Roles for Arabidopsis CAMTA transcription factors in cold-regulated gene expression and freezing tolerance.
about
Jasmonates: Emerging Players in Controlling Temperature Stress ToleranceAbiotic stress responses in plants: roles of calmodulin-regulated proteinsInvolvement of calmodulin and calmodulin-like proteins in plant responses to abiotic stressesLow-temperature perception leading to gene expression and cold tolerance in higher plantsCalcium-Mediated Abiotic Stress Signaling in RootsAtaxia and Purkinje cell degeneration in mice lacking the CAMTA1 transcription factorPlastidial metabolite MEcPP induces a transcriptionally centered stress-response hub via the transcription factor CAMTA3Recent advances in the dissection of drought-stress regulatory networks and strategies for development of drought-tolerant transgenic rice plants.Dehydration responsive element binding transcription factors and their applications for the engineering of stress tolerance.Adaptation to seasonality and the winter freeze.Global transcriptome profiles of Camellia sinensis during cold acclimationAnalysis of global gene expression in Brachypodium distachyon reveals extensive network plasticity in response to abiotic stress.Transcriptional regulation of the paper mulberry under cold stress as revealed by a comprehensive analysis of transcription factorsEnhancing crop resilience to combined abiotic and biotic stress through the dissection of physiological and molecular crosstalk.The Banana Fruit SINA Ubiquitin Ligase MaSINA1 Regulates the Stability of MaICE1 to be Negatively Involved in Cold Stress ResponseTranscriptome analysis of the vernalization response in barley (Hordeum vulgare) seedlingsRDM4 modulates cold stress resistance in Arabidopsis partially through the CBF-mediated pathway.Salt stress and senescence: identification of cross-talk regulatory components.The effects of phenotypic plasticity on photosynthetic performance in winter rye, winter wheat and Brassica napus.Changes in external pH rapidly alter plant gene expression and modulate auxin and elicitor responses.Characterization of a calcium/calmodulin-regulated SR/CAMTA gene family during tomato fruit development and ripeningPoplar GTL1 is a Ca2+/calmodulin-binding transcription factor that functions in plant water use efficiency and drought toleranceSeven zinc-finger transcription factors are novel regulators of the stress responsive gene OsDREB1B.Calmodulin-binding protein CBP60g is a positive regulator of both disease resistance and drought tolerance in Arabidopsis.A key general stress response motif is regulated non-uniformly by CAMTA transcription factorsCalcium dependent CAMTA1 in adult stem cell commitment to a myocardial lineageDiscovery of stress responsive DNA regulatory motifs in Arabidopsis.Tomato SR/CAMTA transcription factors SlSR1 and SlSR3L negatively regulate disease resistance response and SlSR1L positively modulates drought stress toleranceColinearity and similar expression pattern of rice DREB1s reveal their functional conservation in the cold-responsive pathway.Co-expression analysis identifies putative targets for CBP60g and SARD1 regulationDeep-sequencing transcriptome analysis of chilling tolerance mechanisms of a subnival alpine plant, Chorispora bungeana.Chilling acclimation provides immunity to stress by altering regulatory networks and inducing genes with protective functions in cassavaCAMTA 1 regulates drought responses in Arabidopsis thalianaCircadian clock-associated 1 and late elongated hypocotyl regulate expression of the C-repeat binding factor (CBF) pathway in Arabidopsis.De novo characterization of the Anthurium transcriptome and analysis of its digital gene expression under cold stress.Transcriptomics and functional genomics of ROS-induced cell death regulation by RADICAL-INDUCED CELL DEATH1.A bulk segregant gene expression analysis of a peach population reveals components of the underlying mechanism of the fruit cold responseLinkage of cold acclimation and disease resistance through plant-pathogen interaction pathway in Vitis amurensis grapevine.Integration of low temperature and light signaling during cold acclimation response in Arabidopsis.Pre-symptomatic transcriptome changes during cold storage of chilling sensitive and resistant peach cultivars to elucidate chilling injury mechanisms
P2860
Q26771441-E0DF8815-5608-4740-892F-AD10013EA489Q26777181-59EB70BC-0381-472A-9491-66BAE4760473Q26795937-54020EB9-77C2-4BC8-83D3-6D21D8277EC8Q26995539-97746296-87D7-4178-9500-9F8CA4FAD39EQ28070133-4914B79D-8625-45FA-8ED2-AF219ED07586Q28591066-F57961AF-99C8-4F64-92AB-6E38664EFB41Q28830923-8763E006-ABF4-4E28-8783-BBFF1206AF4BQ30389466-5DF0C5A8-6EE5-4286-91C9-A93448F8EB0DQ30401162-E9A52C48-997C-4920-9DC8-3E19FDCF1710Q30647157-20784F03-A7C6-4F77-BFB0-A470CCE5BED1Q31121707-98CB3665-8183-4CC5-9703-2A53D75A8D26Q31149484-17EC8DD9-7900-44AC-8FA8-236203568B71Q33360607-280A82CA-314C-4C38-BB14-659AD860461BQ33657895-7E4896D4-1A9F-4F6B-97B8-E2D9E82FD7D3Q33785830-0C38818D-2D9B-4C79-901A-FA5E6968D9F3Q33847114-9C1B04B1-6C2A-4449-9273-3CDD4AC07FFEQ33915206-8B9E9463-688F-4554-A732-680E852A0C01Q33931718-A17EA844-4D0F-4B25-8DF7-EE58E14C8247Q34007436-2BED7EF7-47D5-48DE-8B58-42C55EFBC6A9Q34061153-81891A01-CA6E-4706-9E0A-8F0CEA367144Q34157943-1A37C50D-9F55-40A0-989D-8D4B5DB2B3A8Q34187306-26855AC1-5CAC-467B-BDE9-701EA7CEBC4CQ34192693-CCA3673D-DA6C-4036-884F-007BD43492C5Q34216145-1BFE5693-7386-4C47-9D7E-08856D3B7239Q34232231-5949544F-6773-4172-A516-6F7783DC1087Q34310259-192EE1D0-1549-43AA-91CF-E97BE649840CQ34389400-488E645F-8AF4-43E6-B073-89CE639E3A96Q34446881-BC130DA3-7413-4626-AF19-91F0866CD795Q34450698-B5EB8BDD-5D11-4EDF-A1BA-A5D6BCEFB464Q34478429-0BAE88EA-D44F-40F8-B10F-DB1C65EC25F9Q34484664-5199213A-699A-4BC7-A22B-4CA003087F23Q34539235-C22D5FCA-7A2D-4E7B-BD8E-D2BCB1DC5F8AQ34645260-28BF1FDF-5491-4907-9E96-4600174D2DB9Q34880631-2DC57B20-ED18-42BC-953E-8A9409590FF3Q35051446-8D4D3174-F04D-4FDA-89ED-31938CD4AC0FQ35097137-9B098228-109A-4D71-B08E-0ADFC086125CQ35112114-BB737003-874F-4683-BF19-7BC40E9D1AF7Q35231174-C1597D2E-0B9E-41B8-852D-FE6F22D06575Q35239779-A97801A7-2386-472E-A4EA-2A988B030676Q35607458-0B14A52C-F23E-46C0-B1D4-111295A2A6FF
P2860
Roles for Arabidopsis CAMTA transcription factors in cold-regulated gene expression and freezing tolerance.
description
2009 nî lūn-bûn
@nan
2009年の論文
@ja
2009年学术文章
@wuu
2009年学术文章
@zh
2009年学术文章
@zh-cn
2009年学术文章
@zh-hans
2009年学术文章
@zh-my
2009年学术文章
@zh-sg
2009年學術文章
@yue
2009年學術文章
@zh-hant
name
Roles for Arabidopsis CAMTA tr ...... ession and freezing tolerance.
@en
Roles for Arabidopsis CAMTA tr ...... ession and freezing tolerance.
@nl
type
label
Roles for Arabidopsis CAMTA tr ...... ession and freezing tolerance.
@en
Roles for Arabidopsis CAMTA tr ...... ession and freezing tolerance.
@nl
prefLabel
Roles for Arabidopsis CAMTA tr ...... ession and freezing tolerance.
@en
Roles for Arabidopsis CAMTA tr ...... ession and freezing tolerance.
@nl
P2093
P2860
P356
P1433
P1476
Roles for Arabidopsis CAMTA tr ...... ession and freezing tolerance.
@en
P2093
Colleen J Doherty
Heather A Van Buskirk
Michael F Thomashow
Susan J Myers
P2860
P304
P356
10.1105/TPC.108.063958
P577
2009-03-06T00:00:00Z