Molecular mechanisms underpinning phosphorus‐use efficiency in rice

Dissanayaka, D. M. S. B.; Plaxton, William C.; Lambers, Hans; Siebers, Meike; Marambe, B.; Wasaki, Jun

doi:10.1111/pce.13191

Cited by 79 publications

(58 citation statements)

References 163 publications

(340 reference statements)

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“…Similarly, there was no response of photosynthetic rate to N and P fertilization in understorey species of a tropical plantation (Zhu, Lu, & Mo, ) or in response to P addition in lowland tropical forest understorey seedlings after 10 years of P fertilization (Pasquini & Santiago, ). The results, combined with LMA results, also agree with studies of several crop species which demonstrated that photosynthesis is far less sensitive to fertilization than leaf growth (Assuero et al, ; Chiera et al, ; Dissanayaka et al, ).…”

Section: Discussionsupporting

confidence: 88%

“…Under P deficiency, photosynthesis is generally reduced (Turnbull, Warren, & Adams, 2007) due to feedback inhibition resulting from reduced leaf growth (Dissanayaka et al, 2018) or because orthophosphate (Pi) in the cytosol becomes limiting (Warren, 2011). Plants also tend to increase their leaf mass per unit area (LMA; Chiera, Thomas, and Rufty (2002) and increase their photosynthetic P-use efficiency (Hidaka & Kitayama, 2009) when P supply is limited.…”

Section: Introductionmentioning

confidence: 99%

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Foliar phosphorus fractions reveal how tropical plants maintain photosynthetic rates despite low soil phosphorus availability

Sayer

et al. 2019

Functional Ecology

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Nitrogen (N) and phosphorus (P) are essential nutrients for plant metabolism, and their availability often limits primary productivity. Whereas the effects of N availability on photosynthetic capacity are well established, we still know relatively little about the effects of P availability at a foliar level, especially in P‐limited tropical forests. We examined photosynthetic capacity, leaf mass per area (LMA) and foliar P fractions in five woody plant species after 6 years of N and P fertilization in a lowland tropical forest. Foliar N:P ratios indicated P limitation of the unfertilized plants; accordingly, photosynthetic P‐use efficiency (PPUE) and LMA decreased with P addition, and foliar N and P concentrations increased, whereas N addition had little effect on measured foliar traits. However, P addition enhanced photosynthetic capacity only in one species and not in other four species. We then assessed plant acclimation to low P availability by quantifying four fractions of foliar P representing different functional pools: structural P, metabolic P (including inorganic P), nucleic acid P, and residual P. We found that P addition enhanced the concentrations of metabolic, structural, and nucleic acid P fractions in all species, but the magnitude of the effect was species‐specific. Our findings indicate that tropical species acclimate to low P availability by altering allocation of foliar P to meet the demand of P for photosynthesis. Importantly, species typical of lowland tropical forests in East Asia maintained their photosynthetic rate under low P availability. We conclude that P limitation of leaf photosynthetic capacity may not be as common as previously assumed due to plant acclimation mechanisms in low‐P tropical forests. Species‐specific strategies to allocate P to different foliar fractions represent a potentially important adaptive mechanism for plants in P‐limited systems.

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Section: Discussionsupporting

confidence: 88%

Section: Introductionmentioning

confidence: 99%

Foliar phosphorus fractions reveal how tropical plants maintain photosynthetic rates despite low soil phosphorus availability

Sayer

et al. 2019

Functional Ecology

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“…Phosphate forms a major component of fundamental biomolecules such as nucleic acids, adenosine phosphates and phospholipids. Ignoring stored vacuolar phosphorus, cellular phospholipids can account for up to a third of organic phosphorus in cells (in the order of RNA > phospholipids > phosphate-esters > DNA > phosphorylated proteins) and therefore represent a major proportion of the phosphorus budget [32,33] . Adaptive metabolic responses that release these stores can make a major contribute to plant adaption to growth under lowphosphorus conditions and represents a target for improving crop phosphorus use efficiency.…”

Section: Membrane Lipid Remodeling: a Strategy To Improve Crop Phosphmentioning

confidence: 99%

“…3). Metabolic adaptation and membrane remodeling enables plants to adapt to extremely low-phosphorus environments [33,34] . Yet the fundamental understanding of the processes underpinning membrane lipid exchange in crops remains limited.…”

Section: Membrane Lipid Remodeling: a Strategy To Improve Crop Phosphmentioning

confidence: 99%

Phosphorus use efficiency and fertilizers: future opportunities for improvements

Blackwell¹,

Darch²,

Haslam³

2019

Front. Agr. Sci. Eng.

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The continued supply of phosphate fertilizers that underpin global food production is an imminent crisis. The rock phosphate deposits on which the world depends are not only finite, but some are contaminated, and many are located in geopolitically unstable areas, meaning that fundamental changes will have to take place in order to maintain food production for a growing global population. No single solution exists, but a combination of approaches to phosphorus management is required not only to extend the lifespan of the remaining non-renewable rock phosphate reserves, but to result in a more efficient, sustainable phosphorus cycle. Solutions include improving the efficiency of fertilizer applications to agricultural land, alongside a better understanding of phosphorus cycling in soil-plant systems, and the interactions between soil physics, chemistry and biology, coupled with plant traits. Opportunities exist for the development of plants that can access different forms of soil phosphorus (e.g., organic phosphorus) and that use internal phosphorus more efficiently. The development of different sources of phosphorus fertilizers are inevitably required given the finite nature of the rock phosphate supplies. Clear opportunities exist, and it is now important that a concerted effort to make advances in phosphorus use efficiency is prioritized.

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“…Remobilization of P-containing metabolites is considered as an important strategy for plants adaption to P deficiency [15]. Under P-limiting conditions, P-containing metabolites, such as nucleic acid, phospholipids and phosphorylated sugars, can be scavenged to release Pi and maintain P homeostasis in plant cells [60]. It has been shown that phosphorylated sugars are reduced by P deficiency in various plants, such as Arabidopsis [37], barley [40], white lupin (Lupinus albus) [61] and Populus cathayana [62].…”

Section: Scavenging Of Pi From P-containing Metabolites During P Defimentioning

confidence: 99%

Metabolic alterations provide insights into Stylosanthes roots responding to phosphorus deficiency

et al. 2020

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Background: Phosphorus (P) deficiency is one of the major constraints limiting plant growth, especially in acid soils. Stylosanthes (stylo) is a pioneer tropical legume with excellent adaptability to low P stress, but its underlying mechanisms remain largely unknown. Results: In this study, the physiological, molecular and metabolic changes in stylo responding to phosphate (Pi) starvation were investigated. Under low P condition, the growth of stylo root was enhanced, which was attributed to the up-regulation of expansin genes participating in root growth. Metabolic profiling analysis showed that a total of 256 metabolites with differential accumulations were identified in stylo roots response to P deficiency, which mainly included flavonoids, sugars, nucleotides, amino acids, phenylpropanoids and phenylamides. P deficiency led to significant reduction in the accumulation of phosphorylated metabolites (e.g., P-containing sugars, nucleotides and cholines), suggesting that internal P utilization was enhanced in stylo roots subjected to low P stress. However, flavonoid metabolites, such as kaempferol, daidzein and their glycoside derivatives, were increased in P-deficient stylo roots. Furthermore, the qRT-PCR analysis showed that a set of genes involved in flavonoids synthesis were found to be up-regulated by Pi starvation in stylo roots. In addition, the abundances of phenolic acids and phenylamides were significantly increased in stylo roots during P deficiency. The increased accumulation of the metabolites in stylo roots, such as flavonoids, phenolic acids and phenylamides, might facilitate P solubilization and cooperate with beneficial microorganisms in rhizosphere, and thus contributing to P acquisition and utilization in stylo. Conclusions: These results suggest that stylo plants cope with P deficiency by modulating root morphology, scavenging internal Pi from phosphorylated metabolites and increasing accumulation of flavonoids, phenolic acids and phenylamides. This study provides valuable insights into the complex responses and adaptive mechanisms of stylo roots to P deficiency.

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Molecular mechanisms underpinning phosphorus‐use efficiency in rice

Cited by 79 publications

References 163 publications

Foliar phosphorus fractions reveal how tropical plants maintain photosynthetic rates despite low soil phosphorus availability

Foliar phosphorus fractions reveal how tropical plants maintain photosynthetic rates despite low soil phosphorus availability

Phosphorus use efficiency and fertilizers: future opportunities for improvements

Metabolic alterations provide insights into Stylosanthes roots responding to phosphorus deficiency

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