Stress enhances the synthesis of secondary plant products: the impact of stress-related over-reduction on the accumulation of natural products.
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Increased ratio of electron transport to net assimilation rate supports elevated isoprenoid emission rate in eucalypts under drought.Transcriptome and metabolite profiling reveals that prolonged drought modulates the phenylpropanoid and terpenoid pathway in white grapes (Vitis vinifera L.).Interactive effects of temperature and drought on cassava growth and toxicity: implications for food security?Resilience of cassava (Manihot esculenta Crantz) to salinity: implications for food security in low-lying regions.Salinity-mediated cyanogenesis in white clover (Trifolium repens) affects trophic interactions.Nitrogen limitation as a driver of genome size evolution in a group of karst plantsPhysiological significance of isoprenoids and phenylpropanoids in drought response of Arundinoideae species with contrasting habitats and metabolism.Anti-cancer effect of Annona Muricata Linn Leaves Crude Extract (AMCE) on breast cancer cell lineTranscriptomic Changes of Drought-Tolerant and Sensitive Banana Cultivars Exposed to Drought Stress.Species-specific photorespiratory rate, drought tolerance and isoprene emission rate in plants.Optimization of photosynthesis by multiple metabolic pathways involving interorganelle interactions: resource sharing and ROS maintenance as the bases.2-DE proteomics analysis of drought treated seedlings of Quercus ilex supports a root active strategy for metabolic adaptation in response to water shortage.Phenotypic differences determine drought stress responses in ecotypes of Arundo donax adapted to different environments.High accumulation of anthocyanins via the ectopic expression of AtDFR confers significant salt stress tolerance in Brassica napus L.Drought stress and leaf herbivory affect root terpenoid concentrations and growth of Tanacetum vulgare.Transcriptional Responses to Pre-flowering Leaf Defoliation in Grapevine Berry from Different Growing Sites, Years, and Genotypes.Drought effects on root and needle terpenoid content of a coastal and an interior Douglas fir provenance.Chemical fingerprinting identifies Echium vulgare, Eupatorium cannabinum and Senecio spp. as plant species mainly responsible for pyrrolizidine alkaloids in bee-collected pollen.Leaf developmental stage modulates metabolite accumulation and photosynthesis contributing to acclimation of Arabidopsis thaliana to water deficit.Modeling of Dolichol Mass Spectra Isotopic Envelopes as a Tool to Monitor Isoprenoid Biosynthesis.Metabolomics and Biochemical Approaches Link Salicylic Acid Biosynthesis to Cyanogenesis in Peach Plants.Changes of Metabolomic Profile in Helianthus annuus under Exposure to Chromium(VI) Studied by capHPLC-ESI-QTOF-MS and MS/MS.Cloning and Characterization of Cheilanthifoline and Stylopine Synthase Genes from Chelidonium majus.Dissection of genotype × environment interactions for mucilage and seed yield in Plantago species: Application of AMMI and GGE biplot analyses.Cyanogenesis in Arthropods: From Chemical Warfare to Nuptial Gifts.Responses of radish (Raphanus sativus ) to drought stressPre-sowing seed treatment with cold plasma and electromagnetic field increases secondary metabolite content in purple coneflower (Echinacea purpurea ) leavesPhytotoxic activity of Cachrys pungens Jan, a mediterranean species: separation, identification and quantification of potential allelochemicals
P2860
Q30843652-7F32BDEB-330B-4A67-BE46-E8611FDA6CCFQ31061477-9A45C0FD-0997-463C-92FB-09F079C488B6Q31104769-A64781B5-1583-4255-976D-1F951EF4010AQ31120583-93CBD656-DEC8-4C5F-BDE6-7A31B60E6756Q33951863-0CDDBA8E-A266-4022-ADE0-3F3512C4EDACQ35778756-6AF19325-6F1A-4DC5-B8AF-83ED3714D8AAQ36063196-19C30D34-8CBE-42F3-9406-FDCD8A2B6B92Q36112190-7553CA6C-8AA0-4B8D-B735-D0325AF6E63BQ36198975-C43DE3DF-6B35-4C0B-8EA9-4BE6B2BF6CFFQ36212994-2829458A-DEBC-4B27-9276-A8CDEF542FEAQ38123716-9B47D574-4004-420F-9BD2-98ED3C306445Q38404882-576F048A-2C91-4B0A-A90D-1F8ED62735DCQ38864092-5FA0764B-1A1E-4C65-8928-5B48F29FF2C3Q39136627-3AA09418-001C-49FE-8EF2-2954CA0D1A71Q39140397-BD84B1AE-81E0-48D2-89A7-AA87EBEB9946Q41917768-CA230D9E-FBD7-4577-A385-DA7C8F16F8AEQ46284256-DB39814A-D545-4322-B8E8-7A67066DF328Q46299605-920B3652-CE04-42FF-817F-2877D61F3182Q46891694-D4129037-DF39-4832-94F5-A224E49B9FC5Q47566557-9D8FB0E9-3D6D-4359-91D9-438995509846Q47611052-1EC37A45-5E65-4BBE-BD8A-87387C5214DEQ47718140-B6DDDF1C-DD64-4346-8E13-8025A2551ADFQ50575437-B899E846-65A4-47FE-AD3E-0D526D67C140Q55005084-223B9F14-E808-4910-A1EE-6240162C8FB9Q55112849-81134455-BEE8-47A9-A45E-B565FB52EFD8Q58389518-CB60E519-4722-46DD-92D6-40B993C65052Q58873321-96FB9A0C-B357-4FEB-B350-11F52E4038E3Q59220439-C1D444F3-65AA-4C0D-BE4C-9DDDB119A229
P2860
Stress enhances the synthesis of secondary plant products: the impact of stress-related over-reduction on the accumulation of natural products.
description
article científic
@ca
article scientifique
@fr
articol științific
@ro
articolo scientifico
@it
artigo científico
@gl
artigo científico
@pt
artigo científico
@pt-br
artikel ilmiah
@id
artikull shkencor
@sq
artículo científico
@es
name
Stress enhances the synthesis ...... umulation of natural products.
@en
type
label
Stress enhances the synthesis ...... umulation of natural products.
@en
prefLabel
Stress enhances the synthesis ...... umulation of natural products.
@en
P2860
P356
P1476
Stress enhances the synthesis ...... umulation of natural products.
@en
P2093
Dirk Selmar
Maik Kleinwächter
P2860
P304
P356
10.1093/PCP/PCT054
P577
2013-04-23T00:00:00Z