Iron uptake and transport in plants: the good, the bad, and the ionome. - Wikidata - awgldk - TriplyDB

Iron uptake and transport in plants: the good, the bad, and the ionome.

Iron uptake and transport in plants: the good, the bad, and the ionome.

http://www.wikidata.org/entity/Q37393353

about

Transition Metal Transport in Plants and Associated Endosymbionts: Arbuscular Mycorrhizal Fungi and Rhizobia Chloroplast Iron Transport Proteins - Function and Impact on Plant Physiology A Survey of Plant Iron Content-A Semi-Systematic Review Epigenetic regulation of iron homeostasis in Arabidopsis New insights into the role of siderophores as triggers of plant immunity: what can we learn from animals?Canga biodiversity, a matter of mining.Dealing with iron metabolism in rice: from breeding for stress tolerance to biofortification Plant Fe status affects the composition of siderophore-secreting microbes in the rhizosphere TcOPT3, a member of oligopeptide transporters from the hyperaccumulator Thlaspi caerulescens, is a novel Fe/Zn/Cd/Cu transporter Recent insights into iron homeostasis and their application in graminaceous crops.Metabolome analysis of Arabidopsis thaliana roots identifies a key metabolic pathway for iron acquisition.Long-distance transport, vacuolar sequestration, tolerance, and transcriptional responses induced by cadmium and arsenic.Integration of P, S, Fe, and Zn nutrition signals in Arabidopsis thaliana: potential involvement of PHOSPHATE STARVATION RESPONSE 1 (PHR1).Synchrotron X-ray microfluorescence measurement of metal distributions in Phragmites australis root system in the Yangtze River intertidal zone.Post-Transcriptional Coordination of the Arabidopsis Iron Deficiency Response is Partially Dependent on the E3 Ligases RING DOMAIN LIGASE1 (RGLG1) and RING DOMAIN LIGASE2 (RGLG2)Temperature Effects on Biomass and Regeneration of Vegetation in a Geothermal Area Circadian clock adjustment to plant iron status depends on chloroplast and phytochrome function.Using μPIXE for quantitative mapping of metal concentration in Arabidopsis thaliana seeds.Pattern of iron distribution in maternal and filial tissues in wheat grains with contrasting levels of iron.Acidobacteria strains from subdivision 1 act as plant growth-promoting bacteria.Autophagy as a possible mechanism for micronutrient remobilization from leaves to seeds.The Challenges and Opportunities Associated with Biofortification of Pearl Millet (Pennisetum glaucum) with Elevated Levels of Grain Iron and Zinc.Fixating on metals: new insights into the role of metals in nodulation and symbiotic nitrogen fixation.Pathways of iron acquisition and utilization in Leishmania.Metal species involved in long distance metal transport in plants.Computer vision and machine learning for robust phenotyping in genome-wide studies Two bHLH Transcription Factors, bHLH34 and bHLH104, Regulate Iron Homeostasis in Arabidopsis thaliana.A turn-on fluorescent probe based on hydroxylamine oxidation for detecting ferric ion selectively in living cells.Expression of cadR Enhances its Specific Activity for Cd Detoxification and Accumulation in Arabidopsis.GABA accretion reduces Lsi-1 and Lsi-2 gene expressions and modulates physiological responses in Oryza sativa to provide tolerance towards arsenic.Genome-Wide Identification and Expression Analysis of NRAMP Family Genes in Soybean (Glycine Max L.).Alterations of iron distribution in Arabidopsis tissues infected by Dickeya dadantii.Brassinosteroids are involved in Fe homeostasis in rice (Oryza sativa L.).The expression of heterologous Fe (III) phytosiderophore transporter HvYS1 in rice increases Fe uptake, translocation and seed loading and excludes heavy metals by selective Fe transport.Natural allelic variation of FRO2 modulates Arabidopsis root growth under iron deficiency.The function of hydrogen sulphide in iron availability: Sulfur nutrient or signaling molecule?Atypical iron storage in marine brown algae: a multidisciplinary study of iron transport and storage in Ectocarpus siliculosus.Finger on the Pulse: Pumping Iron into Chickpea.Sphingolipids in the root play an important role in regulating the leaf ionome in Arabidopsis thaliana.Systems and trans-system level analysis identifies conserved iron deficiency responses in the plant lineage.

P2860

Q26741509-BC775F94-754D-4B90-971D-D2DB4A7DD6A0 Q26750996-B4662D78-BD64-49C8-A202-87832BB53B32 Q26774199-8B121653-979C-4720-AB4C-CDE9CB79AC6D Q26809951-90950375-65E8-443F-A913-2BC19019B5B2 Q26827090-B868C314-EC06-4AFA-B58B-0FE8420B5B79 Q30390067-825B84BF-E2E1-4F8D-8260-F0831DF3CF0B Q33749127-FBC03964-BB9A-46D1-B2D5-9BF3F9EC957D Q33811502-D061B7F9-3795-485D-9B63-9D8818D65E94 Q34325724-08EFA42D-E6F6-45FE-898A-63776C03990B Q34561892-E6B05145-2987-4F1B-8127-67A98FF69976 Q35212436-EDE64519-ABD3-4893-8109-09EFD18B46D5 Q35318151-83D6AABA-ECB1-4677-8210-E7F4DEA44A7B Q35545436-7D6599FA-522E-4495-A7CD-5DEAEA35C399 Q36064639-2CC47B13-7F15-42C9-88E2-AFB97B9DD23B Q36134007-031206E2-BD4F-4A8A-94CF-ED3E8BA6E8FF Q36317135-51DD7791-F926-438F-8E89-4CE0D92C4110 Q36628875-A8E19910-E6FA-40EB-9D1B-3566D624EC41 Q36893745-6793EF19-54C8-421B-8E6C-82E78D1A4A46 Q37069209-FE7D47BD-9B02-4B58-804A-BB346ACF4303 Q37366295-61092526-83B3-45B9-938C-CC9C18332A33 Q37510924-7B09504F-B97B-4136-8664-D5A92DE00598 Q37528473-E3647497-D939-4811-8CB7-E5210FA90B63 Q37581546-9E720A4A-1F69-4375-B069-5774973D439A Q38130388-1FFCEABA-C62E-4FF0-AC26-37BB973E6014 Q38203879-C6C60057-FF6F-4A29-AF02-A68C8C675F9E Q38921290-355D05B6-2DE8-46EE-814C-38C8D921145C Q39177194-DB972F4A-2E76-44A7-80F9-F1A35BC210B8 Q39363115-EA9F07B4-8526-4ED6-91BF-35D49743F7E7 Q40665619-3C22DB68-2EFC-4BD6-843E-021E2406777E Q41459450-B3905CC2-C14B-4226-B3A9-A06D0CD0C256 Q41463238-38B59243-AC6E-4568-AD69-77665CEDD758 Q41722580-365CA506-D9AB-4150-846C-F72AF8747EBF Q41747385-1328FA13-908A-4F8F-8395-9840EAF96ADF Q41833026-6E5E8CBA-92AB-4AE8-B8A5-1DA87BE427C9 Q42223437-B9576400-938A-4E0C-9DB5-C9E046B8B685 Q42380838-B08B2173-BB50-4C40-816F-A5A923EA3A76 Q42433690-CD9EF74C-8B34-4466-AE24-CAACFC697EC6 Q42657928-181B07D8-4479-4E91-AADD-990E31167D52 Q42745500-F4C8A429-216F-4AF1-9D3B-6840D8271D08 Q42773427-DC977B50-BE18-4DB3-9C30-73E11A9C38C1

P2860

Iron uptake and transport in plants: the good, the bad, and the ionome.

http://www.wikidata.org/entity/Q37393353

description

article científic

@ca

article scientifique

@fr

articolo scientifico

@it

artigo científico

@pt

bilimsel makale

@tr

scientific article published on October 2009

@en

vedecký článok

@sk

vetenskaplig artikel

@sv

videnskabelig artikel

@da

vědecký článek

@cs

name

Iron uptake and transport in plants: the good, the bad, and the ionome.

@en

Iron uptake and transport in plants: the good, the bad, and the ionome.

@nl

type

label

Iron uptake and transport in plants: the good, the bad, and the ionome.

@en

Iron uptake and transport in plants: the good, the bad, and the ionome.

@nl

prefLabel

Iron uptake and transport in plants: the good, the bad, and the ionome.

@en

Iron uptake and transport in plants: the good, the bad, and the ionome.

@nl

P1433

Q37393353-183F19BF-F2D3-4F29-A56D-CFE0C581FE2F

P1476

Q37393353-5DE607F6-EF3E-4391-BA8B-26A3233001C5

P2093

Q37393353-5FF1EF9C-39BF-4694-B1E5-A772BFCB3CFB

P2860

Q37393353-019E11B6-1B4D-429A-AF35-F0105ECF51E0

Q37393353-0559B84C-01DF-46B9-85A4-95C78A7FB65A

Q37393353-065B429C-BEA1-4A15-9EEB-28A1301BB8A7

Q37393353-07B1E93B-4422-4372-B610-142596128A95

Q37393353-097A3164-40D2-4F5E-AF12-F49562B22FE8

Q37393353-09C3BA3D-1ECF-4330-940F-7B6B5A5E6530

Q37393353-0B7B03B8-CCE8-4E4E-9200-CDF65F9936AE

Q37393353-0BE7E59E-8A92-4C5D-8AEF-34FE098BB9DE

Q37393353-0CA35EDE-C99D-4E21-8240-4D18D5398927

Q37393353-0DEC1B3D-F649-4140-AC84-A9FC06417385

P304

Q37393353-E5CE9DCD-80AD-4FB2-BE6A-1F45AF5AB8C5

P31

Q37393353-F6D7D76F-3CF7-4B23-B207-013A4C97D4BE

P356

Q37393353-B9A65041-0310-404D-B17B-20DF97FFC330

P433

Q37393353-4D428E99-3261-4ED8-879C-9530B4D450B9

P478

Q37393353-CAAF6E7D-1A2D-4777-B930-372F7551BAA5

P50

Q37393353-0193BC34-EE1B-4B3E-AF8D-D69CD822C7E7

P577

Q37393353-C2ACA6FD-A210-47E9-9813-CF4706622BC2

P5875

Q37393353-9E0136C5-87BC-4F4D-BC9F-299FE2324820

P698

Q37393353-2F062407-14E5-4908-A85D-CA355A3B6BFE

P932

Q37393353-DBB1FE4A-DC1E-41EB-BE34-B0AA2CB88CD3

P356

P1433

Chemical Reviews

P1476

Iron uptake and transport in plants: the good, the bad, and the ionome.

@en

P2093

Joe Morrissey

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

P2860

The poly(C)-binding proteins: a multiplicity of functions and a search for mechanisms.

The ABC transporter Atm1p is required for mitochondrial iron homeostasis.

Structure and differential expression of the four members of the Arabidopsis thaliana ferritin gene family

A human mitochondrial ferritin encoded by an intronless gene

Deoxymugineic acid increases Zn translocation in Zn-deficient rice plants

Purdue ionomics information management system. An integrated functional genomics platform.

(52)Fe translocation in barley as monitored by a positron-emitting tracer imaging system (PETIS): evidence for the direct translocation of Fe from roots to young leaves via phloem.

Two iron-regulated cation transporters from tomato complement metal uptake-deficient yeast mutants.

Maize yellow stripe1 encodes a membrane protein directly involved in Fe(III) uptake.

Evidence for the presence of ferritin in plant mitochondria.

P304

4553-4567

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

P31

scholarly article

P356

10.1021/CR900112R

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

P433

10

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

P478

109

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

P50

Mary Lou Guerinot

P577

2009-10-01T00:00:00Z

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

P5875

26812088

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

P698

19754138

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

P932

2764373

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