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Root cell-wall properties are proposed to contribute to phosphorus (P) mobilization by groundnut and pigeonpea

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Abstract

Groundnuts showed a superior ability to take up phosphorus (P) from two soils of extremely low fertility, where sorghum and soybean died of P deficiency. This ability could not be attributed to differences in root development, to P uptake parameters such as Cmin, or to the excretion of root exudates capable of solubilizing iron- (Fe-P) and aluminum-bound P (Al-P), the sparingly soluble P forms in soils. A new P solubilizing mechanism (called `contact reaction') which occurs at the interface between root surface and soil particles, is therefore proposed. Isolated cell walls from groundnut roots solubilized more P from P-fixing minerals than those from sorghum and soybean roots. The P-solubilizing activity of groundnut root cell-walls might therefore be related to the superior growth of this crop under P-deficient conditions. The P-solubilizing active sites in groundnut root cell walls were located at the root surface and could act as chelating agent with Fe(III). This P-solubilizing active component in the cell walls could be extracted by NaOH, but not by HCl, and was identified as a small molecule through column chromatography with Sephadex LH-20. The P-solubilizing ability of pigeonpea root cell-walls was examined and found to be as high as that of groundnut. As pigeonpea plants excrete significant amount of root exudates with Fe-P solubilizing ability only after they flower, the P-solubilizing ability of root cell-walls may partially explain the high P efficiency of this species before it flowers.

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Authors and Affiliations

  1. Division of Soil Sciences, National Institute of Agro-Environmental Sciences, Tsukuba, Ibaraki, 305-8604, Japan

    N. Ae & R.F. Shen

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  1. N. Ae
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  2. R.F. Shen
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Correspondence to N. Ae.

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Ae, N., Shen, R. Root cell-wall properties are proposed to contribute to phosphorus (P) mobilization by groundnut and pigeonpea. Plant and Soil 245, 95–103 (2002). https://doi.org/10.1023/A:1020669326602

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