Superior Root Hair Formation Confers Root Efficiency in Some, But Not All, Rice Genotypes upon P Deficiency

Nestler, Josefine; Wissuwa, Matthias

doi:10.3389/fpls.2016.01935

Cited by 59 publications

(42 citation statements)

References 39 publications

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“…Lateral roots were recently proposed to have different, specialized functions depending on their developmental type [74]. Supporting this proposal, we showed that the thinner lateral roots of rice produced shorter and fewer root hairs [75], and found a positive linear relationship between lateral root diameter and root hair length [56]. These results were reproduced in different growth conditions, with main roots (seminal and crown axile roots) consistently producing the longest and most root hairs, followed by L-type and S-type lateral roots (Figure 2) (see Section 4 for experimental details).…”

Section: Root Hair Variation Within Root Typessupporting

confidence: 82%

“…Earlier studies in one set of near-isogenic rice lines differing in root size and P uptake showed these differences remained unchanged in sterilized soil [55]. Based on the limited evidence available to date, one may tentatively conclude that the AM symbiosis contributes less to rice genotypic differences in P uptake compared to root attributes such as size, fineness or root hair length and density [56].…”

Section: Rice Association With Mycorrhizal Fungimentioning

confidence: 96%

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Phosphorus Efficient Phenotype of Rice

Kant¹,

Ishizaki²,

Pariasca‐Tanaka³

et al. 2018

Rice Crop - Current Developments

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The ideal phenotype to cope with P deficiency is suggested to be a larger root system, both in terms of length and foraging area, coupled with a high capacity for P solubilization from compounds exuded from roots. Greater soil exploration results in a large number of roots in the top soil, longer roots in general with more cortical aerenchyma, more and longer root hairs, and a shift in mycorrhizal and bacterial colonization. However, these assumptions often result from experiments in highly controlled, sterile and soil-free conditions using model plants or single ecotypes where results are then extrapolated to all genotypes and plant species. In recent years this generalization has been questioned. Here, we summarize recent rice research analyzing the natural diversity of rice root systems under P deficiency. Interestingly, while some of the high yielding genotypes do show the expected, large root system phenotype, some have a surprisingly small root system-as little as a quarter of that of the large root system varieties-but achieve similar yield and P uptake under P deficiency. This effect has recently been termed root efficiency, which we discuss in this chapter in conjunction with root foraging traits.

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Section: Root Hair Variation Within Root Typessupporting

confidence: 82%

Section: Rice Association With Mycorrhizal Fungimentioning

confidence: 96%

Phosphorus Efficient Phenotype of Rice

Kant¹,

Ishizaki²,

Pariasca‐Tanaka³

et al. 2018

Rice Crop - Current Developments

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“…FOFIFA 172 is more responsive (less performant under low P input) than Chomrong Dhan. The generally P-efficient genotype DJ123, known for its good performance on low P soils (Mori et al, 2016; Nestler & Wissuwa, 2016; Vandamme, Wissuwa, et al, 2016), was not high yielding in the low P environment of this study and it even showed comparable or lower yields than the generally P-inefficient rice genotype, NERICA 4. Hence, this indicates that this P-efficient genotype (DJ123) is likely not adapted to the cold highlands of Madagascar while NERICA 4 seems somehow more robust in such environment.…”

Section: Discussioncontrasting

confidence: 54%

“…The main significant effects of genotypes (Table 4) are more affected by their growth potential, i.e. under TSP+FYM application, rather than by their inherent differences in in PAE and PUE that exist among rice genotypes (De Bauw et al, 2019; Nestler and Wissuwa, 2016; Vandamme et al, 2016a). This indicates that genotype selection likely becomes inferior to management options when soil limitations are very severe.…”

Section: Discussionmentioning

confidence: 99%

“…Genotypic variation exists in both PUE and PAE (Vandamme, Rose, et al, 2016; Vandamme, Wissuwa, et al, 2016; Wissuwa & Ae, 2001). Genotypic variation in PAE is related to a combination of differences in effective root surface area (Nestler & Wissuwa, 2016) per plant or in P acquisition strategies (Clark, 1983). For example, it is well established that plants can mobilize soil-adsorbed P by secreting root exudates, with different underlying P-solubilisation strategies from the inorganic P pool, or that plants can access organic P forms by the excretion of phosphatases (Richardson et al, 2011; Rose et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

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Farm yard manure enhances phosphate fertilizer use efficiency in different upland rice genotypes through mitigating aluminium toxicity

Bauw

Shimamura

Rakotoson³

et al. 2020

Preprint

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23Upland rice production on weathered soils is often constrained by phosphorus (P) deficiency and soil 24 acidity. Farmyard manure application (FYM) can sharply enhance yields and agronomic P fertilizer (TSP) 25 efficiency. We tested the hypothesis that rice genotypes differ in the extent of using organic P and offering 26 distinct benefits under TSP-FYM combinations. Multiple field trials were conducted in the uplands of 27 Madagascar, with factorial combinations of six genotypes, FYM, and TSP applications, with blanket N&K 28 additions. Rice grain yields reached 6 t ha -1 after three years of TSP+FYM application, were lower when 29 FYM or TSP were used separately, while crops failed under zero P input. Genotypic differences were 30 inferior to the large treatment effects. Application of FYM increased soil pH and CaCl2-extractable P while 31 decreasing CaCl2-extractable aluminium. An additional liming trial indicated that beneficial effects of FYM 32 over TSP relate to liming effects. Genotypic ranking of yields and agronomic efficiency was inconsistent, 33 without superior genotypes under FYM versus TSP. However, Chomrong Dhan and FOFIFA 172 showed 34 superior yields under TSP+FYM. The FYM application lowers aluminium toxicity which overrules potential 35 effects of organic P supply. Aluminium tolerance should be included when developing rice genotypes for 36 low P tolerance in weathered soils.NA Data not available. a Phosphorus Acquisition Efficiency, expressed as total P uptake in mg at low P availability in the soil. b Root Efficiency, expressed as total P uptake per unit root size (either root biomass in g or root surface area in cm 2 ).

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