Copper and iron homeostasis in Arabidopsis: responses to metal deficiencies, interactions and biotechnological applications.
about
Temporal aspects of copper homeostasis and its crosstalk with hormonesFacing the challenges of Cu, Fe and Zn homeostasis in plantsPhloem small RNAs, nutrient stress responses, and systemic mobility.Microarray analysis of Arabidopsis plants in response to allelochemical L-DOPA.Molecular and functional analyses of COPT/Ctr-type copper transporter-like gene family in riceTranscriptomic and metabolomic analysis of copper stress acclimation in Ectocarpus siliculosus highlights signaling and tolerance mechanisms in brown algaeTranscriptomic and physiological characterization of the fefe mutant of melon (Cucumis melo) reveals new aspects of iron-copper crosstalk.Conservation and diversity of microRNA-associated copper-regulatory networks in Populus trichocarpa.MicroRNA-mediated systemic down-regulation of copper protein expression in response to low copper availability in Arabidopsis.SQUAMOSA Promoter Binding Protein-Like7 Is a Central Regulator for Copper Homeostasis in Arabidopsis.Functional characterisation of Arabidopsis SPL7 conserved protein domains suggests novel regulatory mechanisms in the Cu deficiency response.Unravelling molecular responses to moderate dehydration in harvested fruit of sweet orange (Citrus sinensis L. Osbeck) using a fruit-specific ABA-deficient mutantStructural Insights into the Nucleotide-Binding Domains of the P1B-type ATPases HMA6 and HMA8 from Arabidopsis thaliana.Overexpression of Arabidopsis ATX1 retards plant growth under severe copper deficiency.Comparative transcriptome analysis of grapevine in response to copper stress.Functional Evolution in the Plant SQUAMOSA-PROMOTER BINDING PROTEIN-LIKE (SPL) Gene Family.Transition metal transport.Copper: an essential metal in biologyIron uptake and transport in plants: the good, the bad, and the ionome.Rice NICOTIANAMINE SYNTHASE 2 expression improves dietary iron and zinc levels in wheat.Phytoextraction of toxic metals: a central role for glutathione.Investigation of copper homeostasis in plant cells by fluorescence lifetime imaging microscopy.kNACking on heaven's door: how important are NAC transcription factors for leaf senescence and Fe/Zn remobilization to seeds?Phenotypic and molecular consequences of overexpression of metal-homeostasis genes.Photosynthetic complex stoichiometry dynamics in higher plants: environmental acclimation and photosynthetic flux control.Too much is bad--an appraisal of phytotoxicity of elevated plant-beneficial heavy metal ions.Identification of negative cis-acting elements in response to copper in the chloroplastic iron superoxide dismutase gene of the moss Barbula unguiculata.Comparison of global responses to mild deficiency and excess copper levels in Arabidopsis seedlings.Transporters, chaperones, and P-type ATPases controlling grapevine copper homeostasis.COPT2, a plasma membrane located copper transporter, is involved in the uptake of Au in Arabidopsis.Regulation of copper homeostasis and biotic interactions by microRNA 398b in common beanCOPT6 is a plasma membrane transporter that functions in copper homeostasis in Arabidopsis and is a novel target of SQUAMOSA promoter-binding protein-like 7Identification and characterization of a novel copper transporter gene family TaCT1 in common wheat.Rosette iron deficiency transcript and microRNA profiling reveals links between copper and iron homeostasis in Arabidopsis thaliana.The CTR/COPT-dependent copper uptake and SPL7-dependent copper deficiency responses are required for basal cadmium tolerance in A. thaliana.Optimal copper supply is required for normal plant iron deficiency responses.The Cth2 ARE-binding protein recruits the Dhh1 helicase to promote the decay of succinate dehydrogenase SDH4 mRNA in response to iron deficiency.Arabidopsis SUMO E3 ligase SIZ1 is involved in excess copper tolerance.Loss of function of Arabidopsis C-terminal domain phosphatase-like1 activates iron deficiency responses at the transcriptional level.The bacterial pathogen Xanthomonas oryzae overcomes rice defenses by regulating host copper redistribution.
P2860
Q28083385-D7112DDA-6A8B-4F1B-9C40-62EF5EE6B2DEQ30499973-D7EB3413-06FD-4C33-9CF5-E09291A81BABQ33553852-C7410E4E-AB86-4EED-AFAA-401E17706246Q33729497-B094CD01-25EC-4479-BC41-3F2C0B94208FQ33878936-8AE42FC2-CBA0-4925-B485-21560FDBD286Q33938766-F4721395-2F43-4871-9967-AEFBBA1609E2Q33983344-7EB4DD2B-17F3-49F0-96E6-5215936D7303Q34225834-6B478BF3-4DE7-41AB-B073-BC0012FC29C6Q34769588-5516EECD-D921-493D-B9A5-E3000AF68E01Q34914954-638BE697-3058-46F3-8729-693C185481A2Q35245755-56F40478-233F-4AA5-B868-3F1F297BD600Q35940326-F8A6F2E0-98F6-40CC-866B-9435555CE64EQ36179334-D6CDC3B4-4FBA-4942-BC78-5177D5208561Q36373144-26F20A9B-687A-4724-9A5B-5671F6232990Q36379659-CCEB16DF-6AB2-4F0A-AA6F-84D4490A3F6FQ36742628-95F6F36D-1554-462E-864C-5422D21FCA6AQ36803080-8BFB5068-D4B8-432D-B97E-BDE1273669DAQ37031388-0834FFD0-8344-4F01-8EBE-9256C4DDE22CQ37393353-F60E90C7-4171-413B-B8A9-47E72DC2C512Q37604164-1D3CF885-C954-4EFF-93BA-2A44104F0ED9Q37864372-3F9A9A93-2A6A-4DC6-B068-46828EC91B3DQ38002341-96259CB8-539B-4CD8-8B4F-83ABF2B53188Q38121080-A0CE100B-F3D2-4E35-9018-5DC967F74CB2Q38196805-3C03EBF2-FD0A-4D14-A120-A93A7EBB9590Q38214669-CE1B4D23-6E30-474A-B828-0B22AA2C4B2FQ38269408-8E5638D3-1901-4C7A-971E-6D673A4C3EC5Q38293738-E48DECBF-281F-4416-B6E8-6207344EA5C8Q38317365-62532220-1EC6-4C2D-A43D-96394BEFB67BQ40857744-23E3506D-6E96-4195-B59F-609F11E3C0C1Q41195615-CB58A52B-7913-459D-8897-1F16948A4FACQ41853506-2E621353-5757-49B2-8F55-0D9F25B820A4Q42011013-28CB7B7F-FB23-41F8-9695-97478D8883A0Q42246586-B83867D5-C29A-4634-8979-6784E88E9EAEQ42433677-216B07DD-0D79-4FE3-852D-3BF567B6CAF6Q42441096-B57AA2A5-0B60-4C4E-A25C-E9546B62D794Q42729675-D3974980-037D-4E8E-86D7-CB89361BE525Q43234009-03E25622-D67D-4CDE-8B74-82D01A9E17DCQ43911256-58208B6A-E10F-428E-B69F-3339888BF62DQ45395761-5FF76033-EBF9-4B0D-B8D9-ADBD006FB7AFQ45577367-1FC15818-FF90-4BB4-94EE-CA111CFC38CD
P2860
Copper and iron homeostasis in Arabidopsis: responses to metal deficiencies, interactions and biotechnological applications.
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
2007年论文
@zh
2007年论文
@zh-cn
name
Copper and iron homeostasis in ...... biotechnological applications.
@ast
Copper and iron homeostasis in ...... biotechnological applications.
@en
type
label
Copper and iron homeostasis in ...... biotechnological applications.
@ast
Copper and iron homeostasis in ...... biotechnological applications.
@en
prefLabel
Copper and iron homeostasis in ...... biotechnological applications.
@ast
Copper and iron homeostasis in ...... biotechnological applications.
@en
P2093
P1476
Copper and iron homeostasis in ...... biotechnological applications.
@en
P2093
Antoni García-Molina
Lola Peñarrubia
Nuria Andrés-Colás
Sergi Puig
P304
P356
10.1111/J.1365-3040.2007.01642.X
P577
2007-03-01T00:00:00Z