Topsoil foraging and phosphorus acquisition efficiency in maize (Zea mays).

@article{Zhu2005TopsoilFA,
  title={Topsoil foraging and phosphorus acquisition efficiency in maize (Zea mays).},
  author={Jinming Zhu and Shawn M. Kaeppler and Jonathan Paul Lynch},
  journal={Functional plant biology : FPB},
  year={2005},
  volume={32 8},
  pages={
          749-762
        }
}
In soybean and common bean, enhanced topsoil foraging permitted by shallow root architectures is advantageous for phosphorus acquisition from stratified soils. The importance of this phenomenon in graminaceous crops, which have different root architecture and morphology from legumes, is unclear. In this study we evaluated the importance of shallow roots for phosphorus acquisition in maize (Zea mays L.). In a field study, maize genotypes with shallower roots had greater growth in low phosphorus… 
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Large Crown Root Number Improves Topsoil Foraging and Phosphorus Acquisition1[OPEN]
TLDR
The hypothesis that large CN improves plant P acquisition from low-P soils by reducing rooting depth and increasing topsoil foraging is supported and the large-CN phenotype merits consideration as a selection target to improve P capture in maize and possibly other cereal crops.
Architectural Tradeoffs between Adventitious and Basal Roots for Phosphorus Acquisition
TLDR
The results confirm the importance of root respiration in nutrient foraging strategies, and demonstrate functional tradeoffs among distinct components of the root system, will be useful in developing ideotypes for more nutrient efficient crops.
Soil type determines how root and rhizosphere traits relate to phosphorus acquisition in field-grown maize genotypes
TLDR
The results indicate the key role of environmental factors for roots traits determining high PAE, and highlights the need to consider soil properties when breeding for highPAE, as various soil types are likely to require different crop ideotypes.
Root distributions of Australian herbaceous perennial legumes in response to phosphorus placement.
TLDR
High P concentration in the surface soil altered root distribution, but did not reduce root proliferation at depth in native legumes, and the Australian herbaceous perennial legumes had root distributions that enhanced P acquisition from low-P soils.
Maize root growth angles become steeper under low N conditions
Impact of axial root growth angles on nitrogen acquisition in maize depends on environmental conditions.
TLDR
Results support the hypothesis that root growth angles are primary determinants of N acquisition in maize, and suggest that genetic selection for root phenotypes could be tailored to specific environments.
Will nutrient-efficient genotypes mine the soil? Effects of genetic differences in root architecture in common bean (Phaseolus vulgaris L.) on soil phosphorus depletion in a low-input agro-ecosystem in Central America
Alteration in root morphological and physiological traits of two maize cultivars in response to phosphorus deficiency
Genotypic variation for root traits of maize (Zea mays L.) from the Purhepecha Plateau under contrasting phosphorus availability
Variation in early phosphorus-uptake efficiency among wheat genotypes grown on two contrasting Australian soils
TLDR
The strongest correlation across all treatments occurred between shoot biomass and root biomass, and factors that may contribute to the variation in P-uptake efficiency among the genotypes are discussed.
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References

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CROP ECOLOGY, MANAGEMENT & QUALITY Topsoil Foraging and Its Role in Plant Competitiveness for Phosphorus in Common Bean
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TLDR
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TLDR
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TLDR
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TLDR
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TLDR
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