Phosphorus Mobilizing Capacity of Selected Grain Legumes Grown Under Phosphorus-Deficient Conditions

T. G. R. M. Thennegedara, D. Dissanayaka
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引用次数: 2

Abstract

Compared with other crops, legumes have superior ability to mobilize part of non-labile phosphorus (P) into labile/available forms. We explored the P-mobilization potential of selected grain legumes and its influence on growth, P uptake, and yield under P-deficient conditions. A pot experiment was carried out in a greenhouse with soybean (Glycine max L.), cowpea (Vigna unguiculata L.), green gram (Vigna radiata L.), and black gram (Vigna mungo L.) with two P fertilizer applications; without (Pdeficient) and with (P-sufficient) Department of Agriculture recommended rates of triple super phosphate. Each crop was harvested at maturity and the bulk and rhizosphere soils were collected to quantify different P fractions using Hedley’s sequential fractionation. Dry weight and P accumulation in different plant organs, i.e. roots, stems, leaves, and pods, were measured. Most plant organs maintained similar dry weight and tissue-P concentration irrespective of the P levels applied. All crops reduced their total plant-P uptake under P-deficient conditions. However, this did not make any change in either pod dry weight or P concentration of pods. Soybean and mung bean had a greater P accumulation compared to cowpea and black gram under both P levels. In contrast, cowpea and black gram showed improved P use efficiency (PUE) than other two legumes. Available P concentration (NaHCO3-P) in rhizosphere soil is greater than that in bulk soil in soybean and cowpea whereas the rhizosphere NaHCO3-P content in mung bean was greatly decreased compared to that of bulk soil when the crop was cultivated in P-deficient soil. The concentration of non-labile P fraction in rhizosphere of all grain legumes were significantly low compared to that of the bulk soil. Results suggest that selected grain legumes could be cultivated in P-deficient soil as they can adapt either through enhancing P uptake or increasing PUE.
缺磷条件下精选粒豆类的磷动员能力
与其他作物相比,豆类具有将部分不稳定磷转化为不稳定/有效形式的优越能力。我们探讨了在缺磷条件下,所选谷物豆类的磷动员潜力及其对生长、磷吸收和产量的影响。在温室中用大豆(Glycine max L.)、豇豆(Vigna ungugillata L.)、绿豌豆(Vignna radiata L.)和黑豌豆(Vinna mungo L.)进行了盆栽试验,并施用了两种磷肥;无(P有效)和(P充足)农业部推荐的三重超磷酸盐用量。每种作物在成熟时收获,并收集大量土壤和根际土壤,以使用Hedley序列分级法量化不同的磷组分。测定了不同植物器官,即根、茎、叶和荚的干重和磷积累。无论施用的磷水平如何,大多数植物器官都保持着相似的干重和组织磷浓度。在缺磷条件下,所有作物都降低了植物对磷的总吸收。然而,这并没有改变荚的干重或磷浓度。在两种磷水平下,大豆和绿豆的磷积累量均大于豇豆和黑豆。与其他两种豆类相比,豇豆和黑豆表现出更高的磷利用效率。大豆和豇豆根际土壤的有效磷浓度(NaHCO3-P)高于大块土壤,而在缺磷土壤中种植时,绿豆根际NaHCO3-P含量显著低于大块土壤。与大块土壤相比,所有豆类作物根际不稳定磷组分的浓度均显著较低。结果表明,选择的谷物豆类可以在缺磷土壤中种植,因为它们可以通过提高磷吸收或增加PUE来适应。
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