FUNCTION AND MECHANISM OF ORGANIC ANION EXUDATION FROM PLANT ROOTS.
about
Use of plant growth-promoting bacteria for biocontrol of plant diseases: principles, mechanisms of action, and future prospects.Replace, reuse, recycle: improving the sustainable use of phosphorus by plantsMechanisms for cellular transport and release of allelochemicals from plant roots into the rhizosphereSynthesis, characterization, applications, and challenges of iron oxide nanoparticles.Association and linkage analysis of aluminum tolerance genes in maizeCalcium oxalate crystals in eucalypt ectomycorrhizae: morphochemical characterizationA genome-scale metabolic reconstruction of Pseudomonas putida KT2440: iJN746 as a cell factoryLow phosphate activates STOP1-ALMT1 to rapidly inhibit root cell elongationA conceptual model of root hair ideotypes for future agricultural environments: what combination of traits should be targeted to cope with limited P availability?A higher plant delta8 sphingolipid desaturase with a preference for (Z)-isomer formation confers aluminum tolerance to yeast and plants.Low pH, aluminum, and phosphorus coordinately regulate malate exudation through GmALMT1 to improve soybean adaptation to acid soils.Coordination between apoplastic and symplastic detoxification confers plant aluminum resistance.Metabolic evolution and the self-organization of ecosystemsCitrate transporters play a critical role in aluminium-stimulated citrate efflux in rice bean (Vigna umbellata) roots.Genome variations account for different response to three mineral elements between Medicago truncatula ecotypes Jemalong A17 and R108Ethylene negatively regulates aluminium-induced malate efflux from wheat roots and tobacco cells transformed with TaALMT1HvALMT1 from barley is involved in the transport of organic anionsTranscriptomic analysis reveals differential gene expression in response to aluminium in common bean (Phaseolus vulgaris) genotypes.Response of native soil microbial functions to the controlled mycorrhization of an exotic tree legume, Acacia holosericea in a Sahelian ecosystem.Phosphate depletion modulates auxin transport in Triticum aestivum leading to altered root branching.Modulation of citrate metabolism alters aluminum tolerance in yeast and transgenic canola overexpressing a mitochondrial citrate synthase.γ-Aminobutyric acid (GABA) signalling in plants.Specialized 'dauciform' roots of Cyperaceae are structurally distinct, but functionally analogous with 'cluster' roots.Molecular characterization of TaSTOP1 homoeologues and their response to aluminium and proton (H(+)) toxicity in bread wheat (Triticum aestivum L.).Genome-wide transcriptomic and phylogenetic analyses reveal distinct aluminum-tolerance mechanisms in the aluminum-accumulating species buckwheat (Fagopyrum tataricum).Auxin secretion by Bacillus amyloliquefaciens FZB42 both stimulates root exudation and limits phosphorus uptake in Triticum aestivium.Novel Set-Up for Low-Disturbance Sampling of Volatile and Non-volatile Compounds from Plant Roots.Effects of exogenous gibberellic acid3 on iron and manganese plaque amounts and iron and manganese uptake in rice.Quantitative trait loci and candidate gene mapping of aluminum tolerance in diploid alfalfaThe mitochondrial malate dehydrogenase 1 gene GhmMDH1 is involved in plant and root growth under phosphorus deficiency conditions in cotton.Global Transcriptome Analysis Reveals Distinct Aluminum-Tolerance Pathways in the Al-Accumulating Species Hydrangea macrophylla and Marker Identification.New roots for agriculture: exploiting the root phenome.Molecular Scanning and Morpho-Physiological Dissection of Component Mechanism in Lens Species in Response to Aluminium Stress.Microbiome and Exudates of the Root and Rhizosphere of Brachypodium distachyon, a Model for Wheat.Isolation and Characterization of an Aluminum-resistant Mutant in Rice.A miniature integrated multimodal sensor for measuring pH, EC and temperature for precision agriculture.Statistical Approaches for Gene Selection, Hub Gene Identification and Module Interaction in Gene Co-Expression Network Analysis: An Application to Aluminum Stress in Soybean (Glycine max L.).Root biomass and exudates link plant diversity with soil bacterial and fungal biomass.Plasma membrane anion channels in higher plants and their putative functions in roots.Nitrogen transformations in modern agriculture and the role of biological nitrification inhibition.
P2860
Q24533556-2E1CF014-1714-4038-81A4-C98930845CB5Q26859282-B7734D5A-8F7B-40B6-8B7F-4A8A10D1AAEFQ26866049-3AA03429-B074-4301-9B25-9673B86E2DDFQ27014954-9B01408E-E392-4C6B-9E45-B935722118B2Q28473501-4C4F34CD-F7FC-4263-9033-57ECD16A2E68Q28534468-49CDC1A5-9D9F-450C-BB8A-3E82AC7BD638Q28756812-2B3C8A25-14FF-4A22-985A-800BBC2A1217Q30313172-9292EA64-56B8-4535-855B-48CFC3ED5403Q30391343-93400D7B-6305-4B4D-9D81-CA12FE126ABCQ33289274-72D3C3C9-119E-4701-9D7B-B82BDC09AC64Q33355148-7487A327-A549-4214-92E6-11CD475AA1EAQ33356021-F65DD8BF-F9BC-450D-B1D4-4717E4F20E6DQ33569326-008DCF83-3BF5-4030-981C-58E87EDC3130Q33579412-89D50470-7B6A-44C3-84EE-2693536CBF8EQ33653458-8ADA2315-2193-44B4-8C86-189C8F3CBC6CQ33677352-E39F8894-16E9-4964-9EC5-29488C55772AQ33722406-612CAB91-C0AE-4105-951E-357C524DAF03Q33918794-14EB3C7C-BD84-4156-A814-7A2DBC815538Q33928839-ABBFE089-DE1D-4719-B443-ADC6A826746DQ34089384-5005E23B-5BBC-479E-9E36-030C2CE7CDEFQ34536119-B1A5C1F3-58D2-4E76-803D-A0AA45588371Q34544540-1EB4B701-E888-44AD-A2D4-109F9A3551F8Q34570317-8B41DC13-8475-41C5-9BC6-875D3AAE4445Q34986796-A9A1B8E7-C4DC-409F-8E1E-3DBAAF6BF27AQ35016311-CE2AA43D-1424-47AF-9D5A-AFF8C9D85185Q35099974-024AE094-5A64-4844-8665-17C594708BABQ35533779-0154E7BD-8B5A-41E8-AD8A-334EBEE5988CQ35566787-A540AAD5-47A5-4434-A046-016B80C62F43Q35650601-FADDAB88-4B93-41A4-9D77-C6E0D420AD93Q35856394-BB50991E-C9A2-4602-A4C9-800546D91442Q35867434-3FA725EE-3B04-4573-9F84-4F1D00A1A3D3Q35876460-D9BA8484-DB80-4B7F-B3FB-6F0718A90158Q36088354-95A2CECA-C5D5-447E-B0A8-AF5AAB2A6E7CQ36160472-9812B581-2B23-498D-9046-034F6E624B80Q36190609-1D541B2D-8E15-4634-9015-2F23B39C26DCQ36215454-54ADDC1B-5082-4FA9-9992-A66CA7E8F670Q36240390-2E39C98A-E4EC-4101-BF36-492BF33F20C4Q36333564-3C07F8D8-4A56-4AFE-8DF7-8A99807D2495Q36379567-CA43C4C6-744A-466E-8E36-57B203B06D68Q36393784-47D39E08-2DE6-4B21-B8DD-B6292A594CFE
P2860
FUNCTION AND MECHANISM OF ORGANIC ANION EXUDATION FROM PLANT ROOTS.
description
2001 nî lūn-bûn
@nan
2001 թուականի Յունիսին հրատարակուած գիտական յօդուած
@hyw
2001 թվականի հունիսին հրատարակված գիտական հոդված
@hy
2001年の論文
@ja
2001年論文
@yue
2001年論文
@zh-hant
2001年論文
@zh-hk
2001年論文
@zh-mo
2001年論文
@zh-tw
2001年论文
@wuu
name
FUNCTION AND MECHANISM OF ORGANIC ANION EXUDATION FROM PLANT ROOTS.
@ast
FUNCTION AND MECHANISM OF ORGANIC ANION EXUDATION FROM PLANT ROOTS.
@en
FUNCTION AND MECHANISM OF ORGANIC ANION EXUDATION FROM PLANT ROOTS.
@nl
type
label
FUNCTION AND MECHANISM OF ORGANIC ANION EXUDATION FROM PLANT ROOTS.
@ast
FUNCTION AND MECHANISM OF ORGANIC ANION EXUDATION FROM PLANT ROOTS.
@en
FUNCTION AND MECHANISM OF ORGANIC ANION EXUDATION FROM PLANT ROOTS.
@nl
prefLabel
FUNCTION AND MECHANISM OF ORGANIC ANION EXUDATION FROM PLANT ROOTS.
@ast
FUNCTION AND MECHANISM OF ORGANIC ANION EXUDATION FROM PLANT ROOTS.
@en
FUNCTION AND MECHANISM OF ORGANIC ANION EXUDATION FROM PLANT ROOTS.
@nl
P2093
P1476
FUNCTION AND MECHANISM OF ORGANIC ANION EXUDATION FROM PLANT ROOTS.
@en
P2093
P304
P356
10.1146/ANNUREV.ARPLANT.52.1.527
P577
2001-06-01T00:00:00Z