Improving Plant Nitrogen Use Efficiency through Alteration of Amino Acid Transport Processes

Perchlik, Molly; Tegeder, Mechthild

doi:10.1104/pp.17.00608

Cited by 155 publications

(106 citation statements)

References 114 publications

(222 reference statements)

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“…As a general concept, N source to sink partitioning is influenced by N uptake and metabolism in source organs, as well as the ability of sources to export, and sinks to import, the N. Studies in Arabidopsis and legumes have demonstrated that amino acid transport processes in the shoot exert regulatory control over N uptake in roots, source metabolism, and allocation to sinks. For example, in pea, increased amino acid phloem loading positively affected N root uptake and, subsequently, N availability for assimilation and usage in source and sink Zhang et al, 2015;Perchlik & Tegeder, 2017). Enhanced N export from leaves and associated changes in leaf N concentrations probably induced a shoot-to-root signal triggering up-regulation of N uptake and delivery to leaves.…”

Section: Relationship Between Source and Sink Nitrogen Transportmentioning

confidence: 99%

“…Current knowledge regarding how amino acid transporters are controlled is mostly limited to transcriptional studies. Transporter expression was found to be cell-and tissue-specific, developmentally regulated, and affected by abiotic or biotic factors such as N, light, salt and drought stress, and nematode or pathogen attack (Pratelli & Pilot, 2014;Hav e et al, 2016;Perchlik & Tegeder, 2017). Changes in the redox status or other endogenous factors may induce the transcriptional changes (Geigenberger & Fernie, 2014;Noctor et al, 2015;Bellegarde et al, 2017;Gulyas et al, 2017).…”

Section: Regulation At Cellular Levelmentioning

confidence: 99%

“…The AAP1 pea plants were also used to determine if and how changes in source-to-sink amino acid transport affect plant NUE Perchlik & Tegeder, 2017). When grown under high, moderate or low N supplies, the transgenic lines always outperformed wild type.…”

Section: Reviewmentioning

confidence: 99%

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Source and sink mechanisms of nitrogen transport and use

2017

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Contents Summary35I.Introduction35II.Nitrogen acquisition and assimilation36III.Root‐to‐shoot transport of nitrogen38IV.Nitrogen storage pools in vegetative tissues39V.Nitrogen transport from source leaf to sink40VI.Nitrogen import into sinks42VII.Relationship between source and sink nitrogen transport processes and metabolism43VIII.Regulation of nitrogen transport43IX.Strategies for crop improvement44X.Conclusions46Acknowledgements47References47 Summary Nitrogen is an essential nutrient for plant growth. World‐wide, large quantities of nitrogenous fertilizer are applied to ensure maximum crop productivity. However, nitrogen fertilizer application is expensive and negatively affects the environment, and subsequently human health. A strategy to address this problem is the development of crops that are efficient in acquiring and using nitrogen and that can achieve high seed yields with reduced nitrogen input. This review integrates the current knowledge regarding inorganic and organic nitrogen management at the whole‐plant level, spanning from nitrogen uptake to remobilization and utilization in source and sink organs. Plant partitioning and transient storage of inorganic and organic nitrogen forms are evaluated, as is how they affect nitrogen availability, metabolism and mobilization. Essential functions of nitrogen transporters in source and sink organs and their importance in regulating nitrogen movement in support of metabolism, and vegetative and reproductive growth are assessed. Finally, we discuss recent advances in plant engineering, demonstrating that nitrogen transporters are effective targets to improve crop productivity and nitrogen use efficiency. While inorganic and organic nitrogen transporters were examined separately in these studies, they provide valuable clues about how to successfully combine approaches for future crop engineering.

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Section: Relationship Between Source and Sink Nitrogen Transportmentioning

confidence: 99%

Section: Regulation At Cellular Levelmentioning

confidence: 99%

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Source and sink mechanisms of nitrogen transport and use

2017

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“…The increased NUE of N under warmed plots with unchanged N content indicated that P. maximum acclimates to moderate heating. This response may be associated with changes in N uptake and assimilation, allocation and remobilisation or metabolic modifications [28]. Increased NUE of N may also be achieved by higher transpiration rates.…”

Section: Discussionmentioning

confidence: 99%

Elevated CO₂and warming change the nutrient status and use efficiency ofPanicum maximumJacq

Carvalho

Prado

Barreto

et al. 2019

Preprint

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14Panicum maximum Jacq. 'Mombaça' (guinea grass) is a C 4 forage grass widely used in 15 tropical pastures for cattle feeding. In this study, we evaluated the isolated and combined 16 effects of warming and elevated CO 2 concentration [CO 2 ] during summer on the nutrient 17 content, nutrient accumulation, nutrient use efficiency and growth of P. maximum under 18 field conditions with adequate water supply. The temperature and [CO 2 ] in the field were 19 controlled by temperature free-air controlled enhancement and free-air CO 2 enrichment 20 systems, respectively. We tested two levels of canopy temperature: ambient temperature 21 and 2°C above ambient temperature, as well as two levels of atmospheric [CO 2 ]: ambient 22 [CO 2 ] (aCO 2 ) and 200 ppm above ambient CO 2 (eCO 2 ). The experiment was established 23 in a completely randomised design with four replications, in a 2×2 factorial scheme. After 24 the pasture establishment, plants were exposed to the treatments for 30 days, with 25 evaluations at 9, 16, 23 and 30 days after the treatments started. Results were dependent 26 on the time of the evaluation, but in the last evaluation (beginning of the grazing), contents 27 of N, K, Mg and S did not change as a function of treatments, P decreased as a function 28 of warming, in [aCO 2 ] and [eCO 2 ], and Ca increased under [eCO 2 ] combined with 29 warming. There was an increase in root dry mass under warming treatment. Combined 30 treatment increased N, Ca and S accumulation without a corresponding increase in the 31 use efficiency of these same nutrients, indicating that the fertiliser dose should increase 32 in the next decades due to human-induced climate change. Our short-term results suggest 33 that the combination of high [CO 2 ] and temperature will increase P. maximum 34 productivity and that the nutritional requirement for N, Ca and S will increase. 35 36 38During the last decades, anthropic emissions of greenhouse gases, such as carbon dioxide 39 (CO 2 ), nitrous oxide (N 2 O) and methane (CH 4 ), have induced alterations in the natural 40 climate cycles of the Earth, elevating the mean surface temperature of the planet [1,2]. 41 The global temperature has been increasing in the last years, and several climate models 42 estimate that this trend will continue in the next decades [3]. Many climate change 43 scenarios have been proposed, depending on the future emissions of greenhouse gases 44 and mitigation policies. According to a moderate-impact scenario outlined by the 45 Intergovernmental Panel on Climate Change (IPCC), the atmospheric CO 2 concentration 46 ([CO 2 ]) will reach 600 ppm by 2100, while the global surface temperature will be between 47 2.0 and 3.7°C above the pre-industrial average temperature [3]. 48In tropical and sub-tropical regions, livestock is one of the most important 49 economic activities, and pastures cover extensive areas of the territory, being the main 50 source for cattle feeding in most of these regions [4]. The effects of climate change on 51 the nutritional ...

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“…To meet the rising global demand for food, the NUE must be improved and the application of N fertilizer must be reduced (Hirel, Le Gouis, Ney, & Gallais, 2007; White & Brown, 2010). The main strategy to achieve this is to increase crop yields and reduce N fertilizer application by increasing the UPE and UTE in plants, to ultimately improve NUE and reduce environmental pollution (Perchlik & Tegeder, 2017). Ultimately, this involves achieving an ideal state whereby the maximum N absorption and photosynthetic production can be achieved by optimizing the light, water, and photosynthetic canopy under conditions of the lowest possible N fertilizer application (Fageria, Baligar, & Li, 2008), however, it is difficult to achieve.…”

Section: Introductionmentioning

confidence: 99%

Late‐sown winter wheat requires less nitrogen input but maintains high grain yield

Yin

Wang

et al. 2020

Agronomy Journal

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Increased attention on the agricultural impacts to environment has revealed excessive N input to be a major concern. Sowing date reportedly impacts crop N uptake, however, few studies have assessed the effects of late sowing with reduced N apply on crop N status and grain yield. We evaluated three treatments: normal sowing (8 October), late sowing (22 October), and optimized late sowing (22 October, with 75% N application) over two wheat (Triticum aestivum L.) growing seasons (2017)(2018)(2019), and assessed their effects on crop N status, N allocation and use, net photosynthetic rate (P max ), grain yield, and soil N budget. Compared to normal sowing, optimized late sowing resulted in near-optimum N status, improved nitrogen use efficiency (NUE), nitrogen utilization efficiency (UTE), and nitrogen uptake efficiency (UPE), while maintaining a high yield. Although aboveground N uptake of late and optimized late sowing at anthesis was lower than that of normal sowing, N distribution was more optimized, mainly manifesting as: unchanged N allocation to the individual plant, but increased N allocation to flag leaf, and steeper green leaf area N in the canopy under optimized late sowing. Optimized N nutrition index and N distribution under late sowing contributed to a higher P max , which resulted in a higher dry matter accumulation rate during post-anthesis, and ultimately a consistent grain yield among the three treatments. Moreover, N input reduction under optimized late sowing decreased the final mineral N in the 0-100-cm soil layer at harvest and apparent N loss, which reduced environmental pollution and resources waste.Abbreviations: AGN, aboveground nitrogen uptake; N f-min , final mineral N in the 0-100-cm soil layer at harvest; N loss , apparent N loss; NNI, nitrogen nutrition index; NUE, nitrogen use efficiency; P max , net photosynthetic rate; SLN, specific green leaf area nitrogen; UPE, nitrogen uptake efficiency; UTE, nitrogen utilization efficiency.

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Improving Plant Nitrogen Use Efficiency through Alteration of Amino Acid Transport Processes

Cited by 155 publications

References 114 publications

Source and sink mechanisms of nitrogen transport and use

Source and sink mechanisms of nitrogen transport and use

Elevated CO₂and warming change the nutrient status and use efficiency ofPanicum maximumJacq

Late‐sown winter wheat requires less nitrogen input but maintains high grain yield

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Improving Plant Nitrogen Use Efficiency through Alteration of Amino Acid Transport Processes

Cited by 155 publications

References 114 publications

Source and sink mechanisms of nitrogen transport and use

Source and sink mechanisms of nitrogen transport and use

Elevated CO2and warming change the nutrient status and use efficiency ofPanicum maximumJacq

Late‐sown winter wheat requires less nitrogen input but maintains high grain yield

Contact Info

Product

Resources

About

Elevated CO₂and warming change the nutrient status and use efficiency ofPanicum maximumJacq