Chapter 2 Cold Signalling and Cold Acclimation in Plants
about
C4 bioenergy crops for cool climates, with special emphasis on perennial C4 grassesGlobal analysis of transcriptome responses and gene expression profiles to cold stress of Jatropha curcas L.Ultrasonic emissions during ice nucleation and propagation in plant xylemCavitation and water fluxes driven by ice water potential in Juglans regia during freeze-thaw cyclesSensitivity of cold acclimation to elevated autumn temperature in field-grown Pinus strobus seedlings.Cucumber (Cucumis sativus L.) Nitric Oxide Synthase Associated Gene1 (CsNOA1) Plays a Role in Chilling StressCloning and characterization of a novel stress-responsive WRKY transcription factor gene (MusaWRKY71) from Musa spp. cv. Karibale Monthan (ABB group) using transformed banana cells.Chilling and frost tolerance in Miscanthus and Saccharum genotypes bred for cool temperate climatesMetabolite changes in conifer buds and needles during forced bud break in Norway spruce (Picea abies) and European silver fir (Abies alba).Role of CBFs as integrators of chloroplast redox, phytochrome and plant hormone signaling during cold acclimation.Refolding of β-stranded class I chitinases of Hippophae rhamnoides enhances the antifreeze activity during cold acclimationComparative Transcriptomics of Sijung and Jumli Marshi Rice during Early Chilling Stress Imply Multiple Protective Mechanisms.Comparative transcriptomics analysis reveals difference of key gene expression between banana and plantain in response to cold stress.Integrative "omic" analysis reveals distinctive cold responses in leaves and roots of strawberry, Fragaria × ananassa 'Korona'Physiological and Biochemical Mechanisms of Seed Priming-Induced Chilling Tolerance in Rice Cultivars.Transgenic barley lines prove the involvement of TaCBF14 and TaCBF15 in the cold acclimation process and in frost toleranceAlternative splicing of transcription factors in plant responses to low temperature stress: mechanisms and functions.Multiple reaction monitoring mass spectrometry is a powerful tool to study glycerolipid composition in plants with different level of desaturase activityWinter leaf reddening in 'evergreen' species.Physiological and molecular changes in plants grown at low temperatures.New clues for a cold case: nitric oxide response to low temperature.Rootstock Sub-Optimal Temperature Tolerance Determines Transcriptomic Responses after Long-Term Root Cooling in Rootstocks and Scions of Grafted Tomato PlantsPerspective Research Progress in Cold Responses of Capsella bursa-pastoris.Hormonal control of cold stress responses in plants.Frost hardening and dehardening potential in temperate trees from winter to budburst.Regulation of low temperature stress in plants by microRNAs.Seed Priming Alters the Production and Detoxification of Reactive Oxygen Intermediates in Rice Seedlings Grown under Sub-optimal Temperature and Nutrient Supply.Evidence for ACD5 ceramide kinase activity involvement in Arabidopsis response to cold stress.Burkholderia phytofirmans PsJN reduces impact of freezing temperatures on photosynthesis in Arabidopsis thaliana.Physiological Mechanisms Only Tell Half Story: Multiple Biological Processes are involved in Regulating Freezing Tolerance of Imbibed Lactuca sativa Seeds.Cold acclimation and low temperature resistance in cotton: Gossypium hirsutum phospholipase Dalpha isoforms are differentially regulated by temperature and light.Proteomic analysis of cold stress-responsive proteins in Thellungiella rosette leaves.iTRAQ-based quantitative proteomic analysis in vernalization-treated faba bean (Vicia faba L.).The genetic characteristics in cytology and plant physiology of two wheat (Triticum aestivum) near isogenic lines with different freezing tolerances.An atypical R2R3 MYB transcription factor increases cold hardiness by CBF-dependent and CBF-independent pathways in apple.Rapid responses of plants to temperature changes.Support for a photoprotective function of winter leaf reddening in nitrogen-deficient individuals of Lonicera japonica.Changes in soluble sugar metabolism in loquat fruit during different cold storage.Proteome analysis of Pueraria mirifica tubers collected in different seasons.Germination phenology determines the propensity for facilitation and competition.
P2860
Q27008907-6B57BE00-2FE2-49EF-AB31-C77E90F2F9D8Q28661206-56841268-6485-44BE-ACB7-98A1EF5C2117Q30374004-C0BEA2A1-334F-4E6C-AC51-78D6957F7828Q30391839-F40FA2BC-1F9C-4F2D-8F1B-78BCC4CCBF9EQ30926847-53A646CA-4D81-43F3-A178-5EA98AC8A38AQ33364321-E8472166-A912-46BF-8CCD-5AB1D8B93D04Q33756423-FB8BAA04-2F3E-405B-A28A-CB7181E1305DQ33860136-6C3FBC50-43C9-407F-B46A-17E7E01A3DC8Q34677479-7E6F4234-CC5B-41F3-8FED-8464BAF303F8Q34777560-CF7D7467-8C09-444C-AAE4-56337030E730Q35120150-7CC15BBA-EB5C-489D-8BC7-4DA3D0137A39Q35631520-58E6111F-B6D6-4B2B-BDD0-9C80E53F8D28Q35658806-A81DA50F-1C94-4502-95B9-75AB46AF5C99Q36162381-3B4272E6-BDF5-4B50-A849-5F492B46159BQ36559627-12CF166D-24D4-49A1-9EB1-E9EB790D185DQ36802507-CAEC815A-7686-4C97-9FC6-627D92F5CDE7Q36878244-380DA41C-CEC9-4635-B4FF-F7DF4046D46BQ37534097-7231C7D9-EAD2-46AE-9539-FD58CBC7DCAFQ37849818-8A217EE2-C383-4756-A969-F16D33D0570AQ38004808-A45A4B19-F161-49D7-9AAD-CC0AE3042F29Q38203627-A9F7C5FA-B94D-4D64-B4CB-56517E366AE1Q38370160-E96BCCE7-69AA-4EA8-8AAE-70ACC162F5EAQ38601422-2B8F419C-268A-403F-BB14-DB56E11DFE50Q38644873-548103DD-3028-4386-BE43-05CC0B9961F2Q39143212-03815D18-94A8-4847-A256-B18792CF4E65Q39202500-6729FC47-07B8-463B-AB91-EE8AF0B0AD57Q39863508-F592E0F1-FD1A-4B3B-B2F3-A4D4BC845AF1Q40900214-61977654-CDEE-4C87-AA2B-F11790F7804FQ41469264-3A06EB19-60C9-40DA-8355-6AD2DCB646A0Q42316929-258B2ED7-DCC4-4481-B7AA-C0648069F916Q42660948-11612E63-848B-4221-AEA3-E9A86E8117B1Q43027469-6CAFA547-3CAE-463D-B852-7EEF6A69CF59Q46264851-668D8BDE-B1AA-4067-9D25-56D2B0394427Q46321034-C48AFAC1-26B7-4835-AC15-CE7D787497D3Q47228942-0907519B-AA01-4B95-83EE-6C827BBA2CFCQ50052111-D19731F3-7545-4E9F-87ED-1FF71DE5EB54Q50220737-C78AC5A8-8421-4584-8C54-E5CBBF4D6C79Q50913004-574D0872-646E-42D8-AC13-8A5F52DE2B8AQ50923976-0A956EFF-6958-42B3-B014-EBDA1754D1C2Q51198900-37017B3B-572A-4FB7-AC35-9B9362EC8749
P2860
Chapter 2 Cold Signalling and Cold Acclimation in Plants
description
article
@en
wetenschappelijk artikel
@nl
наукова стаття, опублікована у 2009
@uk
name
Chapter 2 Cold Signalling and Cold Acclimation in Plants
@en
Chapter 2 Cold Signalling and Cold Acclimation in Plants
@nl
type
label
Chapter 2 Cold Signalling and Cold Acclimation in Plants
@en
Chapter 2 Cold Signalling and Cold Acclimation in Plants
@nl
prefLabel
Chapter 2 Cold Signalling and Cold Acclimation in Plants
@en
Chapter 2 Cold Signalling and Cold Acclimation in Plants
@nl
P2093
P1476
Chapter 2 Cold Signalling and Cold Acclimation in Plants
@en
P2093
Alain Zachowski
Eric Ruelland
Marie-Noelle Vaultier
Vaughan Hurry
P304
P356
10.1016/S0065-2296(08)00602-2
P577
2009-01-01T00:00:00Z