Nitrate transceptor(s) in plants. - Wikidata - wikimedia - TriplyDB

Nitrate transceptor(s) in plants.

Nitrate transceptor(s) in plants.

http://www.wikidata.org/entity/Q37829122

about

Phosphate Uptake and Allocation - A Closer Look at Arabidopsis thaliana L. and Oryza sativa L Metabolic regulation of triacylglycerol accumulation in the green algae: identification of potential targets for engineering to improve oil yield Molecular Mechanism Underlying the Plant NRT1.1 Dual-Affinity Nitrate Transporter Ion channels in plants Understanding nitrate assimilation and its regulation in microalgae A New Oidiodendron maius Strain Isolated from Rhododendron fortunei and its Effects on Nitrogen Uptake and Plant Growth A phospholipid uptake system in the model plant Arabidopsis thaliana.Unexpectedly low nitrogen acquisition and absence of root architecture adaptation to nitrate supply in a Medicago truncatula highly branched root mutant An RNA-Seq based gene expression atlas of the common bean.Nutrient sensing and signaling in the yeast Saccharomyces cerevisiae.The nitrate transporter (NRT) gene family in poplar.Phosphorus and nitrogen regulate arbuscular mycorrhizal symbiosis in Petunia hybrida Reduced frequency of lateral root branching improves N capture from low-N soils in maize.Nitrogen economics of root foraging: transitive closure of the nitrate-cytokinin relay and distinct systemic signaling for N supply vs. demand.Alanine aminotransferase variants conferring diverse NUE phenotypes in Arabidopsis thaliana.Multiple roles of nitrate transport accessory protein NAR2 in plants MADS-box transcription factor OsMADS25 regulates root development through affection of nitrate accumulation in rice.Phosphorus nutrition of phosphorus-sensitive Australian native plants: threats to plant communities in a global biodiversity hotspot Carbon: Nitrogen Interaction Regulates Expression of Genes Involved in N-Uptake and Assimilation in Brassica juncea L Knockdown of the partner protein OsNAR2.1 for high-affinity nitrate transport represses lateral root formation in a nitrate-dependent manner Succinic Semialdehyde Promotes Prosurvival Capability of Agrobacterium tumefaciens Searching iron sensors in plants by exploring the link among 2'-OG-dependent dioxygenases, the iron deficiency response and metabolic adjustments occurring under iron deficiency In scarcity and abundance: metabolic signals regulating cell growth Nitric oxide generated by nitrate reductase increases nitrogen uptake capacity by inducing lateral root formation and inorganic nitrogen uptake under partial nitrate nutrition in rice Low vapour pressure deficit affects nitrogen nutrition and foliar metabolites in silver birch Systems biology for enhanced plant nitrogen nutrition.Auxin and the integration of environmental signals into plant root development.Nitrogen metabolism meets phytopathology.Signal interactions in the regulation of root nitrate uptake.Common and specific responses to availability of mineral nutrients and water.Mutation of NRT1.1 enhances ammonium/low pH-tolerance in Arabiopsis thaliana.Global poplar root and leaf transcriptomes reveal links between growth and stress responses under nitrogen starvation and excess.NPKS uptake, sensing, and signaling and miRNAs in plant nutrient stress.A new insight into root responses to external cues: Paradigm shift in nutrient sensing.Hormones and nitrate: a two-way connection.Nitrogen sensing in legumes.Interactions between nitrate and ammonium in their uptake, allocation, assimilation, and signaling in plants.Effects of Parental Temperature and Nitrate on Seed Performance are Reflected by Partly Overlapping Genetic and Metabolic Pathways.The NRT2.5 and NRT2.6 genes are involved in growth promotion of Arabidopsis by the plant growth-promoting rhizobacterium (PGPR) strain Phyllobacterium brassicacearum STM196.Optimization of BY-2 cell suspension culture medium for the production of a human antibody using a combination of fractional factorial designs and the response surface method.

P2860

Q26738313-ECFE9880-4A1D-4C36-A6D9-C213AECF814D Q26769592-5E78EBAE-1BCA-4F12-AB67-DE7307D827BC Q26770723-E28C0F7C-8A91-4229-8235-AC789DA6E4BA Q26995173-B38D19A6-5841-49F1-BF12-C014D9B4610B Q28083852-AD64E116-C438-4A0F-B5AE-40859CDAE97A Q28829429-12C2D46F-E256-4DB0-9882-22E8CA648132 Q33361191-0C0FEBF8-F0D9-4196-AE8E-E5953BE23AC8 Q33677360-4E19F6BB-9C23-40CE-AD43-7C2EF18B1324 Q34333041-EA28D7C5-DBF4-4C39-82FB-53C26EF81928 Q34548962-8A7D9FB0-F6F5-41C1-A84B-80C5C2072326 Q34973346-C158928B-F98F-4C54-B77B-608AAE1FE787 Q35114845-FE867A9A-3D02-4810-A015-6FE4EB7B9949 Q35230166-9B07A85E-5185-4348-B8BF-4CE0C6E1A622 Q35546864-626F055A-25C9-40F6-AEAB-163E3B670646 Q35591879-B21D61E7-5D29-44BA-A053-DF7932CDDE0C Q35671990-25112850-8D69-4F61-8CE0-8B9CBBBE2DE8 Q35741418-70170959-0F45-42FE-A854-C4B13C9829B0 Q36049960-5D789BD0-3987-469A-A02F-F7C879E707EC Q36135830-A4C4FE2C-D8F6-4EB9-8210-EC9AFDB3EF38 Q36353462-037861C9-C6C5-4795-9EEA-92D9C0C0A28F Q36634938-8C57D6C5-E466-4BDD-B02A-92A59CC4AE35 Q36888600-4A39081D-28EB-4B88-AB82-2A0AC4403BA1 Q37158492-C98A4CD3-E088-4E8C-98C1-9A43219718E0 Q37179836-18DB05EA-C391-4A5E-8986-2F468B22FD45 Q37635510-A6E4FA26-33F6-4E92-854F-0B527B0746FA Q38022607-C12A76FF-C879-498A-84CA-9C828091AAAD Q38153668-236BAFE9-7623-408D-826E-2F0F697BA59E Q38235658-4941E7CB-56BA-417B-AD2F-AF06F76B6151 Q38244113-96EE3B96-036F-490E-9ECA-52ECEAEFBD08 Q38362137-FB115F6F-34A3-404B-B7ED-411BAE1A2BA5 Q38411064-975CE4E1-9F20-4800-92CA-671BA55D0C2E Q38457012-6361F7D2-F625-4642-BD8D-4D6ED6ABCED9 Q38530654-EF947829-8E99-4038-948A-5EB6FE997D53 Q38543071-EB38B14A-0C1D-49FA-97A0-23BB09DB5A58 Q38785137-3E0BF844-DD18-440E-84E1-0F5AB71BDF32 Q39032329-616DC248-756B-4861-8FF7-4A4C68633759 Q39051083-022A4FA2-68A0-471C-919B-8F433B35AE8C Q39060966-DD6D1DE7-5492-489E-8F4B-A28A9B0C52B4 Q39126036-5714E30B-8759-4D8F-97A5-31C12D1CEFC9 Q39145795-77FB00C9-F1E8-4989-8996-5358ECA23C13

P2860

Nitrate transceptor(s) in plants.

http://www.wikidata.org/entity/Q37829122

description

article científic

@ca

article scientifique

@fr

articolo scientifico

@it

artigo científico

@pt

bilimsel makale

@tr

scientific article published on 14 January 2011

@en

vedecký článok

@sk

vetenskaplig artikel

@sv

videnskabelig artikel

@da

vědecký článek

@cs

name

Nitrate transceptor

@nl

Nitrate transceptor(s) in plants.

@en

type

label

Nitrate transceptor

@nl

Nitrate transceptor(s) in plants.

@en

prefLabel

Nitrate transceptor

@nl

Nitrate transceptor(s) in plants.

@en

P1433

Q37829122-2E0E3295-3021-4F7B-98A6-BCFA1AD34203

P1476

Q37829122-6A24C87C-CDC8-4B86-8A77-BAC7F65858DB

P2093

Q37829122-20820257-FED7-4D63-A899-F4991249D4DD

Q37829122-39567C3A-27E3-4B03-A80E-A0901F96D333

Q37829122-3AFF0477-2089-4CAF-85C8-BA0B6A15D891

Q37829122-C248098E-FDB4-49BD-812F-8D5A5A1DD48C

P2860

Q37829122-0003432D-6083-43FB-8DDF-CFCC5396DDE8

Q37829122-005C84A9-352C-43F9-B460-42492D9BE3FD

Q37829122-037D7B6E-E33F-496E-826D-128D16C49E1D

Q37829122-0C28EC1F-B6FF-4408-ABDE-E87EAFAA8260

Q37829122-0E4913A7-BEFB-43F5-84E6-82B1C3D2100D

Q37829122-14D62E8C-FDA1-49C8-90A8-ACACFF97ED5D

Q37829122-18F33549-0984-4693-A1CC-1C9C87F4EFFD

Q37829122-1950387F-E4DF-43F3-AA72-5DA492BE1FC9

Q37829122-330D883B-27FF-4CF0-87EF-375E99B0AFC6

Q37829122-36EACB70-D7A2-45A2-8C7B-A1D6447DDAFF

P304

Q37829122-10E39FAE-D8E8-4DC1-964E-CC349F84D033

P31

Q37829122-BEF65600-222C-4745-9F77-E632446AC8AB

P356

Q37829122-22C4BDDE-D305-4579-8980-C84ED1A35184

P433

Q37829122-4AB93DB7-628F-40A7-8108-6B5F8DEAAA66

P478

Q37829122-850DC297-8436-4593-B656-B595B4F41925

P577

Q37829122-A8D4CCEA-685D-4D87-ACC5-E37CEC62BC6D

P5875

Q37829122-9DB8D6F5-5AB6-4009-BE8E-808450109A79

P698

Q37829122-64804061-4AE4-4EA2-8E0A-9C17AF7426EF

P356

P1433

Journal of Experimental Botany

P1476

Nitrate transceptor(s) in plants.

@en

P2093

Alain Gojon

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

Edith Laugier

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

Francine Perrine-Walker

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

Gabriel Krouk

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

P2860

Transport and signaling through the phosphate-binding site of the yeast Pho84 phosphate transceptor

The MEP2 ammonium permease regulates pseudohyphal differentiation in Saccharomyces cerevisiae.

The herbicide sensitivity gene CHL1 of Arabidopsis encodes a nitrate-inducible nitrate transporter

Environmental regulation of lateral root initiation in Arabidopsis

A system biology approach highlights a hormonal enhancer effect on regulation of genes in a nitrate responsive "biomodule".

Transcript profiling in the chl1-5 mutant of Arabidopsis reveals a role of the nitrate transporter NRT1.1 in the regulation of another nitrate transporter, NRT2.1.

Major alterations of the regulation of root NO(3)(-) uptake are associated with the mutation of Nrt2.1 and Nrt2.2 genes in Arabidopsis.

Dual pathways for regulation of root branching by nitrate

The Arabidopsis dual-affinity nitrate transporter gene AtNRT1.1 (CHL1) is activated and functions in nascent organ development during vegetative and reproductive growth.

A putative transporter is essential for integrating nutrient and hormone signaling with lateral root growth and nodule development in Medicago truncatula.

P304

2299-2308

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

P31

scholarly article

P356

10.1093/JXB/ERQ419

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

P433

7

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

P478

62

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

P577

2011-01-14T00:00:00Z

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

P5875

49759729

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

P698

21239382

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