The use of metabolomics integrated with transcriptomic and proteomic studies for identifying key steps involved in the control of nitrogen metabolism in crops such as maize

Amiour, Nardjis; Imbaud, Sandrine; Clément, Gilles; Agier, Nicolas; Zivy, Michel; Valot, Benoı̂t; Balliau, Thierry; Armengaud, Patrick; Quilleré, Isabelle; Cañas, Rafael A.; Tercet-Laforgue, Thérèse; Hirel, Bertrand

doi:10.1093/jxb/ers186

Cited by 179 publications

(160 citation statements)

References 103 publications

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“…The rate of N uptake in roots is determined by ionic concentration (Tsay et al 2007 ), which is infl uenced by various stress conditions (Segonzac et al 2007 ). Recently, it was reported that in maize, N-defi ciency stress resembled the response of plants to a number of other biotic and abiotic stresses, in terms of transcript, protein, and metabolite accumulation (Amiour et al 2012 ). In rice, two proteins, fi brillin and hairpin-binding protein, have been identifi ed previously as N-defi ciency stressresponsive proteins (Song et al 2010 ;Amiour et al 2012 ).…”

Section: Nitrogen Starvation/limitationmentioning

confidence: 99%

Nitrogen and Stress

Jangam

Raghuram

2015

Elucidation of Abiotic Stress Signaling in Plants

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Nitrogen is an essential macronutrient for the plants and fertilizer N-use effi ciency is becoming an increasing economic and environmental concern. The nutrient stress conditions of N defi ciency and N excess may get exacerbated by other abiotic stresses, which in turn are likely to be worsened by climate change. Exploring their interrelationships is being increasingly facilitated by the growing knowledge of the genome-wide N response as well as other abiotic stress responses in model plants. Nitrate and its more reduced forms are not only sources of plant N nutrition but also signals that govern their own uptake; N, C, and redox metabolism; and hormonal and other organism-wide responses. The signaling mechanisms involved in N response or response to N stress or N-use effi ciency are currently far less well understood than those in other abiotic stresses. The purpose of this review is to provide an overview of the current state of knowledge on normal N response and response to N stress, as well as their interrelationships with other abiotic stresses. Nitrogen is an important macroelement for plant growth. However, plant can't use atmospheric nitrogen as such and depend on its availability in more reactive forms such as urea, nitrate, ammonium, amino acids, etc. Even legumes depend on symbiotic N-fi xing bacteria to convert N 2 into ammonium ions to meet their N requirements. Therefore, the term nitrogen (N) is used in this review to represent a broad range of reactive species of N compounds. In agricultural soils, N compounds and other nutrients have to be constantly replenished as fertilizers/manures to enable repetitive cropping. As N fertilizers are expensive, N-use effi ciency becomes an important determinant of crop productivity. Keywords

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Section: Nitrogen Starvation/limitationmentioning

confidence: 99%

Nitrogen and Stress

Jangam

Raghuram

2015

Elucidation of Abiotic Stress Signaling in Plants

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“…Thus, it would be possible for researchers to even predict the quantitative and qualitative efect an introduction or deduction that a selected element or compound could have in the gene network or pathway within a biological system. For example, it would be possible to predict what efect could high concentrations of Ca have on the phenotype or the production of a selected phenolic acid in a selected grain compartment (endosperm) [89]. The integration of these technologies would enable researchers to determine which gene region could be targeted to improve the levels of a desirable metabolite without afecting other biological systems.…”

Section: The Use Of -Omics Technologies To Improve Nutritional Bioavamentioning

confidence: 99%

Progress and Challenges in Improving Nutritional Quality in Wheat

Lephuthing¹,

Baloyi²,

Sosibo³

et al. 2017

Wheat Improvement, Management and Utilization

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Wheat (Triticum aestivum L.) houses a wide range of nutritional components such as iron (Fe), zinc (Zn), vitamins and phenolic acids, which are important for plant metabolism and human health. The bioavailability of these nutritional components is low due to their interaction with other components and low quantity in the endosperm. Biofortiication is a more sustainable approach that could improve the bioavailability of essential nutritional components. Substantial progress has been made to improve nutritional quality through the application of conventional, technological and transgenic approaches. This has led to the discovery, cloning and introgression of the Gpc-B1 gene; the invention of online databases with minimally characterized biosynthetic, metabolic pathways and biological processes of wheat-related species; the establishment of genetic variation in grain Fe and Zn content and the biofortiication of wheat with Zn by the HarvestPlus organization. Nonetheless, the biofortiication of wheat with micronutrients and phenolic acids is still a challenge due to incomplete understanding of the wheat genome, biosynthesis and translocation of selected nutritional components into diferent wheat grain compartments. There is a need to integrate selected omics technologies to obtain a holistic overview and manipulate key biological processes involved in the remobilization and biosynthesis of nutritional components into desired wheat grain compartments.

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“…79 Combinations of transcriptome, proteome and metabolite profiling helps in revealing the correlation between the expression of stress related biosynthetic genes and corresponding metabolic products, which further increases our understanding of plant stress responses. 83 discussed the potential use of 'Omics' studies to improve understanding of whole plant nitrogen econOmics in maize.…”

Section: Kusano Et Almentioning

confidence: 99%