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Root anatomical phenes associated with water acquisition from drying soil: targets for crop improvementModel-assisted integration of physiological and environmental constraints affecting the dynamic and spatial patterns of root water uptake from soilsRoot suberin forms an extracellular barrier that affects water relations and mineral nutrition in ArabidopsisAn updated model for nitrate uptake modelling in plants. I. Functional component: cross-combination of flow-force interpretation of nitrate uptake isotherms, and environmental and in planta regulation of nitrate influxDirigent domain-containing protein is part of the machinery required for formation of the lignin-based Casparian strip in the root.High-resolution isotope measurements resolve rapid ecohydrological dynamics at the soil-plant interface.Transpiration from shoots triggers diurnal changes in root aquaporin expression.The role of ABA and the transpiration stream in the regulation of the osmotic water permeability of leaf cells.Aquaporin-mediated increase in root hydraulic conductance is involved in silicon-induced improved root water uptake under osmotic stress in Sorghum bicolor L.The exodermis: a variable apoplastic barrier.Identification and expression of nine oak aquaporin genes in the primary root axis of two oak species, Quercus petraea and Quercus roburRoot apoplastic barriers block Na+ transport to shoots in rice (Oryza sativa L.).Breaking conceptual locks in modelling root absorption of nutrients: reopening the thermodynamic viewpoint of ion transport across the root.Silicon enhanced salt tolerance by improving the root water uptake and decreasing the ion toxicity in cucumber.Plant xylem hydraulics: What we understand, current research, and future challenges.Silicon moderated the K deficiency by improving the plant-water status in sorghumIn low transpiring conditions, uncoupling the BnNrt2.1 and BnNrt1.1 NO 3(-) transporters by glutamate treatment reveals the essential role of BnNRT2.1 for nitrate uptake and the nitrate-signaling cascade during growth.Trait-based model development to support breeding programs. A case study for salt tolerance and rice.Genome-wide identification, characterization, and expression profile of aquaporin gene family in flax (Linum usitatissimum).Carbon dioxide and water transport through plant aquaporins.Water transport and energy.Applying 'drought' to potted plants by maintaining suboptimal soil moisture improves plant water relationsRoot architecture and hydraulic conductance in nutrient deprived Pistacia lentiscus L. seedlings.Drought-induced root aerenchyma formation restricts water uptake in rice seedlings supplied with nitrate.In low transpiring conditions, nitrate and water fluxes for growth of B. napus plantlets correlate with changes in BnNrt2.1 and BnNrt1.1 transporter expressionWater uptake by seminal and adventitious roots in relation to whole-plant water flow in barley (Hordeum vulgare L.).Zinc uptake and radial transport in roots of Arabidopsis thaliana: a modelling approach to understand accumulation.Estimation of the hydraulic conductivities of lupine roots by inverse modelling of high-resolution measurements of root water uptake.Rapid changes in root hydraulic conductivity and aquaporin expression in rice (Oryza sativa L.) in response to shoot removal - xylem tension as a possible signalImplications of a zinc uptake and transport model.An ABC Transporter Is Involved in the Silicon-Induced Formation of Casparian Bands in the Exodermis of Rice.Root hydraulic conductivity and adjustments in stomatal conductance: hydraulic strategy in response to salt stress in a halotolerant species.Phenotypic plasticity and water flux rates of Citrus root orders under salinity.Water and solute permeabilities of Arabidopsis roots in relation to the amount and composition of aliphatic suberinVirtual Plants Need Water Too: Functional-Structural Root System Models in the Context of Drought Tolerance Breeding.Radial transport of salt and water in roots of the common reed (Phragmites australis Trin. ex Steudel).Aquaporin-facilitated water uptake in barley (Hordeum vulgare L.) rootsA series RCL circuit theory for analyzing non-steady-state water uptake of maize plants.Hydraulic conductivity of rice roots.A cohesion/tension mechanism explains the gating of water channels (aquaporins) in Chara internodes by high concentration.
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Q26830054-DDF7C382-899F-47FD-BA3D-4FCF47FE86DDQ27709696-780C32BA-F59A-4DD4-B29D-95828BA5841EQ28475483-5DA8C8E4-6E6B-4F59-A525-A18EB865CE46Q28658417-70CCD34A-F709-4F0D-A76F-52A9F92AF6EBQ30544043-2A18CC48-E0FC-46DB-8086-2144557A5204Q31044164-CF3CE6C0-FA74-471E-9A96-126049556D40Q33849360-D1270119-0E9B-4632-B20B-E44BF3156552Q33950437-8DF7B2A8-A33C-4E57-A3EC-69B52CC0902AQ34089287-60F0400E-3277-4155-98BC-12EB5B4D046BQ34439992-7A4CA9E3-2076-40A9-8109-613831F81002Q34532364-B6AD5434-EAE0-4B32-A4E9-E78BB408D6DFQ35157060-AD0F6A1A-7C2E-4521-AB82-6EA262C3ED47Q35558861-C6C5135F-64F8-4355-8607-2A2DADE91D34Q36097533-3B1B0C77-6F15-4077-A01D-33A0A998E05EQ36308729-7E5B1E8F-81E2-4E00-B6D3-3BA0A0B72D76Q36670924-E0863BD1-9D32-4DB4-BA10-510879EFFEF6Q36852207-76811A2B-1B0D-4528-8065-27B7C9E967AEQ38703738-69C45BBC-860D-4830-A74C-14DEA9FEAB4CQ38817548-F752B365-3A62-49CC-9673-074259E45F5CQ38980365-9688035A-C402-449C-835C-8FD57F197C64Q38984561-19A11511-9F05-4808-B019-149C570E6A08Q39371981-B75D610F-2427-4D38-92E9-BADB3F548443Q39534843-04A9A193-33DD-41CE-90C0-7C5C778BEEF3Q39613673-D1583AAA-0FD5-43C2-AD9A-4060AA4722A8Q40797350-0436C7CA-63F9-4C0C-A169-D213EF6EE494Q41209364-FD9D8981-BB48-4298-8959-02B4E45F5960Q41369658-89B8F1E4-4A51-4499-8960-E6837A85EE97Q41632185-F52FF526-8319-419F-9D43-C751A38E2187Q41632190-99C16DFE-2995-4597-8B62-1AB8780A6F14Q41899165-26AE8FAD-1288-4131-9E9B-AA320B0FF6B4Q41937516-CACA26CC-BF1B-481F-BF65-77CA1BD21B5AQ41956724-6FE98613-62AC-49D8-8EC8-F179AAEF13DBQ42039972-E487BC48-6115-4850-92FA-1B503CAD0E6DQ42185468-B995FC3F-DB44-4C20-B0C6-2EF19903CB1EQ42251858-2474F9AE-F056-4021-B9C0-7063510A33D9Q42435639-242E18D6-4F03-43A7-9296-AB08191EE5ACQ42861354-21E898E6-ACC9-4A09-A1DB-225E01D43F25Q42955865-922C50B5-965B-4A01-A7D0-3A6967F88F21Q43718590-BE7A55F3-79A2-44FF-96BC-AE844C646021Q44739105-1A4C7AE1-0CFE-42A2-AF99-6130A0D99A88
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description
im Januar 2000 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована у 2000
@uk
type
P356
P1433
P2888
P356
10.1023/A:1026439226716
P577
2000-01-01T00:00:00Z
P6179
1032184139