From The Cover: A role for Arabidopsis cryptochromes and COP1 in the regulation of stomatal opening.
about
Control of stomatal aperture: a renaissance of the old guardAbscisic Acid as an Internal Integrator of Multiple Physiological Processes Modulates Leaf Senescence Onset in Arabidopsis thaliana.Hypersensitive to red and blue 1 and its modification by protein phosphatase 7 are implicated in the control of Arabidopsis stomatal apertureStomata prioritize their responses to multiple biotic and abiotic signal inputsGenome-wide association mapping identifies a new arsenate reductase enzyme critical for limiting arsenic accumulation in plantsThe OsmiR396c-OsGRF4-OsGIF1 regulatory module determines grain size and yield in riceA Mechanism for Reorientation of Cortical Microtubule Arrays Driven by Microtubule SeveringGenetic architecture of carbon isotope composition and growth in Eucalyptus across multiple environments.OsLEA3-2, an abiotic stress induced gene of rice plays a key role in salt and drought toleranceDirect visualization of Agrobacterium-delivered VirE2 in recipient cells.Use of confocal laser as light source reveals stomata-autonomous function.A gain-of-function mutation in IAA7/AXR2 confers late flowering under short-day light in Arabidopsis.RNAi-directed downregulation of OsBADH2 results in aroma (2-acetyl-1-pyrroline) production in rice (Oryza sativa L.).HFR1 is crucial for transcriptome regulation in the cryptochrome 1-mediated early response to blue light in Arabidopsis thalianaSecret message at the plant surface.Phototropins and chloroplast activity in plant blue light signaling.RAN1 is involved in plant cold resistance and development in rice (Oryza sativa)The Effect of Spectral Quality on Daily Patterns of Gas Exchange, Biomass Gain, and Water-Use-Efficiency in Tomatoes and Lisianthus: An Assessment of Whole Plant MeasurementsCommon and unique elements of the ABA-regulated transcriptome of Arabidopsis guard cellsCryptochrome 2 and phototropin 2 regulate resistance protein-mediated viral defense by negatively regulating an E3 ubiquitin ligaseArabidopsis fatty acid desaturase FAD2 is required for salt tolerance during seed germination and early seedling growth.The suppression of WRKY44 by GIGANTEA-miR172 pathway is involved in drought response of Arabidopsis thaliana.Cryptochrome 1 and phytochrome B control shade-avoidance responses in Arabidopsis via partially independent hormonal cascadesThe Cryptochrome Blue Light ReceptorsOpaque7 encodes an acyl-activating enzyme-like protein that affects storage protein synthesis in maize endospermThe action mechanisms of plant cryptochromesArabidopsis seed-specific vacuolar aquaporins are involved in maintaining seed longevity under the control of ABSCISIC ACID INSENSITIVE 3A study of the blue-light-dependent phosphorylation, degradation, and photobody formation of Arabidopsis CRY2.Arabidopsis STO/BBX24 negatively regulates UV-B signaling by interacting with COP1 and repressing HY5 transcriptional activityGenome-wide investigation of the NAC transcription factor family in melon (Cucumis melo L.) and their expression analysis under salt stress.The Small G Protein AtRAN1 Regulates Vegetative Growth and Stress Tolerance in Arabidopsis thalianaThe novel quantitative trait locus GL3.1 controls rice grain size and yield by regulating Cyclin-T1;3Regulation of developmental and environmental signaling by interaction between microtubules and membranes in plant cells.Transcriptome Analyses Reveal the Involvement of Both C and N Termini of Cryptochrome 1 in Its Regulation of Phytohormone-Responsive Gene Expression in Arabidopsis.Roles of ion channels and transporters in guard cell signal transduction.cry1 and GPA1 signaling genetically interact in hook opening and anthocyanin synthesis in Arabidopsis.Arabidopsis CRY2 and ZTL mediate blue-light regulation of the transcription factor CIB1 by distinct mechanisms.Rice aleurone layer specific OsNF-YB1 regulates grain filling and endosperm development by interacting with an ERF transcription factor.Sumoylation stabilizes RACK1B and enhance its interaction with RAP2.6 in the abscisic acid response.Plant organelle proteomics: collaborating for optimal cell function.
P2860
Q27011653-2ACEE194-BADA-46C9-9039-7616979884D9Q27307184-76A6F047-DDC2-4F13-814A-E42D9C2030ABQ28483638-369710DE-196F-4999-A862-D3F5C3EC70FAQ28540460-5B839BAA-7AE4-41AB-8EA7-4AB189202BAFQ28542399-C61EF287-CDF5-45F4-B313-D05BE667B7F5Q28596455-5950C71E-99FC-43BB-8765-61F32A1753EBQ29036602-C98BC885-8DB5-4C7A-89DA-ECBD1F4FA4E6Q30887134-C2AC827B-ABCC-4D84-A14A-A13162C145A8Q31101241-A971641B-F31B-4B4C-8CD2-C2B01BE78056Q31144852-615E3A3A-6E5A-4294-88E3-5DC212D7ADD3Q33267294-4A41AF67-45DF-447B-AC7D-9D639FCB589CQ33351210-60000D29-3D3E-4550-8A59-DB2E8ED899FDQ33374442-727995AD-70F6-42EE-BC8E-75DB6F7B0A1CQ33381534-2A973422-F29A-47E8-AE9E-723E8040197CQ33496430-BC4FAA60-39EC-45E8-91B7-494C4B2F738EQ33570231-33A86F61-6F0D-4EAC-8211-D96CFD75B4A4Q33809932-59D38F61-15F0-45A3-940F-67CA85DD2097Q33814984-0C0A1327-61CF-4ECF-AACE-371EFFABA9E7Q33893289-79CF7333-154C-4AA4-80A0-7FBE24CB1241Q34067907-B60DE092-7C61-41D4-BE4A-F2A438DB734DQ34141789-DAB3EF9D-330F-4B61-8A00-85083FF526CEQ35040077-8F54E8A8-21D3-44AE-830B-C97561446DE5Q35103293-9D1C4CFF-1378-43A7-AFB4-D1FBC8895FBDQ35161827-3DDD0F2F-3234-4A5C-9EA5-8D522E83F309Q35620426-64062DB9-B3C3-4EC7-A82E-A2F4A0FFF622Q35751826-F7165FD6-1612-4839-A955-698DECD613ECQ35867059-F594554B-0429-45FA-AAE2-5B688E21C1A2Q35969399-11A2FBC1-F731-4255-9891-054A0036A9B3Q36009210-0050643C-F879-490C-9C56-6ADF9C6ADA75Q36031094-B5C6A720-5AA3-4323-B9B5-196C117F681EQ36039710-E4B7C5F7-324B-44F2-B2DF-34008864BBE1Q36449154-982970AB-F95A-4FC8-9368-260966F93706Q36547297-4975A122-1672-43AC-AF06-59FEE7DE883FQ36681215-755E102E-CA1F-4F0F-9E57-02BA6C233F5FQ36803084-755A9394-0EB7-4DF2-94AF-EBE0A820EDFAQ36913111-CB49144D-AC1A-4422-AB09-A2F1B9A258F9Q37256157-AF785DE9-61B0-430D-9622-28F4817F7150Q37530069-38D934FF-CD73-48A5-908B-C9DE5E3D3166Q37685768-DDC07A92-8149-4C06-8E04-08E95C53D810Q37805395-F8676078-6A16-4AE6-B783-104EEE04A2B9
P2860
From The Cover: A role for Arabidopsis cryptochromes and COP1 in the regulation of stomatal opening.
description
2005 nî lūn-bûn
@nan
2005 թուականի Օգոստոսին հրատարակուած գիտական յօդուած
@hyw
2005 թվականի օգոստոսին հրատարակված գիտական հոդված
@hy
2005年の論文
@ja
2005年論文
@yue
2005年論文
@zh-hant
2005年論文
@zh-hk
2005年論文
@zh-mo
2005年論文
@zh-tw
2005年论文
@wuu
name
From The Cover: A role for Ara ...... egulation of stomatal opening.
@ast
From The Cover: A role for Ara ...... egulation of stomatal opening.
@en
type
label
From The Cover: A role for Ara ...... egulation of stomatal opening.
@ast
From The Cover: A role for Ara ...... egulation of stomatal opening.
@en
prefLabel
From The Cover: A role for Ara ...... egulation of stomatal opening.
@ast
From The Cover: A role for Ara ...... egulation of stomatal opening.
@en
P2093
P2860
P356
P1476
From The Cover: A role for Ara ...... regulation of stomatal opening
@en
P2093
Qing-Hua Li
Yan-Chun Zhang
P2860
P304
12270-12275
P356
10.1073/PNAS.0501011102
P407
P50
P577
2005-08-10T00:00:00Z