about
The tiny eukaryote Ostreococcus provides genomic insights into the paradox of plankton speciationThe effects of bacterial volatile emissions on plant abiotic stress toleranceThree-Dimensional Reconstruction, by TEM Tomography, of the Ultrastructural Modifications Occurring in Cucumis sativus L. Mitochondria under Fe DeficiencyCrystallographic snapshots of iterative substrate translocations during nicotianamine synthesis in archaeaThe metalloreductase Fre6p in Fe-efflux from the yeast vacuole.Involvement of Iron-Containing Proteins in Genome Integrity in Arabidopsis ThalianaAn extracellular siderophore is required to maintain the mutualistic interaction of Epichloƫ festucae with Lolium perenneExposure to nitric oxide protects against oxidative damage but increases the labile iron pool in sorghum embryonic axesFacing the challenges of Cu, Fe and Zn homeostasis in plantsMonoubiquitin-dependent endocytosis of the iron-regulated transporter 1 (IRT1) transporter controls iron uptake in plants.Identification of a novel iron regulated basic helix-loop-helix protein involved in Fe homeostasis in Oryza sativaA roadmap for zinc trafficking in the developing barley grain based on laser capture microdissection and gene expression profiling.Early iron-deficiency-induced transcriptional changes in Arabidopsis roots as revealed by microarray analyses.Identification of up-regulated genes in flag leaves during rice grain filling and characterization of OsNAC5, a new ABA-dependent transcription factor.A new family of ferritin genes from Lupinus luteus--comparative analysis of plant ferritins, their gene structure, and evolution.Getting a sense for signals: regulation of the plant iron deficiency response.Expression profiling of the 14-3-3 gene family in response to salt stress and potassium and iron deficiencies in young tomato (Solanum lycopersicum) roots: analysis by real-time RT-PCR.Variation and inheritance of iron reductase activity in the roots of common bean (Phaseolus vulgaris L.) and association with seed iron accumulation QTL.Dealing with iron metabolism in rice: from breeding for stress tolerance to biofortificationProteomic characterization of iron deficiency responses in Cucumis sativus L. roots.Mobilization of vacuolar iron by AtNRAMP3 and AtNRAMP4 is essential for seed germination on low iron.Iron deficiency affects nitrogen metabolism in cucumber (Cucumis sativus L.) plantsUpdate on plant ionomics.The Pseudomonas fluorescens Siderophore Pyoverdine Weakens Arabidopsis thaliana Defense in Favor of Growth in Iron-Deficient Conditions.Metal movement within the plant: contribution of nicotianamine and yellow stripe 1-like transporters2'-Deoxymugineic acid promotes growth of rice (Oryza sativa L.) by orchestrating iron and nitrate uptake processes under high pH conditionsGenome-wide association studies identifies seven major regions responsible for iron deficiency chlorosis in soybean (Glycine max).Genome-wide association mapping of iron homeostasis in the maize association populationRNA sequencing of Populus x canadensis roots identifies key molecular mechanisms underlying physiological adaption to excess zincElevation of NO production increases Fe immobilization in the Fe-deficiency roots apoplast by decreasing pectin methylation of cell wall.The Organization of Controller Motifs Leading to Robust Plant Iron HomeostasisAugmenting iron accumulation in cassava by the beneficial soil bacterium Bacillus subtilis (GBO3).A novel soil manganese mechanism drives plant species loss with increased nitrogen deposition in a temperate steppe.Carbon Monoxide Interacts with Auxin and Nitric Oxide to Cope with Iron Deficiency in Arabidopsis.The Iron Assimilatory Protein, FEA1, from Chlamydomonas reinhardtii Facilitates Iron-Specific Metal Uptake in Yeast and Plants.Enhanced plant tolerance to iron starvation by functional substitution of chloroplast ferredoxin with a bacterial flavodoxinFEA1, FEA2, and FRE1, encoding two homologous secreted proteins and a candidate ferrireductase, are expressed coordinately with FOX1 and FTR1 in iron-deficient Chlamydomonas reinhardtii.Brassinosteroids are involved in response of cucumber (Cucumis sativus) to iron deficiencyPost-Transcriptional Coordination of the Arabidopsis Iron Deficiency Response is Partially Dependent on the E3 Ligases RING DOMAIN LIGASE1 (RGLG1) and RING DOMAIN LIGASE2 (RGLG2)Organization and function of the plant pleiotropic drug resistance ABC transporter family.
P2860
Q22066332-20C5BBAA-C050-46B6-92E7-AC0D7268697BQ26781176-16BCF743-05B4-431D-A04D-9255CC91AF59Q27304886-15E75264-6A87-41E8-A28E-86D676647CEBQ27657686-26E24C13-E90F-4C54-84EB-B9A4144B3BBAQ27940317-D50B225E-5AA6-404F-AD46-AA92B78469F8Q28084415-830D86CE-53A0-49CC-8A4E-DC0CBA0059ECQ28487486-2076E661-BA48-4CF8-B22D-12252239AAA4Q28756680-644AB87D-9AE5-418F-9F6B-37B4FC46C54FQ30499973-7157B9C2-36D2-44D2-A367-1761155FD07FQ30503486-BBA7F9EE-869E-4016-A573-8D5C20A6AF45Q30986964-843EDA77-A418-4DD0-96D5-41AD3DA06524Q33419598-3917737F-CF35-47AE-9D5B-196D4EDA6F31Q33427192-738CEB1D-863C-446B-A1A5-DD6C02AB8735Q33495608-5418D06D-E8AF-4BAA-BDA8-0E56D59ADFA0Q33499614-349D4D48-CBCB-42A5-B568-BA585F1E13E8Q33558892-F8917E24-5D73-4F93-AFD0-E8E58A7B1B43Q33579088-F77CBCC8-0582-44E7-A83A-842F4BC19CE0Q33710968-BAB7A8F3-E092-4A57-83CE-13A5B7E803F3Q33749127-A0E08284-E821-4C06-A1BA-08D2581D6C65Q33759942-7AFEDC63-37E9-473F-B31A-84AE92449B27Q34324866-8731BBEE-9ABA-431A-8B05-B562C78D5348Q34443747-C33C0518-89B1-440E-9D7F-8B81C4E8FB44Q34550973-4823DC84-F37A-4810-808D-85A13ED66970Q34676119-CB56279A-5728-42FB-BA92-7C8BBEBC4C05Q34870428-DCB11FAA-6D34-4B58-98B4-474E90888F6FQ35022947-767D39CF-7B20-4A65-86F6-3A1C739B77FAQ35254940-442EA6D5-3F34-4827-937D-D4A3AAA70CC4Q35551531-B9A42F4E-1C95-421D-A59C-69E1ECA70DFEQ35559434-F25FC08C-51AF-432D-A3D1-94A43CD164CFQ35739880-96ECB316-8AA0-4E02-A7C9-D615E04CA26AQ35901788-8071F9B5-6938-4738-BFF5-7D85AEAFB072Q35916286-79061E92-95D0-4674-B814-FA09E563745DQ35968010-127A2943-C7E0-49C1-A461-68D9200199DAQ35970081-026F8DDB-A1D0-4AA3-AE2D-4F34A9BB6918Q35970517-D4EBFB94-9A23-4840-B12A-1A5642D2A0E2Q36090239-43BA54D1-5E81-48E0-8471-F7316F09828FQ36095329-EF56B0F0-7482-4F54-BF0B-2CEC01EEB217Q36104648-879C020B-EE1B-404A-8869-52F9E2139BEDQ36134007-4ABF5124-7C3D-4225-B046-3D5D7722417BQ36408708-914FE950-83A5-4069-BD62-CDF8AC81755C
P2860
description
2003 nĆ® lÅ«n-bĆ»n
@nan
2003 Õ©ÕøÖÕ”ÕÆÕ”Õ¶Õ« Õ
ÕøÖÕ¶ÕøÖÕ”ÖÕ«Õ¶ Õ°ÖÕ”ÕæÕ”ÖÕ”ÕÆÕøÖÕ”Õ® Õ£Õ«ÕæÕ”ÕÆÕ”Õ¶ ÕµÖ
Õ¤ÕøÖÕ”Õ®
@hyw
2003 Õ©Õ¾Õ”ÕÆÕ”Õ¶Õ« Õ°ÕøÖÕ¶Õ¾Õ”ÖÕ«Õ¶ Õ°ÖÕ”ÕæÕ”ÖÕ”ÕÆÕ¾Õ”Õ® Õ£Õ«ÕæÕ”ÕÆÕ”Õ¶ Õ°ÕøÕ¤Õ¾Õ”Õ®
@hy
2003幓ć®č«ę
@ja
2003幓č«ę
@yue
2003幓č«ę
@zh-hant
2003幓č«ę
@zh-hk
2003幓č«ę
@zh-mo
2003幓č«ę
@zh-tw
2003幓č®ŗę
@wuu
name
Iron transport and signaling in plants.
@ast
Iron transport and signaling in plants.
@en
type
label
Iron transport and signaling in plants.
@ast
Iron transport and signaling in plants.
@en
prefLabel
Iron transport and signaling in plants.
@ast
Iron transport and signaling in plants.
@en
P1476
Iron transport and signaling in plants.
@en
P2093
Catherine Curie
Jean-FranƧois Briat
P304
P356
10.1146/ANNUREV.ARPLANT.54.031902.135018
P577
2003-01-01T00:00:00Z