scholarly article | Q13442814 |
P50 | author | Johannes A. Postma | Q57420868 |
P2093 | author name string | Jonathan P Lynch | |
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Root cortical aerenchyma improves the drought tolerance of maize (Zea mays L.). | Q39630992 | ||
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Effect of phosphorus availability on basal root shallowness in common bean | Q77311738 | ||
How Do Plants Achieve Tolerance to Phosphorus Deficiency? Small Causes with Big Effects | Q79267836 | ||
Trade-off between root porosity and mechanical strength in species with different types of aerenchyma | Q80095692 | ||
Is root growth under phosphorus deficiency affected by source or sink limitations? | Q81777361 | ||
Decreased Ethylene Biosynthesis, and Induction of Aerenchyma, by Nitrogen- or Phosphate-Starvation in Adventitious Roots of Zea mays L | Q83268759 | ||
P433 | issue | 5 | |
P407 | language of work or name | English | Q1860 |
P921 | main subject | phosphorus | Q674 |
P1104 | number of pages | 13 | |
P304 | page(s) | 829-841 | |
P577 | publication date | 2010-10-22 | |
P1433 | published in | Annals of Botany | Q1821243 |
P1476 | title | Theoretical evidence for the functional benefit of root cortical aerenchyma in soils with low phosphorus availability | |
P478 | volume | 107 |
Q64252568 | An Integrative Systems Perspective on Plant Phosphate Research |
Q50169836 | Buffered delivery of phosphate to Arabidopsis alters responses to low phosphate. |
Q89456893 | Co-optimization of axial root phenotypes for nitrogen and phosphorus acquisition in common bean |
Q36427117 | Comparative Morphophysiological Analyses and Molecular Profiling Reveal Pi-Efficient Strategies of a Traditional Rice Genotype. |
Q84834924 | Comparative spatiotemporal analysis of root aerenchyma formation processes in maize due to sulphate, nitrate or phosphate deprivation |
Q36089149 | Complementarity in root architecture for nutrient uptake in ancient maize/bean and maize/bean/squash polycultures. |
Q48192091 | Contrasting development of lysigenous aerenchyma in two rice genotypes under phosphorus deficiency. |
Q35531584 | Evolution of US maize (Zea mays L.) root architectural and anatomical phenes over the past 100 years corresponds to increased tolerance of nitrogen stress. |
Q34858093 | Flooding tolerance in interspecific introgression lines containing chromosome segments from teosinte (Zea nicaraguensis) in maize (Zea mays subsp. mays). |
Q57192124 | Greater lateral root branching density in maize improves phosphorus acquisition from low phosphorus soil |
Q41139824 | Impact of axial root growth angles on nitrogen acquisition in maize depends on environmental conditions |
Q30829408 | Impacts of environmental factors on fine root lifespan |
Q37165584 | Integration of root phenes for soil resource acquisition |
Q92509557 | Interspecific competition among catch crops modifies vertical root biomass distribution and nitrate scavenging in soils |
Q53075581 | Large Crown Root Number Improves Topsoil Foraging and Phosphorus Acquisition. |
Q38944483 | Large root cortical cell size improves drought tolerance in maize |
Q36123238 | Making better maize plants for sustainable grain production in a changing climate |
Q41781511 | New insights into trophic aerenchyma formation strategy in maize (Zea mays L.) organs during sulfate deprivation |
Q38370100 | OpenSimRoot: widening the scope and application of root architectural models |
Q37179527 | Opportunities and challenges in the subsoil: pathways to deeper rooted crops. |
Q38989716 | Overview: Early history of crop growth and photosynthesis modeling |
Q46770074 | Phene synergism between root hair length and basal root growth angle for phosphorus acquisition |
Q34802821 | Plant growth and architectural modelling and its applications. Preface. |
Q39624906 | Reduced Lateral Root Branching Density Improves Drought Tolerance in Maize. |
Q38944478 | Reduced root cortical cell file number improves drought tolerance in maize |
Q46265470 | Reduction in Root Secondary Growth as a Strategy for Phosphorus Acquisition. |
Q47846873 | Root Cortical Senescence Improves Growth under Suboptimal Availability of N, P, and K. |
Q26830054 | Root anatomical phenes associated with water acquisition from drying soil: targets for crop improvement |
Q28654218 | Root cortical aerenchyma enhances nitrogen acquisition from low-nitrogen soils in maize |
Q39365233 | Root cortical aerenchyma enhances the growth of maize on soils with suboptimal availability of nitrogen, phosphorus, and potassium. |
Q41860702 | Root cortical aerenchyma inhibits radial nutrient transport in maize (Zea mays). |
Q36973310 | Root cortical burden influences drought tolerance in maize. |
Q47981273 | Root cortical senescence decreases root respiration, nutrient content and radial water and nutrient transport in barley |
Q37879327 | Root phenes for enhanced soil exploration and phosphorus acquisition: tools for future crops |
Q30855705 | Root structural and functional dynamics in terrestrial biosphere models--evaluation and recommendations |
Q27027741 | Root systems biology: integrative modeling across scales, from gene regulatory networks to the rhizosphere |
Q39733763 | Root transcriptomes of two acidic soil adapted Indica rice genotypes suggest diverse and complex mechanism of low phosphorus tolerance |
Q90029019 | Soil compaction and the architectural plasticity of root systems |
Q39617171 | Spatiotemporal variation of nitrate uptake kinetics within the maize (Zea mays L.) root system is associated with greater nitrate uptake and interactions with architectural phenes. |
Q36973306 | Steep, cheap and deep: an ideotype to optimize water and N acquisition by maize root systems |
Q42079451 | The Frustration with Utilization: Why Have Improvements in Internal Phosphorus Utilization Efficiency in Crops Remained so Elusive? |
Q48307360 | The optimal lateral root branching density for maize depends on nitrogen and phosphorus availability |
Q36259277 | Tracing of Two Pseudomonas Strains in the Root and Rhizoplane of Maize, as Related to Their Plant Growth-Promoting Effect in Contrasting Soils |
Q42251858 | Virtual Plants Need Water Too: Functional-Structural Root System Models in the Context of Drought Tolerance Breeding |
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