Limited effects of the soluble organic phosphorus fraction on the root phosphorus uptake efficiency of upland rice genotypes grown in acid soil

Shimamura, Erina; Merckx, Roel; Smolders, Erik

doi:10.1080/00380768.2020.1864230

Cited by 4 publications

(1 citation statement)

References 52 publications

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“…Wissuwa and Ae (2001) investigated the P uptake of 30 rice genotypes and observed a high variation for P uptake (0.6–12.9 mg P per plant). Several recent studies in rice and other crops have reported that using genotypes with high P‐uptake efficiency is the best approach for P‐deficient soils, while genotypes with P efficiency produce sufficient dry matter per unit of P consumption (Bilal et al, 2018; Iqbal et al, 2019; Sandaña, 2016; Shimamura et al, 2020). Typically, low P (LP) limits the aboveground growth of rice (i.e., number of tillers, shoot biomass, leaf area index (LAI), and leaf photosynthetic rate), and varieties with strong tolerance to LP could adapt to LP environment by increasing the root growth (Deng et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Tolerance to low phosphorus was enhanced by an alternate wetting and drying regime in rice

Deng

Qiao

Wang

et al. 2021

Food and Energy Security

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is an essential macronutrient for plant growth and development (Baker et al., 2015;Plaxton & Tran, 2011). Compared to nitrogen (N), P is a non-renewable resource. Despite large amounts of organic and inorganic P in natural soils, only 0.1% of the total P is available to plants because of the low solubility and rapid conversion of P compounds to unavailable or less available P after fertilizer application in the soil (Bhadouria et al.,

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Section: Introductionmentioning

confidence: 99%

Tolerance to low phosphorus was enhanced by an alternate wetting and drying regime in rice

Deng

Qiao

Wang

et al. 2021

Food and Energy Security

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Root biomass explains genotypic differences in phosphorus uptake of rainfed rice subjected to water and phosphorus stresses

Verbeeck

Houben

Bauw³

et al. 2023

Plant Soil

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Fertilizer Addition Modifies Utilization of Different P Sources in Upland Rice on Strongly P-fixing Andosols

Mundschenk,

Remus,

Augustin

et al. 2024

J Soil Sci Plant Nutr

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Aims High Phosphorus (P) efficiencies such as internal P utilization efficiency (PUE) and P acquisition efficiency (PAE) are crucial for upland rice production, particularly on highly P-fixing soils like Andosols. While the effect of root traits associated with high PAE in upland rice has been studied intensively, less attention has been given to the origin of P (native soil-P versus fertilizer-P) taken up by plants when evaluating differences in P efficiency. Here we aim to evaluate the efficiency of different upland rice genotypes to acquire native soil-P and fertilizer-P. Methods Four upland rice genotypes with varying PAE were grown in an Andosol at low- and high-P fertilization level and harvested 9 and 34 days after emergence. Fertilizer-P was labeled with 33P to distinguish between the efficiency to acquire P originating from native soil and fertilizer by measuring plant P uptake. Results Increased fertilizer supply enhanced native soil-P uptake. Under low-P conditions the genotype DJ123 showed a superior PAE and an increased acquisition of native soil-P while AB199 was identified to have a superior internal PUE under P deficient conditions. Differences between genotypes in overall PAE under high-P conditions were not significant but the distinction of P sources showed that genotype DJ123 acquired significantly more native soil-P per unit root than all other genotypes. Conclusions Our results indicate that variations in PAE among genotypes are associated with their ability to access native soil-P. DJ123 emerged as the most adept genotype in acquiring sparingly soluble native soil-P and future studies should unravel the rhizosphere processes underlying increased PAE of native soil-P.

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Limited effects of the soluble organic phosphorus fraction on the root phosphorus uptake efficiency of upland rice genotypes grown in acid soil

Cited by 4 publications

References 52 publications

Tolerance to low phosphorus was enhanced by an alternate wetting and drying regime in rice

Tolerance to low phosphorus was enhanced by an alternate wetting and drying regime in rice

Root biomass explains genotypic differences in phosphorus uptake of rainfed rice subjected to water and phosphorus stresses

Fertilizer Addition Modifies Utilization of Different P Sources in Upland Rice on Strongly P-fixing Andosols

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