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De novo characterization of fall dormant and nondormant alfalfa (Medicago sativa L.) leaf transcriptome and identification of candidate genes related to fall dormancyUnravelling molecular mechanisms from floral initiation to lipid biosynthesis in a promising biofuel tree species, Pongamia pinnata using transcriptome analysisFlower bud transcriptome analysis of Sapium sebiferum (Linn.) Roxb. and primary investigation of drought induced flowering: pathway construction and G-quadruplex prediction based on transcriptomeGenetic determinism of phenological traits highly affected by climate change in Prunus avium: flowering date dissected into chilling and heat requirements.EARLY BUD-BREAK 1 (EBB1) is a regulator of release from seasonal dormancy in poplar treesCan phenological models predict tree phenology accurately in the future? The unrevealed hurdle of endodormancy break.Are winter and summer dormancy symmetrical seasonal adaptive strategies? The case of temperate herbaceous perennials.Transcriptome analysis of Japanese pear (Pyrus pyrifolia Nakai) flower buds transitioning through endodormancy.Expression and genomic structure of the dormancy-associated MADS box genes MADS13 in Japanese pears (Pyrus pyrifolia Nakai) that differ in their chilling requirement for endodormancy release.Effect of extending the photoperiod with low-intensity red or far-red light on the timing of shoot elongation and flower-bud formation of 1-year-old Japanese pear (Pyrus pyrifolia).The Role of Temperature in the Growth and Flowering of Geophytes.The sweet cherry (Prunus avium) FLOWERING LOCUS T gene is expressed during floral bud determination and can promote flowering in a winter-annual Arabidopsis accession.Comprehensive Transcriptome Analyses Reveal Differential Gene Expression Profiles of Camellia sinensis Axillary Buds at Para-, Endo-, Ecodormancy, and Bud Flush Stages.Dual regulation of water retention and cell growth by a stress-associated protein (SAP) gene in PrunusKnowing when not to grow.Actinidia DRM1--an intrinsically disordered protein whose mRNA expression is inversely correlated with spring budbreak in kiwifruit.Vernalization and the chilling requirement to exit bud dormancy: shared or separate regulation?A genome-wide analysis of MADS-box genes in peach [Prunus persica (L.) Batsch]Coordinated Expression of FLOWERING LOCUS T and DORMANCY ASSOCIATED MADS-BOX-Like Genes in Leafy SpurgeGenome-wide transcriptome profiling provides insights into floral bud development of summer-flowering Camellia azalea.Comparative Transcriptome Analysis of the Less-Dormant Taiwanese Pear and the Dormant Japanese Pear during Winter Season.Mapping of Candidate Genes Involved in Bud Dormancy and Flowering Time in Sweet Cherry (Prunus avium)Gladiolus hybridus ABSCISIC ACID INSENSITIVE 5 (GhABI5) is an important transcription factor in ABA signaling that can enhance Gladiolus corm dormancy and Arabidopsis seed dormancy.Comparative RNA-seq based transcriptomic analysis of bud dormancy in grapeCold Treatment Breaks Dormancy but Jeopardizes Flower Quality in Camellia japonica L.Dormancy-associated MADS-box genes and microRNAs jointly control dormancy transition in pear (Pyrus pyrifolia white pear group) flower bud.The contrasting effects of short-term climate change on the early recruitment of tree species.Transcriptome comparison reveals key candidate genes responsible for the unusual reblooming trait in tree peonies.The dynamic nature of bud dormancy in trees: environmental control and molecular mechanisms.Epigenetic regulation of bud dormancy events in perennial plantsA molecular framework for seasonal growth-dormancy regulation in perennial plants.Chemical control of flowering time.Allelic variants of the esterase gene W14/15 differentially regulate overwinter survival in perennial gentian (Gentiana L.).Transcription through the eye of a needle: daily and annual cyclic gene expression variation in Douglas-fir needles.Functional diversification of the dehydrin gene family in apple and its contribution to cold acclimation during dormancy.Transcription profiling of the chilling requirement for bud break in apples: a putative role for FLC-like genes.A Conserved Carbon Starvation Response Underlies Bud Dormancy in Woody and Herbaceous SpeciesComparative Transcriptome Analysis of Chinary, Assamica and Cambod tea (Camellia sinensis) Types during Development and Seasonal Variation using RNA-seq Technology.Cyanogenic Glucosides and Derivatives in Almond and Sweet Cherry Flower Buds from Dormancy to Flowering.Extensive Transcriptome Changes During Natural Onset and Release of Vegetative Bud Dormancy in Populus
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Q28544913-4CC00A01-6942-436B-8E92-6EE70A9A1991Q28598310-C1226C58-A67A-4AA9-864D-3C568F7215BAQ28652830-B18E832E-7C3C-4C3E-9B26-BF08A368A34EQ30732288-F1E33EBB-7730-4519-B0F7-E51C5FB2613BQ30832552-0D30AECB-C058-4550-975D-12CF2EF185FCQ31106214-2BDE6B06-3A40-4693-989E-60E419FED680Q31154689-BF31D39A-A852-468D-A830-8DFD84ADB7F4Q33355758-756E4E29-2423-43C2-BA22-DFD26AA615B8Q33355986-2DFF2E58-0D4F-4C67-ADC4-BE683F7A4D94Q33358529-207D7DEF-1785-4A1A-B952-CE0F487C388EQ33363073-08F45C33-56E4-40E6-876C-5D148C5193EEQ33364303-6B089FE6-5BE7-489D-B87A-644130C3F2FFQ33571445-37E03DD9-B770-4ADB-8C17-27B334035F8BQ33672023-1233BB0A-B527-4963-8DDB-CCE95C863823Q33774420-47AEC509-2A9A-4638-B54D-CA534CC86C3FQ34629323-B24953E0-FA97-4B89-B228-B67577C97E19Q34722240-39030A3E-E6EF-484C-A19E-30B24DECFBE9Q35085595-EC08BAAF-16AC-458D-A4D8-9B4E4A9902F1Q35593351-DAB6F211-3ADE-494D-B84F-9917B8DD3F11Q35609729-7ECB6C1D-6B00-4346-9101-34A6E57E74D1Q35801451-AA8D66D9-BAD8-4816-8E68-051B961A54CCQ35846961-0367F6FC-33B8-45C0-990B-0797497F64F1Q36242225-BA3AE385-6462-4851-BDDB-BC8A7B08F573Q36254288-893A6417-86DF-45B8-9AB6-67D4A9A4F5CFQ36271864-1D55DDD0-0CAF-4CDE-BA5B-6B9AE744B127Q36380095-AAD45C10-A2AC-4FD4-9003-54C20A79F28BQ36390271-0E0EE299-41D4-406D-A0DE-3A69DE5D52DFQ37308904-7A87099D-A1BF-4323-B0F2-65CEB8731A40Q38016477-8119378D-82DA-4DD2-830F-5104C1862983Q38219412-A81A6A85-7A4F-4EAB-A96D-99BCB671D5C6Q38616920-A17414E9-6C18-471B-92DC-D683B8728C70Q39137975-E8900E43-E7C8-47B1-885E-C4EE62F43D5EQ41023914-A4543D39-B6AE-4C21-97BC-F2BB2173B74DQ41111659-DD8928D8-FBF7-42E3-97A6-1D365EE70BB9Q41158663-24253BD7-495E-4720-A693-09B8A5A0D436Q41270279-D7F82C40-6B67-4CC0-9769-2244D4E9A46FQ41815346-93B15711-D66C-41FE-B31E-0ABA0520E5E8Q42011133-FCCC2CAE-4B74-4E91-826E-6C08456D38A6Q42256025-E43C0158-4F2F-44FA-83B4-22542D3B93EBQ42653132-BE995F6A-4873-4831-A3B2-815D806CDE49
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description
im Dezember 2009 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в грудні 2009
@uk
name
Common mechanisms regulate flowering and dormancy
@en
Common mechanisms regulate flowering and dormancy
@nl
type
label
Common mechanisms regulate flowering and dormancy
@en
Common mechanisms regulate flowering and dormancy
@nl
prefLabel
Common mechanisms regulate flowering and dormancy
@en
Common mechanisms regulate flowering and dormancy
@nl
P1433
P1476
Common mechanisms regulate flowering and dormancy
@en
P2093
David Horvath
P304
P356
10.1016/J.PLANTSCI.2009.09.002
P577
2009-12-01T00:00:00Z