Ethylene and Phloem Signals Are Involved in the Regulation of Responses to Fe and P Deficiencies in Roots of Strategy I Plants

Lucena, Carlos; Porras, Rafael; García, María J.; Alcántara, Estéban; Pérez‐Vicente, Rafael; Zamarreño, Ángel M.; Bacaicoa, Eva; García-Mina, José M.; Smith, Aaron P.; Romera, Francisco J.

doi:10.3389/fpls.2019.01237

Cited by 20 publications

(21 citation statements)

References 66 publications

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“…Organic anion secretion and rhizosphere acidification mobilize not only P but also other nutrients like Fe, Ca, Mn, or Zn, increasing their uptake rates (Lamont, 2003). P is loaded into the xylem through transporters (Lucena et al, 2019). Phosphorus deficiency initially reduces the levels of sugars (fructose, glucose, and sucrose) in shoots, and phosphorylated metabolites such as glycerol-3-phosphate, fructose-6-phosphate, glucose-6-phosphate, or myo-inositol-phosphate levels decrease in both shoots and roots of L. albus (Müller et al, 2015).…”

Section: P and N Deficiencies Affect The Formation And Metabolism Ofmentioning

confidence: 99%

Section: P and N Deficiencies Affect The Formation And Metabolism Ofmentioning

confidence: 99%

“…Recently, miR399 has also been linked to legume nodule functional processes ( Figueredo et al, 2020 ). The importance of ethylene and miR399 has been reported in the regulation of responses to Fe and P deficiencies ( Lucena et al, 2019 ). Nitric oxide (NO) is another signaling molecule related to both N and P signaling.…”

Section: N–p Interactive Regulation Pathwaysmentioning

confidence: 99%

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Nitrogen and Phosphorus Interplay in Lupin Root Nodules and Cluster Roots

et al. 2021

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Nitrogen (N) and phosphorus (P) are two major plant nutrients, and their deficiencies often limit plant growth and crop yield. The uptakes of N or P affect each other, and consequently, understanding N–P interactions is fundamental. Their signaling mechanisms have been studied mostly separately, and integrating N–P interactive regulation is becoming the aim of some recent works. Lupins are singular plants, as, under N and P deficiencies, they are capable to develop new organs, the N2-fixing symbiotic nodules, and some species can also transform their root architecture to form cluster roots, hundreds of short rootlets that alter their metabolism to induce a high-affinity P transport system and enhance synthesis and secretion of organic acids, flavonoids, proteases, acid phosphatases, and proton efflux. These modifications lead to mobilization in the soil of, otherwise unavailable, P. White lupin (Lupinus albus) represents a model plant to study cluster roots and for understanding plant acclimation to nutrient deficiency. It tolerates simultaneous P and N deficiencies and also enhances uptake of additional nutrients. Here, we present the structural and functional modifications that occur in conditions of P and N deficiencies and lead to the organogenesis and altered metabolism of nodules and cluster roots. Some known N and P signaling mechanisms include different factors, including phytohormones and miRNAs. The combination of the individual N and P mechanisms uncovers interactive regulation pathways that concur in nodules and cluster roots. L. albus interlinks N and P recycling processes both in the plant itself and in nature.

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Section: P and N Deficiencies Affect The Formation And Metabolism Ofmentioning

confidence: 99%

Section: P and N Deficiencies Affect The Formation And Metabolism Ofmentioning

confidence: 99%

Section: N–p Interactive Regulation Pathwaysmentioning

confidence: 99%

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Nitrogen and Phosphorus Interplay in Lupin Root Nodules and Cluster Roots

et al. 2021

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“…Among these responses are the enhanced expression of specific transporters and the alteration of the root system architecture (Maruyama-Nakashita et al, 2006 ; Takahashi et al, 2011 ; Zhang et al, 2014 ; Briat et al, 2015b ; García et al, 2015 ; Lucena et al, 2015 ; Ajmera et al, 2019 ; Crombez et al, 2019 ; Venuti et al, 2019 ). In Arabidopsis , the main phosphate transporters implicated in its acquisition from the medium are PHT1;1 and PHT1;4 (also named PT1 and PT2; Nagarajan and Smith, 2012 ; Lucena et al, 2018 , 2019 ; Crombez et al, 2019 ); the ones for sulfate are SULTR1;1 and SULTR1;2 (Maruyama-Nakashita et al, 2006 ; Takahashi et al, 2011 ; Yamaguchi et al, 2020 ), and the one for Fe 2+ is IRT1 (Kobayashi and Nishizawa, 2012 ; Lucena et al, 2015 ). Nutrient deficiencies also alter the expression of internal transporters, like PHT1;5, which plays a critical role in mobilizing phosphate from source to sink organs (Nagarajan et al, 2011 ; Nagarajan and Smith, 2012 ; Zhang et al, 2014 ).…”

Section: Introductionmentioning

confidence: 99%

“…Both Fe and P deficiencies can induce other responses, like the acidification of the rhizosphere; the increased synthesis and release of organic acids and phenolics to the rhizosphere; and the development of subapical root hairs (Kobayashi and Nishizawa, 2012 ; Correia et al, 2014 ; Wang et al, 2014 ; Zhang et al, 2014 ; García et al, 2015 ; Lucena et al, 2015 , 2018 , 2019 ; Neumann, 2016 ; Tsai and Schmidt, 2017 ; Venuti et al, 2019 ). Particularly, Fe deficiency can induce an enhanced ferric reductase activity (FRA), due to increased expression of the FRO2 gene (Kobayashi and Nishizawa, 2012 ; Lucena et al, 2015 ), and P deficiency an enhanced phosphatase activity (PA), due to increased expression of PAP genes, like PAP7 or PAP17 (also named ACP5 ; Lei et al, 2011 ; Zhang et al, 2014 ; Lucena et al, 2018 , 2019 ; Venuti et al, 2019 ).…”

Section: Introductionmentioning

confidence: 99%

Influence of Ethylene Signaling in the Crosstalk Between Fe, S, and P Deficiency Responses in Arabidopsis thaliana

et al. 2021

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To cope with P, S, or Fe deficiency, dicot plants, like Arabidopsis, develop several responses (mainly in their roots) aimed to facilitate the mobilization and uptake of the deficient nutrient. Within these responses are the modification of root morphology, an increased number of transporters, augmented synthesis-release of nutrient solubilizing compounds and the enhancement of some enzymatic activities, like ferric reductase activity (FRA) or phosphatase activity (PA). Once a nutrient has been acquired in enough quantity, these responses should be switched off to minimize energy costs and toxicity. This implies that they are tightly regulated. Although the responses to each deficiency are induced in a rather specific manner, crosstalk between them is frequent and in such a way that P, S, or Fe deficiency can induce responses related to the other two nutrients. The regulation of the responses is not totally known but some hormones and signaling substances have been involved, either as activators [ethylene (ET), auxin, nitric oxide (NO)], or repressors [cytokinins (CKs)]. The plant hormone ET is involved in the regulation of responses to P, S, or Fe deficiency, and this could partly explain the crosstalk between them. In spite of these crosslinks, it can be hypothesized that, to confer the maximum specificity to the responses of each deficiency, ET should act in conjunction with other signals and/or through different transduction pathways. To study this latter possibility, several responses to P, S, or Fe deficiency have been studied in the Arabidopis wild-type cultivar (WT) Columbia and in some of its ethylene signaling mutants (ctr1, ein2-1, ein3eil1) subjected to the three deficiencies. Results show that key elements of the ET transduction pathway, like CTR1, EIN2, and EIN3/EIL1, can play a role in the crosstalk among nutrient deficiency responses.

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Ethylene and Phloem Signals Are Involved in the Regulation of Responses to Fe and P Deficiencies in Roots of Strategy I Plants

Cited by 20 publications

References 66 publications

Nitrogen and Phosphorus Interplay in Lupin Root Nodules and Cluster Roots

Nitrogen and Phosphorus Interplay in Lupin Root Nodules and Cluster Roots

Influence of Ethylene Signaling in the Crosstalk Between Fe, S, and P Deficiency Responses in Arabidopsis thaliana

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