Regulatory metabolic networks in drought stress responses.
about
Exploring Jasmonates in the Hormonal Network of Drought and Salinity ResponsesPhytomelatonin: assisting plants to survive and thriveNitric oxide function in plant biology: a redox cue in deconvolutionThe role of abscisic acid in fruit ripening and responses to abiotic stressThe Structure of Arabidopsis thaliana OST1 Provides Insights into the Kinase Regulation Mechanism in Response to Osmotic StressChemical PARP inhibition enhances growth of Arabidopsis and reduces anthocyanin accumulation and the activation of stress protective mechanismsTranscriptome Profiling of Watermelon Root in Response to Short-Term Osmotic StressTackling drought stress: receptor-like kinases present new approachesLAITOR--Literature Assistant for Identification of Terms co-Occurrences and RelationshipsGlobal transcriptome analysis reveals circadian regulation of key pathways in plant growth and development.De novo assembly of red clover transcriptome based on RNA-Seq data provides insight into drought response, gene discovery and marker identification.Metabolomic changes in grains of well-watered and drought-stressed transgenic rice.Transcriptomic network analyses of leaf dehydration responses identify highly connected ABA and ethylene signaling hubs in three grapevine species differing in drought tolerance.Epidermis: the formation and functions of a fundamental plant tissue.Meristem maintenance, auxin, jasmonic and abscisic acid pathways as a mechanism for phenotypic plasticity in Antirrhinum majus.SuperSAGE: the drought stress-responsive transcriptome of chickpea roots.Transcriptional profiling in response to terminal drought stress reveals differential responses along the wheat genome.Analysis of gene expression and physiological responses in three Mexican maize landraces under drought stress and recovery irrigation.Stress-inducible expression of AtDREB1A transcription factor greatly improves drought stress tolerance in transgenic indica rice.Global climate change and tree nutrition: influence of water availability.Development of SSR Markers Based on Transcriptome Sequencing and Association Analysis with Drought Tolerance in Perennial Grass Miscanthus from ChinaApplication of functional genomics and proteomics to plant cryopreservation.Overexpression of the PeaT1 Elicitor Gene from Alternaria tenuissima Improves Drought Tolerance in Rice Plants via Interaction with a Myo-Inositol Oxygenase.Moderate drought causes dramatic floral transcriptomic reprogramming to ensure successful reproductive development in ArabidopsisFunctional annotation of the transcriptome of Sorghum bicolor in response to osmotic stress and abscisic acid.Genome wide expression profiling of two accession of G. herbaceum L. in response to drought.Cell expansion-mediated organ growth is affected by mutations in three EXIGUA genesDiscovery and analysis of microRNAs in Leymus chinensis under saline-alkali and drought stress using high-throughput sequencing.Addressing the role of microRNAs in reprogramming leaf growth during drought stress in Brachypodium distachyon.Salt stress encourages proline accumulation by regulating proline biosynthesis and degradation in Jerusalem artichoke plantletsTranscriptome sequencing and whole genome expression profiling of chrysanthemum under dehydration stressGlobal analysis of gene expression profiles in physic nut (Jatropha curcas L.) seedlings exposed to drought stress.Identification of rapidly induced genes in the response of peanut (Arachis hypogaea) to water deficit and abscisic acid.Comparative transcriptome profiling of the maize primary, crown and seminal root in response to salinity stress.Comparative metabolic and transcriptional analysis of a doubled diploid and its diploid citrus rootstock (C. junos cv. Ziyang xiangcheng) suggests its potential value for stress resistance improvement.Identification of an important site for function of the type 2C protein phosphatase ABI2 in abscisic acid signalling in ArabidopsisPoplar trees reconfigure the transcriptome and metabolome in response to drought in a genotype- and time-of-day-dependent mannerExogenous spermine pretreatment confers tolerance to combined high-temperature and drought stress in vitro in trifoliate orange seedlings via modulation of antioxidative capacity and expression of stress-related genes.Metabolic responses of willow (Salix purpurea L.) leaves to mycorrhization as revealed by mass spectrometry and (1)H NMR spectroscopy metabolite profiling.Cuticular wax biosynthesis as a way of inducing drought resistance.
P2860
Q26773101-C6EC1772-7D89-451B-8D20-96F768AFD3BFQ26824170-81CA69F2-2928-4C0E-B1F6-31C0C5ED3C9EQ27000624-A9DA0DE9-1768-440F-AE53-C05121665BD7Q27023154-63E43781-DFED-43D8-8385-C9D9E8B3A034Q27674795-D3FEB7C4-1F44-4787-8A24-11D5F858CB28Q28483946-0D205C74-5B6D-4F61-BC40-0963BC8602B0Q28553609-EFCC3839-5228-4884-B1FC-910766A42DF2Q28728719-0A362B7B-7D98-4E5F-8FD7-56C714DCBD00Q28744445-CD78DB4D-77BB-4A47-8F55-49167450CE34Q30440986-801F4798-965E-4AE3-B3D4-73B502F6C3F7Q30830052-79933B78-38E6-4ADA-830F-173EBDAE0D75Q30900245-7EC2CBA4-26CC-4536-B17B-827670C509E8Q31100144-4D5C96DA-EEEE-4739-8D9B-BCC665645037Q33350076-4A9F1140-465F-4042-96EC-E52529F3611CQ33362385-8EF90F12-42E8-4526-AC85-707E9A89A60EQ33386215-9E35D5EB-68BA-49CD-988F-FCB959BA12AEQ33474176-975BDC10-A16F-4AF7-825C-E3CDD086C149Q33514858-3265A0E0-7CE5-442E-B27A-DA9C33C34522Q33569137-8B067ED1-04DF-4FFF-91DB-B83F91B88FF2Q33617305-AE61DE98-A42E-4637-B13A-E4022B2EF1FDQ33689798-3D53B2AA-C6E7-4763-AB2A-1F4E3C2146BEQ33775232-FE6A216E-4C85-402A-82D0-ED084DC98208Q33780998-BEBF5AD3-E71D-4CF5-A3E0-811B284ED744Q33792491-B99302F5-B352-470F-B94D-391CA9336C4EQ34050755-CD834FA7-A36D-4DB9-A8D2-6EEE68A2D292Q34198274-3DCF8133-2F7B-4B49-92CD-F1431554BFF0Q34269118-5D56A6C2-F137-4B06-9513-E966F761C67EQ34450032-5AC097BF-9CDE-4366-8863-0854DC98B184Q34522259-CF2EC7FE-B4E1-4C98-ADF7-A6C9544B0116Q34700913-36DE9934-FD11-4DBF-997B-2D6F6626B51CQ35001364-EDBA9256-A305-41D0-854A-1133671EFD10Q35016066-996A2445-AF45-4098-A7E2-74945BFAA2FCQ35196114-CA98AE83-A642-4EF7-8E27-112507D8ECB8Q35213753-E2ADF55E-E350-4A05-BBD1-FE7DDBD8E191Q35218278-4A3F9AB4-3577-49C1-9136-A48DF709EF10Q35570147-87DA1C3F-2E19-4B62-A9BD-FB3B279B97D9Q35610324-2C2C01BC-34B5-4B09-BF7B-A03EFA9283A3Q35613325-EECD12D9-705D-4E8D-BDB4-467D9F7100B1Q35617019-16D55F4E-CA78-4322-97E5-2DA921E06B87Q35671280-F1B7383F-7343-44BE-A4BB-ADCDEA54E17E
P2860
Regulatory metabolic networks in drought stress responses.
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
2007年论文
@zh
2007年论文
@zh-cn
name
Regulatory metabolic networks in drought stress responses.
@ast
Regulatory metabolic networks in drought stress responses.
@en
type
label
Regulatory metabolic networks in drought stress responses.
@ast
Regulatory metabolic networks in drought stress responses.
@en
prefLabel
Regulatory metabolic networks in drought stress responses.
@ast
Regulatory metabolic networks in drought stress responses.
@en
P50
P1476
Regulatory metabolic networks in drought stress responses.
@en
P2093
Kaoru Urano
P304
P356
10.1016/J.PBI.2007.04.014
P577
2007-04-30T00:00:00Z