Molecular responses to dehydration and low temperature: differences and cross-talk between two stress signaling pathways.
about
Characterizing the stress/defense transcriptome of ArabidopsisAdding injury to insult: pathogen detection and responses.Abscisic Acid and Abiotic Stress Tolerance in Crop PlantsExploring Jasmonates in the Hormonal Network of Drought and Salinity ResponsesMYB transcription factor genes as regulators for plant responses: an overviewTranscriptional regulation of drought response: a tortuous network of transcriptional factorsABA signal in rice under stress conditionsRegulation of abiotic stress signal transduction by E3 ubiquitin ligases in Arabidopsis.Contribution of ABA UDP-glucosyltransferases in coordination of ABA biosynthesis and catabolism for ABA homeostasisA rice membrane-bound calcium-dependent protein kinase is activated in response to low temperatureArabidopsis PLC1 is required for secondary responses to abscisic acid signalsA novel stress-induced sugarcane gene confers tolerance to drought, salt and oxidative stress in transgenic tobacco plantsTackling drought stress: receptor-like kinases present new approachesFern and lycophyte guard cells do not respond to endogenous abscisic acidGenome-wide survey and expression analysis of the OSCA gene family in riceGenome-wide identification and evolutionary analyses of the PP2C gene family with their expression profiling in response to multiple stresses in Brachypodium distachyonIntroduction of the rd29A:AtDREB2A CA gene into soybean (Glycine max L. Merril) and its molecular characterization in leaves and roots during dehydration.Characterisation and natural variation of a dehydrin gene in Quercus petraea (Matt.) Liebl.Plants in a cold climate.Physiological stressors and invasive plant infections alter the small RNA transcriptome of the rice blast fungus, Magnaporthe oryzae.Adaptation to seasonality and the winter freeze.Monitoring the expression pattern of 1300 Arabidopsis genes under drought and cold stresses by using a full-length cDNA microarray.Characterization of SP1, a stress-responsive, boiling-soluble, homo-oligomeric protein from aspen.Monitoring expression profiles of rice genes under cold, drought, and high-salinity stresses and abscisic acid application using cDNA microarray and RNA gel-blot analyses.dwarf and delayed-flowering 1, a novel Arabidopsis mutant deficient in gibberellin biosynthesis because of overexpression of a putative AP2 transcription factor.Isolation of a novel barley cDNA encoding a nuclear protein involved in stress response and leaf senescence.Genetic responses to phosphorus deficiency.Galactinol synthase1. A novel heat shock factor target gene responsible for heat-induced synthesis of raffinose family oligosaccharides in Arabidopsis.Involvement of ethylene in stress-induced expression of the TLC1.1 retrotransposon from Lycopersicon chilense Dun.Identification of cold acclimation-responsive Rhododendron genes for lipid metabolism, membrane transport and lignin biosynthesis: importance of moderately abundant ESTs in genomic studies.An early response regulatory cluster induced by low temperature and hydrogen peroxide in seedlings of chilling-tolerant japonica rice.Isolation and characterization of induced genes under drought stress at the flowering stage in maize (Zea mays).Putative cold acclimation pathways in Arabidopsis thaliana identified by a combined analysis of mRNA co-expression patterns, promoter motifs and transcription factors.Transcriptomic identification of candidate genes involved in sunflower responses to chilling and salt stresses based on cDNA microarray analysisThe STT3a subunit isoform of the Arabidopsis oligosaccharyltransferase controls adaptive responses to salt/osmotic stress.Identification of transcription factors involved in root apex responses to salt stress in Medicago truncatulaThe low-oxygen-induced NAC domain transcription factor ANAC102 affects viability of Arabidopsis seeds following low-oxygen treatment.Integrated transcriptomic and proteomic profiling of white spruce stems during the transition from active growth to dormancy.Expression profiling of tomato pre-abscission pedicels provides insights into abscission zone properties including competence to respond to abscission signalsPlant hormone cross-talk: the pivot of root growth.
P2860
Q24791362-63C8384E-8FF4-48B9-BC72-BDF47D84C989Q24804410-D3D240D7-DE99-4173-AA73-C5297A9E29ECQ26747353-336AF8D8-2EA6-4556-9466-8C4508FD58E1Q26773101-B085C628-B940-45FA-9969-66379042EB26Q26827201-D27D1E8A-7BD0-4F08-BDBB-6E55417F0149Q26851270-928F1747-7D06-4C87-A73D-FFD54FB600FBQ27011772-8D693DB2-5761-4630-AC66-A7518AD4169BQ27686867-59275E25-9092-4A69-A5B3-F09D0CB80228Q28083467-226D0C67-C9D7-49A8-97FD-7BDEBFD76F02Q28360010-6DFF03CA-5757-4126-B466-CE70165E980CQ28364443-00063004-0537-4399-8DDC-0B598DB751B1Q28483657-056F10E8-A3D0-4A95-9878-DDA3FBA51D80Q28728719-4AAAE8C9-E63B-4840-A88C-44DC23B747F8Q28729136-1CE0F7F3-8D7C-487B-8053-C3F26F1462D9Q30380672-B75FEA5B-D71E-477A-A4F0-6F702C167CE6Q30385173-21E02D03-D9F5-4753-9578-AB4D7A17657EQ30392579-72755A83-22FD-4971-A699-11BD3DBCAF4FQ30407791-51FA1337-AC86-4731-B3A9-065EBE82E428Q30499890-3271AC1B-C29C-4537-B616-D60BAA7F8F69Q30624212-504BD067-5369-430B-B4BB-109C4E0AAAB5Q30647157-483D1B58-BD2C-4660-8E93-B40BCF1F5160Q30649918-0AE7B1F4-219A-4940-B2CD-90D4AB0FE13AQ30862593-AE15257A-9D65-42F5-BD5D-316D5F480A0BQ31029661-40327720-3030-4BDE-8638-F39E78BECFB9Q31044068-19FDB16B-F5A5-4350-ADF1-D87120FF09A2Q31063509-EA9DB995-9F83-41E0-8AF0-486C885F8DB9Q33205472-20E09B3B-15F1-488A-85C3-7771876315B2Q33207640-67077F04-3E68-4AB1-817B-066987373578Q33220243-CCA91031-9B2E-4516-BDE5-BF0E450B276AQ33262447-FCC1BB3E-3A22-438C-99E5-FD4DDEA0EE50Q33288105-28B671C1-190D-4E92-9659-63D5CFDBD57CQ33293109-CB03E75F-A536-498F-AD24-B885FF2CD189Q33296340-0DE0BBDD-9188-49A0-8AE0-89C2255F0DF6Q33316585-B5133568-817D-484A-B511-298719705967Q33338718-76FA448C-6378-48EB-81AE-0E2FE1C3B527Q33346291-360D8922-934F-4B40-A333-C9D5B31CC091Q33346670-D63F0062-06CE-454A-A428-F08C14A00FBBQ33352318-77915D46-06EC-467E-9CB8-94362BBFA911Q33355476-837691B7-7336-4FAA-ACE3-E694B34F5495Q33359942-69C137EE-9DC3-4835-988E-0CD969ECEB8D
P2860
Molecular responses to dehydration and low temperature: differences and cross-talk between two stress signaling pathways.
description
2000 nî lūn-bûn
@nan
2000 թուականի Յունիսին հրատարակուած գիտական յօդուած
@hyw
2000 թվականի հունիսին հրատարակված գիտական հոդված
@hy
2000年の論文
@ja
2000年論文
@yue
2000年論文
@zh-hant
2000年論文
@zh-hk
2000年論文
@zh-mo
2000年論文
@zh-tw
2000年论文
@wuu
name
Molecular responses to dehydra ...... two stress signaling pathways.
@ast
Molecular responses to dehydra ...... two stress signaling pathways.
@en
type
label
Molecular responses to dehydra ...... two stress signaling pathways.
@ast
Molecular responses to dehydra ...... two stress signaling pathways.
@en
prefLabel
Molecular responses to dehydra ...... two stress signaling pathways.
@ast
Molecular responses to dehydra ...... two stress signaling pathways.
@en
P1476
Molecular responses to dehydra ...... two stress signaling pathways.
@en
P2093
Shinozaki K
Yamaguchi-Shinozaki K
P304
P356
10.1016/S1369-5266(00)00067-4
P577
2000-06-01T00:00:00Z