Acquisition of phosphorus and nitrogen in the rhizosphere and plant growth promotion by microorganisms
about
Large-scale sequestration of atmospheric carbon via plant roots in natural and agricultural ecosystems: why and howBiological nitrogen fixation in non-legume plantsNitrogen signalling in plant interactions with associative and endophytic diazotrophic bacteriaA model to explain plant growth promotion traits: a multivariate analysis of 2,211 bacterial isolatesPhosphorus mobilizing consortium Mammoth P(™) enhances plant growthA conceptual model of root hair ideotypes for future agricultural environments: what combination of traits should be targeted to cope with limited P availability?An In vitro Study of Bio-Control and Plant Growth Promotion Potential of Salicaceae Endophytes.The physiology of invasive plants in low-resource environmentsEndophytic microbes Bacillus sp. LZR216-regulated root development is dependent on polar auxin transport in Arabidopsis seedlings.Identification of extracellular glycerophosphodiesterases in Pseudomonas and their role in soil organic phosphorus remineralisationMicrobial community responses to organophosphate substrate additions in contaminated subsurface sediments.Changes in the bacterial community of soybean rhizospheres during growth in the fieldFusarium oxysporum and its bacterial consortium promote lettuce growth and expansin A5 gene expression through microbial volatile organic compound (MVOC) emission.Abscisic Acid Regulates Auxin Homeostasis in Rice Root Tips to Promote Root Hair Elongation.The rhizosphere microbiota of plant invaders: an overview of recent advances in the microbiomics of invasive plants.Bacterial biosynthesis of 1-aminocyclopropane-1-caboxylate (ACC) deaminase, a useful trait to elongation and endophytic colonization of the roots of rice under constant flooded conditions.Plant root transcriptome profiling reveals a strain-dependent response during Azospirillum-rice cooperationThe rhizosphere microbiome: significance of plant beneficial, plant pathogenic, and human pathogenic microorganisms.Nitrogen loss by anaerobic oxidation of ammonium in rice rhizosphereSystemic colonization of clover (Trifolium repens) by Clostridium botulinum strain 2301.Plant growth promotion induced by phosphate solubilizing endophytic Pseudomonas isolates.Transplanting Soil Microbiomes Leads to Lasting Effects on Willow Growth, but not on the Rhizosphere MicrobiomeBacterial Diversity and Community Structure in Two Bornean Nepenthes Species with Differences in Nitrogen Acquisition Strategies.Genome size and ploidy influence angiosperm species' biomass under nitrogen and phosphorus limitationDevelopment of a method for detection and quantification of B. brongniartii and B. bassiana in soil.Community composition and activity of anaerobic ammonium oxidation bacteria in the rhizosphere of salt-marsh grass Spartina alterniflora.Plant Growth Promoting Rhizobacteria and Silicon Synergistically Enhance Salinity Tolerance of Mung Bean.Insight into the effects of different cropping systems on soil bacterial community and tobacco bacterial wilt rate.Crop management as a driving force of plant growth promoting rhizobacteria physiology.Microbiome and Exudates of the Root and Rhizosphere of Brachypodium distachyon, a Model for Wheat.Maize growth responses to soil microbes and soil properties after fertilization with different green manures.Plant species differ in early seedling growth and tissue nutrient responses to arbuscular and ectomycorrhizal fungi.Diversity of Bacillus-like bacterial community in the sediments of the Bamenwan mangrove wetland in Hainan, China.Bacillus aryabhattai SRB02 tolerates oxidative and nitrosative stress and promotes the growth of soybean by modulating the production of phytohormones.P accumulation and physiological responses to different high P regimes in Polygonum hydropiper for understanding a P-phytoremediation strategy.Crop acquisition of phosphorus, iron and zinc from soil in cereal/legume intercropping systems: a critical reviewMedicago truncatula Gaertn. as a model for understanding the mechanism of growth promotion by bacteria from rhizosphere and nodules of alfalfaLife in an arsenic-containing gold mine: genome and physiology of the autotrophic arsenite-oxidizing bacterium rhizobium sp. NT-26Fluorescent Pseudomonas Strains with only Few Plant-Beneficial Properties Are Favored in the Maize Rhizosphere.Melatonin-Producing Endophytic Bacteria from Grapevine Roots Promote the Abiotic Stress-Induced Production of Endogenous Melatonin in Their Hosts
P2860
Q26850157-2F5634CB-73B6-4012-8459-5DAF7F21F305Q27014863-1EEC908B-EC68-49A9-938B-D2BF45D58726Q27025019-7C9EFC26-FAB3-4165-9540-3D563A18590BQ28542880-1CDD09D6-ED6A-4DA4-9B0F-33F408AFA858Q28829919-5602CB70-63FC-4035-BA92-953C1CC212C4Q30391343-A3C740B7-D833-4B44-A0FA-ED7BB7EB80DCQ30841651-988493A7-69C9-4A49-953F-618F60524D0AQ31107584-73A68B9B-C687-4E80-9B20-157EF1CC65DBQ33360102-D80085CD-6031-4D92-A5AB-5D3D820E22B2Q33708487-A86AB7C4-A66D-4A38-92F9-12ED59BB0A83Q33784337-866E5956-3C5D-4F2C-8CA4-7CF23F447960Q33793642-13FE8F73-3F0E-4B8C-899D-9DED8D999CC0Q33799728-0D050CEA-4033-4CA9-A87B-8D0D27429C8DQ33843283-1772E445-771E-4B82-9B1B-09630564B0BBQ33937998-D889C78F-62E4-4944-B353-015A1E77A5EDQ34288343-AAD3E693-E4D0-4F97-A681-67C2865B1990Q34462561-75E59ECA-B3C0-4664-B0C1-2ECA623F1EF5Q34780579-9C822F21-D6A7-452F-A0F3-8E4BB99882D7Q35562605-04E8B41A-5FF9-4061-85E1-13EF39F5EE1FQ35845993-F978AB41-71D6-48E4-A8C7-CE54B1D35928Q35877095-57057AF9-2424-4035-9D43-4463414BBF17Q35886351-3D0B7DAA-1DAA-4A7B-A8FB-9D82FEEAF6C1Q35899262-6E9D7124-2BED-480A-B163-AA18632F7D2FQ35923462-BAAA3838-E4D8-4B25-BA35-244E50F97771Q35956736-2F320537-4A0C-44A1-B45E-87FC8E544FD0Q36029635-EF5FA0BB-1756-4E1E-B8D4-5C249A0C141FQ36068036-FA771301-C85D-4C8B-B9F5-C1F88D964E32Q36137305-EDCAD622-42F7-488F-85FF-2DCD4D3CA60CQ36139272-CECB1405-727E-45FA-B74A-3E62F33FD2AAQ36160472-55CFC90B-C3FE-4FD4-86FC-3DBF05BB4330Q36183681-14A9BC34-BE1C-4C68-BD53-23B3CEEFD7F5Q36190947-0A830AA0-8894-4CFD-A674-E9F35AD1BB0AQ36273890-A0DFA652-633D-4957-B8F1-50D90C9BD807Q36304230-35035AD9-FCBA-4F26-8D44-EE9318065139Q36356812-23D1510C-8358-465F-B5A6-06245B7C5A02Q36613120-9861CD56-40B0-4EF5-B837-75B79D91B824Q36814427-9288E0B7-7A0D-4C6C-973C-C8346AC7DF76Q36905244-B9E51D47-E763-4446-8F1C-F1FCF6C73198Q37201868-85BBAB28-DFB1-4046-831D-6A3C6416DBE3Q37270573-B01BF14C-39B3-4DF3-B5F6-29B8F144611F
P2860
Acquisition of phosphorus and nitrogen in the rhizosphere and plant growth promotion by microorganisms
description
article
@en
im Februar 2009 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в лютому 2009
@uk
name
Acquisition of phosphorus and ...... th promotion by microorganisms
@en
Acquisition of phosphorus and ...... th promotion by microorganisms
@nl
type
label
Acquisition of phosphorus and ...... th promotion by microorganisms
@en
Acquisition of phosphorus and ...... th promotion by microorganisms
@nl
prefLabel
Acquisition of phosphorus and ...... th promotion by microorganisms
@en
Acquisition of phosphorus and ...... th promotion by microorganisms
@nl
P2093
P2860
P1433
P1476
Acquisition of phosphorus and ...... th promotion by microorganisms
@en
P2093
Alan E. Richardson
Ann M. McNeill
Claire Prigent-Combaret
José-Miguel Barea
P2860
P2888
P304
P356
10.1007/S11104-009-9895-2
P577
2009-02-27T00:00:00Z