Nonemitting Poplar.Isoprene research - 60 years later, the biology is still enigmatic.Bidirectional exchange of biogenic volatiles with vegetation: emission sources, reactions, breakdown and deposition.Oak powdery mildew (Erysiphe alphitoides)-induced volatile emissions scale with the degree of infection in Quercus robur.Quantitative patterns between plant volatile emissions induced by biotic stresses and the degree of damage.How light, temperature, and measurement and growth [CO2] interactively control isoprene emission in hybrid aspen.Scaling of photosynthesis and constitutive and induced volatile emissions with severity of leaf infection by rust fungus (Melampsora larici-populina) in Populus balsamifera var. suaveolens.Affinity and Efficacy Studies of Tetrahydrocannabinolic Acid A at Cannabinoid Receptor Types One and Two.Differential Accumulation of Volatile Organic Compounds by Leaves and Roots of Two Guianese Philodendron Species, P. fragrantissimum Kunth and P. melinonii Brongn.Significance of terpenoids in induced indirect plant defence against herbivorous arthropods.Methyl jasmonate-induced emission of biogenic volatiles is biphasic in cucumber: a high-resolution analysis of dose dependence.Mono- and sesquiterpene release from tomato (Solanum lycopersicum) leaves upon mild and severe heat stress and through recovery: from gene expression to emission responses.Thermogenic respiratory processes drive the exponential increase of volatile organic compound emissions in Macrozamia cycad cones.Photosynthesis, stomatal conductance and terpene emission response to water availability in dry and mesic Mediterranean forestsA screening study of leaf terpene emissions of 43 rainforest species in Danum Valley Conservation Area (Borneo) and their relationships with chemical and morphological leaf traitsSeasonal changes in the daily emission rates of terpenes by Quercus ilex and the atmospheric concentrations of terpenes in the natural park of Montseny, NE SpainEcological metabolomics: overview of current developments and future challengesVolatile organic compounds emissions in Norway spruce (Picea abies) in response to temperature changesSeasonal contrasting changes of foliar concentrations of terpenes and other volatile organic compound in four dominant species of a Mediterranean shrubland submitted to a field experimental drought and warming
P2860
Q21131979-BFC4E840-51A1-4DA5-A34C-B8C7CBAABE0BQ24657721-ECA93630-CF32-4E42-864F-782FC5D353B2Q30396145-6E7C2FC0-071B-4ED1-B1F0-F9837BF591F3Q30818747-6F3C600B-5D8E-4F62-B279-AC238F99C4AFQ30979648-1135F1EE-83F4-49EE-98E9-61E20CCFE929Q34550605-47AD370F-7A2E-4E76-B800-F78A88CFE829Q34903341-2EA2EF48-1E58-4D7C-BD09-561F892B6694Q35540131-61104304-BF38-4A74-9858-A929349D3D20Q37034496-4708D158-2844-4907-A858-2B38FBFEC2B8Q39097743-0A5A6351-A9C6-496C-ABDA-BDAA104D7704Q40659428-4D320140-1756-47CC-9BF2-ACA4BE1A87F8Q41016971-46B45CC7-9A1C-4D50-A573-1F1AAC70396AQ46439756-42F1400D-5B32-485A-8752-0C6DFB6E3BE5Q46798986-6C90B65B-0CC2-4D39-B63A-06978A9FEC7AQ49578682-534A65B4-5737-4AB1-904D-639381BD2CA9Q49723640-EDD6013A-FE67-4D35-9935-E34645360863Q51485274-A4ED4B78-E585-41E5-88F9-50154CE160E0Q56990586-CABDAE8F-8D80-4FAC-A776-EB65F94C632DQ56990742-839383F1-17EC-44DA-8FE5-EEC5649D6F41Q56991077-AD60DDD0-34EC-44E5-BC76-A28BD37DA8B4Q56991174-9A6A4DB7-8F49-445F-A0E0-9FBF14E3543FQ56991703-78580709-56A8-45A2-BE30-85E0617B38F1Q56991793-1A7C3341-5D9D-4880-AA9B-FEC9A60683B7
P2860
The capacity for thermal protection of photosynthetic electron transport varies for different monoterpenes in Quercus ilex.
description
2005 nî lūn-bûn
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2005年の論文
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2005年学术文章
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2005年学术文章
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2005年学术文章
@zh-cn
2005年学术文章
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2005年学术文章
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2005年學術文章
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name
The capacity for thermal prote ...... monoterpenes in Quercus ilex.
@en
The capacity for thermal prote ...... monoterpenes in Quercus ilex.
@nl
type
label
The capacity for thermal prote ...... monoterpenes in Quercus ilex.
@en
The capacity for thermal prote ...... monoterpenes in Quercus ilex.
@nl
prefLabel
The capacity for thermal prote ...... monoterpenes in Quercus ilex.
@en
The capacity for thermal prote ...... monoterpenes in Quercus ilex.
@nl
P2860
P50
P356
P1433
P1476
The capacity for thermal prote ...... monoterpenes in Quercus ilex.
@en
P2093
Iolanda Filella
Joan Llusià
P2860
P304
P356
10.1104/PP.105.065995
P407
P577
2005-08-26T00:00:00Z