Iterative Group Analysis (iGA): a simple tool to enhance sensitivity and facilitate interpretation of microarray experimentsGraph-based iterative Group Analysis enhances microarray interpretationVector analysis as a fast and easy method to compare gene expression responses between different experimental backgroundsPlant responses to abiotic stress: The chromatin context of transcriptional regulationBiodesalination: a case study for applications of photosynthetic bacteria in water treatment.Natural variation of Arabidopsis root architecture reveals complementing adaptive strategies to potassium starvation.Learning from evolution: Thellungiella generates new knowledge on essential and critical components of abiotic stress tolerance in plants.Potassium channels in barley: cloning, functional characterization and expression analyses in relation to leaf growth and development.Potassium deficiency induces the biosynthesis of oxylipins and glucosinolates in Arabidopsis thalianaCoronatine-insensitive 1 (COI1) mediates transcriptional responses of Arabidopsis thaliana to external potassium supply.Pollen development and fertilization in Arabidopsis is dependent on the MALE GAMETOGENESIS IMPAIRED ANTHERS gene encoding a type V P-type ATPase.The effect of potassium nutrition on pest and disease resistance in plants.Histone deacetylase complex1 expression level titrates plant growth and abscisic acid sensitivity in Arabidopsis.Food for thought: how nutrients regulate root system architectureHyperosmotic priming of Arabidopsis seedlings establishes a long-term somatic memory accompanied by specific changes of the epigenome.EZ-Rhizo: integrated software for the fast and accurate measurement of root system architecture.Nitrate reductase mutation alters potassium nutrition as well as nitric oxide-mediated control of guard cell ion channels in Arabidopsis.Stomatal clustering in Begonia associates with the kinetics of leaf gaseous exchange and influences water use efficiencyThe potassium-dependent transcriptome of Arabidopsis reveals a prominent role of jasmonic acid in nutrient signaling.Multilevel analysis of primary metabolism provides new insights into the role of potassium nutrition for glycolysis and nitrogen assimilation in Arabidopsis roots.Transcriptome analysis of root transporters reveals participation of multiple gene families in the response to cation stress.Stomatal Spacing Safeguards Stomatal Dynamics by Facilitating Guard Cell Ion Transport Independent of the Epidermal Solute Reservoir.The Histone Deacetylase Complex 1 Protein of Arabidopsis Has the Capacity to Interact with Multiple Proteins Including Histone 3-Binding Proteins and Histone 1 Variants.Analysis of the Root System Architecture of Arabidopsis Provides a Quantitative Readout of Crosstalk between Nutritional Signals.Chromatin and Epigenetics.Na+ transport in Acetabularia bypasses conductance of plasmalemma.Abiotic stress and plant genome evolution. Search for new modelsContrasting nutrient-disease relationships: Potassium gradients in barley leaves have opposite effects on two fungal pathogens with different sensitivities to jasmonic acidElectrophysiological characterization of pathways for K+uptake into growing and non-growing leaf cells of barleyEngineering mannitol biosynthesis in Escherichia coli and Synechococcus sp. PCC 7002 using a green algal fusion proteinPhysiology and metabolismThellungiella halophila, a salt-tolerant relative of Arabidopsis thaliana, has specific root ion-channel features supporting K+/Na+ homeostasis under salinity stressThe role of calcium sensor-interacting protein kinases in plant adaptation to potassium-deficiency: new answers to old questionsLotus tenuis tolerates combined salinity and waterlogging: maintaining O2 transport to roots and expression of an NHX1-like gene contribute to regulation of Na+ transportPhenotyping jasmonate regulation of root growthThe twins K+ and Na+ in plantsEZ-Root-VIS: A Software Pipeline for the Rapid Analysis and Visual Reconstruction of Root System ArchitectureCryptic variation in RNA-directed DNA-methylation controls lateral root development when auxin signalling is perturbedTo respond or not to respond? Natural variation of root architectural responses to nutrient signalsK+-Selective inward-rectifying channels and apoplastic pH in barley roots
P50
Q24796175-5F326E57-0215-431A-9F52-86A120F2AC70Q24797743-1E20E542-7A71-4869-8609-075D8186AB88Q24815182-747B3472-4DA3-44D1-85AE-A90CF919CEF2Q26739703-B07AC65B-3DE2-4BDE-97C9-ABFDDF6B4CA6Q30773562-C657057E-9083-4D0D-B2F2-BA406B6C638AQ33355085-45487300-A011-4784-9690-1A2266D924A4Q33468465-7C15424A-680B-4493-8385-4801297749FAQ33493572-5E165559-6F8B-4ED0-A30B-1BB1FCF1C088Q33654805-FB168ED0-4295-4A9A-BD36-E75C26A4F4D8Q33754131-25C55FDF-A924-4BEF-8ECA-807E117F7817Q34133649-D36B3CEE-37A8-45F3-953B-8978BEAA2A6BQ37106613-5613B993-251C-4824-B7D6-BD07A0006319Q39350671-540625D3-A32E-43B4-828A-DD0E9E4E1C9AQ39411271-1976D40D-1EDD-452F-9B11-A88FED29D2B0Q39428700-80CC51C2-8AB4-4C32-8393-775A052BA7FDQ40028698-EA83D366-5DC1-473D-AFCE-2FE163F21E8AQ40385236-694715B4-66F1-4E5C-AE75-8ECB6E76A64AQ42239945-2CB6FDB1-ABEE-434B-A536-E93B84CD9AD3Q45044383-59D11390-2233-46FE-81D3-9FAE0145F47BQ46061178-568454ED-0E1C-40C4-8006-400DD80645ACQ47631547-3A6D689F-AE6E-4DCB-9039-3008E96933D5Q48163103-F14D7AF0-E8FA-4675-A374-5B5A8F89B04BQ49066861-90630243-C007-4137-8805-681CBCE1787BQ50673337-49028CC3-6277-4CE9-B2FD-7D05165552A6Q51819970-B60ACFB6-962C-4275-AFA5-388C4CF834CBQ52513656-87C713A8-8E73-4F4B-9851-47C722711085Q56899412-D945047C-6CF5-4120-9305-2E1731672ED3Q57400491-D18B9432-D9B4-447E-88DA-E0E06DEF85EDQ58166263-A6831BF6-56FB-4A0F-8594-F88363CD416CQ58573181-5E956D43-CF34-43A0-9E04-3FB535B898B0Q61060281-AC5D5CDB-FB54-44F4-8940-C20E77E3AB77Q79276586-C761C6A9-D772-4475-BA9F-730D39F70A4EQ80477481-1DBDCCEE-9C34-4482-9E8A-9CA1B9A26FEDQ84159943-31631C8D-D507-4F39-B9D6-0B19ACEFF325Q86652491-F41C231E-6F01-45B9-ACCC-38080447BD49Q87839182-E7293305-9DC6-4769-AB1F-4803B39D735FQ89080997-596A7388-2350-4A44-BFC3-A783C1D6F32CQ92563657-24549071-0D85-40C2-B045-F560F9D80222Q94002683-239AF6C9-D367-4D68-AF69-2AA7531C9C47Q95299986-0D7DF26B-7E54-4118-B59F-5C425E4A9F49
P50
description
Professor for Molecular Plant Physiology
@en
wetenschapper
@nl
name
Anna Amtmann
@ast
Anna Amtmann
@en
Anna Amtmann
@es
Anna Amtmann
@nl
type
label
Anna Amtmann
@ast
Anna Amtmann
@en
Anna Amtmann
@es
Anna Amtmann
@nl
prefLabel
Anna Amtmann
@ast
Anna Amtmann
@en
Anna Amtmann
@es
Anna Amtmann
@nl
P106
P1153
6601955352
P21
P31
P496
0000-0001-8533-121X