Auxin, ethylene and brassinosteroids: tripartite control of growth in the Arabidopsis hypocotyl. - Wikidata - wikimedia - TriplyDB

Auxin, ethylene and brassinosteroids: tripartite control of growth in the Arabidopsis hypocotyl.

Auxin, ethylene and brassinosteroids: tripartite control of growth in the Arabidopsis hypocotyl.

http://www.wikidata.org/entity/Q46455222

about

Tomato BRASSINOSTEROID INSENSITIVE1 is required for systemin-induced root elongation in Solanum pimpinellifolium but is not essential for wound signaling A current perspective on the role of AGCVIII kinases in PIN-mediated apical hook development Ethylene and Hormonal Cross Talk in Vegetative Growth and Development Hormonal networks involved in apical hook development in darkness and their response to light Hypocotyl adventitious root organogenesis differs from lateral root development Differential growth at the apical hook: all roads lead to auxin Comparative proteomics indicates that biosynthesis of pectic precursors is important for cotton fiber and Arabidopsis root hair elongation.Transcriptome profiling, molecular biological, and physiological studies reveal a major role for ethylene in cotton fiber cell elongation.Chemical genetic dissection of brassinosteroid-ethylene interaction Regulation of ACS protein stability by cytokinin and brassinosteroid Glucose and phytohormone interplay in controlling root directional growth in Arabidopsis.Patatin-related phospholipase pPLAIIIδ influences auxin-responsive cell morphology and organ size in Arabidopsis and Brassica napus Petiole hyponasty: an ethylene-driven, adaptive response to changes in the environment.Coordinated regulation of apical hook development by gibberellins and ethylene in etiolated Arabidopsis seedlings The plant growth promoting substance, lumichrome, mimics starch, and ethylene-associated symbiotic responses in lotus and tomato roots.Ethylene promotes hyponastic growth through interaction with ROTUNDIFOLIA3/CYP90C1 in Arabidopsis.Diurnal regulation of plant growth.Characterization of tub4(P287L) , a β-tubulin mutant, revealed new aspects of microtubule regulation in shade.Temporal transcriptional response to ethylene gas drives growth hormone cross-regulation in Arabidopsis.Ethylene acts as a negative regulator of glucose induced lateral root emergence in Arabidopsis Three related receptor-like kinases are required for optimal cell elongation in Arabidopsis thaliana.Ethylene and hydrogen peroxide are involved in brassinosteroid-induced salt tolerance in tomato.How ethylene works in the reproductive organs of higher plants: a signaling update from the third millennium.Anatomy and transcript profiling of gynoecium development in female sterile Brassica napus mediated by one alien chromosome from Orychophragmus violaceus.Analysis of apical hook formation in Alaska pea with a 3-D clinostat and agravitropic mutant ageotropum.Physiological regulation and functional significance of shade avoidance responses to neighbors.Ethylene in vegetative development: a tale with a riddle.Computational modelling of the BRI1 receptor system.The Arabidopsis thaliana hypocotyl, a model to identify and study control mechanisms of cellular expansion.Jasmonate-activated MYC2 represses ETHYLENE INSENSITIVE3 activity to antagonize ethylene-promoted apical hook formation in Arabidopsis.Molecular mechanisms and ecological function of far-red light signalling.Gene transcript profiles in the desert plant Nitraria tangutorum during fruit development and ripening.Protein expression changes during cotton fiber elongation in response to drought stress and recovery.Transcriptional Regulation of Brassinosteroid Accumulation during Carrot Development and the Potential Role of Brassinosteroids in Petiole Elongation.When the time is ripe.How calmodulin binding transcription activators (CAMTAs) mediate auxin responses.Function of Arabidopsis hexokinase-like1 as a negative regulator of plant growth Growing in darkness: The etiolated lupin hypocotyls Comparison of the transcriptome between two cotton lines of different fiber color and quality.Dehydration and vernalization treatments identify overlapping molecular networks impacting endodormancy maintenance in leafy spurge crown buds.

P2860

Q24678059-BBFCE978-8B3F-4D2D-BE40-E218C90DB08C Q26779165-11ABE1E3-BE4A-469C-9FEF-FBDD96114D57 Q26800287-5A6FC90A-3CA1-4372-B708-CA57363B5CDB Q26824441-B27D0BEC-BC10-4644-8E47-E2A421D5CA6F Q26853517-33173901-3FBC-4F99-9E1E-72402A84C85C Q27008361-69762E1C-A536-4636-A733-EEBD9EADC77E Q30984112-7043F733-E6C6-413E-A29D-71E380A0FBED Q33233225-4DD38C30-BC95-4FA2-BC2D-EE82F7D652D2 Q33510298-97BAC09E-07FD-49DE-96D9-383455FC9C80 Q33594359-3DB3B436-951D-4930-BE89-9D8071CAD53E Q34372895-4C58B538-2DED-42B8-9440-D9FB7BA12A7F Q34622327-C18E1A97-7DB4-47C9-BE90-121AB1EC6244 Q35646127-78891F0E-806B-45B8-8D58-7B84D5ACEE10 Q35932362-AB2F88D7-2598-4699-82CE-F59681A92D6E Q36021375-4FFB1752-6A3E-4D66-9880-29285ED87425 Q36523817-119A3BD8-A2C5-4AF6-B8D9-0B834A478F83 Q36642377-8B4953CC-022A-4C7B-84DB-E4D568628935 Q36653770-C1BB892B-B068-4DD6-AD74-02644A0CB50A Q36920993-F8C6A13E-9248-4586-B968-E5162AFF8718 Q36944344-490598F2-283F-4224-9E89-154F421ABE8D Q37183167-FB9D3F20-08EE-4216-AEB0-F695A08C2E4E Q37339736-97E6D331-E6AA-4310-BE3F-3CFBA61B1AEE Q37514917-3EFEB06E-2D20-4062-8977-2A1F5F5293CB Q37595484-9C6B4427-4A45-4E2E-8571-80D6D3384A44 Q37702519-5E61CE1A-6BE0-4915-8FA6-241B6E3210E4 Q37734081-7FC4CBC1-2708-492C-800A-D96A87DAF142 Q37992179-536A9D99-9493-49D4-BEAF-1329C76A7E12 Q38082805-5A93261A-DD57-4CC2-A0FD-494D81A8A993 Q38196366-70A011D5-B7BD-481A-BB2F-B9CADF496957 Q38308198-75394987-4383-4431-ADF2-46229E4B5D5A Q39094905-CB1532F3-EBAC-4373-8A6A-28314DD98F4E Q39573957-C770A159-AE77-4F36-ACA0-2862A2EB684A Q39629395-8C2A1645-632D-4AD6-A2F0-B1BC6CB2E682 Q41370698-B089DD6A-8EEF-4D8B-B03B-B21D7E2DAA3A Q41574113-4274D077-71C8-40E0-9014-4B215E1B7238 Q41777770-F33F8322-EDF3-4138-94A4-9E84F1AC09A8 Q42105952-312739F4-3513-4098-92E0-F5D32324C8B4 Q42207297-291ABF49-ABCE-422A-B7FB-5AFFEA7DB988 Q43009682-EF3C8EA9-ED1B-4F22-B5F8-FF746F5E3852 Q44311710-ED832C00-6FCF-440A-AA3F-2C941AF213C2

P2860

Auxin, ethylene and brassinosteroids: tripartite control of growth in the Arabidopsis hypocotyl.

http://www.wikidata.org/entity/Q46455222

description

2005 nî lūn-bûn

@nan

2005年の論文

@ja

2005年学术文章

@wuu

2005年学术文章

@zh

2005年学术文章

@zh-cn

2005年学术文章

@zh-hans

2005年学术文章

@zh-my

2005年学术文章

@zh-sg

2005年學術文章

@yue

2005年學術文章

@zh-hant

name

Auxin, ethylene and brassinost ...... in the Arabidopsis hypocotyl.

@en

Auxin, ethylene and brassinost ...... in the Arabidopsis hypocotyl.

@nl

type

label

Auxin, ethylene and brassinost ...... in the Arabidopsis hypocotyl.

@en

Auxin, ethylene and brassinost ...... in the Arabidopsis hypocotyl.

@nl

prefLabel

Auxin, ethylene and brassinost ...... in the Arabidopsis hypocotyl.

@en

Auxin, ethylene and brassinost ...... in the Arabidopsis hypocotyl.

@nl

P1433

Q46455222-AD0E8306-F20B-4749-BFD9-8DAED985AD71

P1476

Q46455222-A76305C1-8DC5-4DF0-8C47-1D4ACDEA62F7

P2093

Q46455222-0103A338-DBF6-4258-9A2B-1C0486FA6D2D

Q46455222-0DDCDC3E-B7B3-48E1-84E5-00DB7DB12F91

Q46455222-13AD9571-BAF0-44F2-A801-F18271D00C31

Q46455222-2C5CD0A7-F5A0-4255-9C21-C10222564BB2

P2860

Q46455222-027A9B0C-E318-46EE-9FD4-5729B9CEAC68

Q46455222-0A78FD29-AD6D-4D2D-A6F4-8881006EDFC4

Q46455222-1A6DCF29-749D-429B-84C3-B38C6ACF108F

Q46455222-1AA3D830-DFDF-41D4-8223-D1B94FDD1A64

Q46455222-232F427C-21DC-46A5-8C9B-3E63C9146F7D

Q46455222-28D340C0-21ED-4E02-996F-8467D82C07C6

Q46455222-35B48448-071B-4497-8EE0-CF99989BCC77

Q46455222-372CE72D-8F6C-4178-B01A-852214708BBE

Q46455222-37E88224-C35F-4987-B7E9-42A671B23938

Q46455222-380C2807-7A4F-45F7-A59A-A0C87E1234BE

P304

Q46455222-90947653-3D2A-44D1-A5EA-220E630B0DBF

P31

Q46455222-1E611AAC-58A3-488B-99BB-889000735E30

P356

Q46455222-19B8E38E-0568-424C-8DD9-A07C84653A4B

P433

Q46455222-8A130CF3-8B25-4A02-9795-654106490FD5

P478

Q46455222-07A73D2D-31EA-44BB-9AB1-3355DDF38F10

P50

Q46455222-060C1944-FFB9-40A6-A8E9-CFD9B8E095D3

P577

Q46455222-AA9D0076-B078-4179-8EC9-0F38615A6911

P698

Q46455222-DB72413E-70C7-45FA-BE0A-BB22A741ACAB

P356

P1433

Plant and Cell Physiology

P1476

Auxin, ethylene and brassinost ...... in the Arabidopsis hypocotyl.

@en

P2093

Filip Vandenbussche

http://www.w3.org/2001/XMLSchema#string

Klaus Palme

http://www.w3.org/2001/XMLSchema#string

Liesbeth De Grauwe

http://www.w3.org/2001/XMLSchema#string

Olaf Tietz

http://www.w3.org/2001/XMLSchema#string

P2860

Interdependency of brassinosteroid and auxin signaling in Arabidopsis

Lateral relocation of auxin efflux regulator PIN3 mediates tropism in Arabidopsis

Arabidopsis mutants in the C-S lyase of glucosinolate biosynthesis establish a critical role for indole-3-acetaldoxime in auxin homeostasis

BIN2, a new brassinosteroid-insensitive locus in Arabidopsis

Localization of the auxin permease AUX1 suggests two functionally distinct hormone transport pathways operate in the Arabidopsis root apex

The Arabidopsis AMP1 gene encodes a putative glutamate carboxypeptidase.

Ethylene-mediated enhancement of apical hook formation in etiolated Arabidopsis thaliana seedlings is gibberellin dependent.

Auxin promotes Arabidopsis root growth by modulating gibberellin response.

Local, efflux-dependent auxin gradients as a common module for plant organ formation.

Gravity-regulated differential auxin transport from columella to lateral root cap cells.

P304

827-836

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1093/PCP/PCI111

http://www.w3.org/2001/XMLSchema#string

P433

6

http://www.w3.org/2001/XMLSchema#string

P478

46

http://www.w3.org/2001/XMLSchema#string

P50

Dominique Van Der Straeten

P577

2005-04-25T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P698

15851402

http://www.w3.org/2001/XMLSchema#string