Similarities and Differences in the Acquisition of Fe and P by Dicot Plants

Lucena, Carlos; Porras, Rafael; Romera, Francisco J.; Alcántara, Estéban; García, María J.; Pérez‐Vicente, Rafael

doi:10.3390/agronomy8080148

Cited by 14 publications

(27 citation statements)

References 157 publications

(228 reference statements)

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“…The existence of cross talk between the responses to Fe and P deficiency could be associated with common signals in the activation of both nutrient deficiency responses, such as ethylene (Nagarajan and Smith, 2012; García et al, 2015; Lucena et al, 2015; Song and Liu, 2015; Neumann, 2016; Lucena et al, 2018), nitric oxide (NO; Graziano and Lamattina, 2007; Meng et al, 2012) and auxin (Chen et al, 2010; Miura et al, 2011; Bhosale et al, 2018). In relation to ethylene, the results presented in Figure 3 show that opt3-2 and pho2 , which exhibit constitutive Fe or P responses, respectively, have greater ACC content in roots than Col-0.…”

Section: Discussionmentioning

confidence: 99%

“…As a result, plants enhance acquisition of Fe and P through morphological and physiological responses in their roots. Deficiency of either nutrient initiates similar root responses, such as development of subapical root hairs or cluster roots and the acidification of the rhizosphere or the production of organic acids (Lucena et al, 2015; Song and Liu, 2015; Neumann, 2016; Stetter et al, 2017; Bhosale et al, 2018; Lucena et al, 2018). A defining feature of Strategy I plants is the need to reduce Fe(III), the most abundant form of Fe in soils, to Fe(II), prior to acquisition.…”

Section: Introductionmentioning

confidence: 99%

“…In previous works, it has been found that P deficiency induces the expression of Fe-related genes; that Fe deficiency induces the expression of P-related genes and that both deficiencies induce the expression of ethylene-related genes (reviewed in García et al, 2015; Lucena et al, 2015; Lucena et al, 2018). Taken together, these results suggest the existence of cross talk between Fe and P deficiency.…”

Section: Introductionmentioning

confidence: 99%

“…Taken together, these results suggest the existence of cross talk between Fe and P deficiency. The upregulation of Fe acquisition genes under P deficiency is generally associated to the increased accumulation of Fe in leaves (Wang Y. H. et al, 2002; Misson et al, 2005; Hirsch et al, 2006; Ward et al, 2008; Zheng et al, 2009; Abel, 2011; Perea-García et al, 2013; Wang et al, 2014, Lucena et al, 2018). On the other hand, P fertilization excess causes Fe chlorosis in calcareous soils (Romera et al, 1992; Sánchez-Rodriguez et al, 2013; Henry et al, 2017) and Fe deficiency affects P content in leaves (de Kock, 1955).…”

Section: Introductionmentioning

confidence: 99%

“…Either work in the nineties revealed links between ethylene and responses to deficiencies of Fe (Romera and Alcántara, 1994) and P (Borch et al, 1999). Although the regulation of the genes related to these responses is not totally understood, ethylene has since been implicated in the activation of both Fe-related genes ( AtFIT , AtFRO2 , and AtIRT1 ; Lucena et al, 2006; Lucena et al, 2015; Lucena et al, 2018; García et al, 2011; García et al, 2015) and P-related genes ( AtPht1;4 and AtPAP17 ; Lei et al, 2011; Roldán et al, 2013). In all cases, the activating effect of ethylene was dependent on the Fe or P status of the plants (García et al, 2011; Lei et al, 2011; Neumann, 2016; Liu et al, 2017), which suggests the involvement of signals other than ethylene in gene activation (García et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

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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

et al. 2019

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Iron (Fe) and phosphorus (P) are two essential mineral nutrients whose acquisition by plants presents important environmental and economic implications. Both elements are abundant in most soils but scarcely available to plants. To prevent Fe or P deficiency dicot plants initiate morphological and physiological responses in their roots aimed to specifically acquire these elements. The existence of common signals in Fe and P deficiency pathways suggests the signaling factors must act in conjunction with distinct nutrient-specific signals in order to confer tolerance to each deficiency. Previous works have shown the existence of cross talk between responses to Fe and P deficiency, but details of the associated signaling pathways remain unclear. Herein, the impact of foliar application of either P or Fe on P and Fe responses was studied in P- or Fe-deficient plants of Arabidopsis thaliana, including mutants exhibiting altered Fe or P homeostasis. Ferric reductase and acid phosphatase activities in roots were determined as well as the expression of genes related to P and Fe acquisition. The results obtained showed that Fe deficiency induces the expression of P acquisition genes and phosphatase activity, whereas P deficiency induces the expression of Fe acquisition genes and ferric reductase activity, although only transitorily. Importantly, these responses were reversed upon foliar application of either Fe or P on nutrient-starved plants. Taken together, the results reveal interactions between P- and Fe-related phloem signals originating in the shoots that likely interact with hormones in the roots to initiate adaptive mechanisms to tolerate deficiency of each nutrient.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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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

et al. 2019

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Review Article: The effect of humic substances on phosphate and iron acquisition by higher plants: Qualitative and quantitative aspects

Gerke¹

2021

J. Plant Nutr. Soil Sci.

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Humic substances affect iron (Fe) and phosphate (P) uptake by higher plants by two different ways. First, humic substances bind Fe(III) by forming humic‐Fe complexes of medium to high stability. In soils with pH > 5.0 these complexes account for most of the Fe in the soil solution, while dissolved Fe from Fe‐oxides exhibit an extreme low solubility (<< 0.1 µM). Humic‐Fe and humic‐Al complexes may bind P and form humic‐metal‐P complexes in the soil solution. Also, humic substances may desorb P bound to Fe(Al)‐oxides by binding to the P sorption sites of the oxides. These mechanisms may increase soil Fe and P availability. Second, humic substances affect several physiological processes of higher plants which are related to the acquisition of mineral nutrients from soil such as Fe and P. Soil humic substances exhibit plant hormone features, the quality and extend depending on the humic sources, the apparent molecular weight and the association status of the humic substances. They may affect the rooting pattern, the excretion of protons and carboxylic anions, the plasma membrane Fe‐reductase activity and they may activate Fe(II) and P transporters. Organic acid anions released by the roots can decrease the apparent molecular weight of the humic substances which may in turn increase the plant hormone activity of the humics. These mutual interactions can be described as soil‐root cross‐talking or humic acid cross‐interactions with roots.

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The arbuscular mycorrhizal mycelium from barley differentially influences various defense parameters in the non-host sugar beet under co-cultivation

et al. 2020

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The interactions between arbuscular mycorrhizal fungi (AMF) and non-host species are poorly studied. Particularly scarce is information on members of the Amaranthaceae/Chenopodiaceae family. Sugar beet (Beta vulgaris) plants were co-cultivated with a host species (Hordeum vulgare) in the presence (+AMF) or absence of Rhizophagus intraradices to explore the hypothesis that the presence of an active, pre-established AMF mycelium induces defense responses in the non-host species. Biomass of sugar beet did not respond to the +AMF treatment, while its root exudation of organic acids and phenolic acids was drastically decreased upon co-cultivation with +AMF barley. The most conspicuous effect was observed on a wide range of potential defense parameters being differentially influenced by the +AMF treatment in this non-host species. Antioxidant defense enzymes were activated and the level of endogenous jasmonic acid was elevated accompanied by nitric oxide accumulation and lignin deposition in the roots after long-term +AMF treatment. In contrast, significant reductions in the levels of endogenous salicylic acid and tissue concentration and exudation of phenolic acids indicated that AM fungus hyphae in the substrate did not induce a hypersensitive-type response in the sugar beet roots and downregulated certain chemical defenses. Our results imply that the fitness of this non-host species is not reduced when grown in the presence of an AMF mycelium because of balanced defense costs. Further studies should address the question of whether or not such modulation of defense pattern influences the pest resistance of sugar beet plants under field conditions.

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Similarities and Differences in the Acquisition of Fe and P by Dicot Plants

Cited by 14 publications

References 157 publications

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

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

Review Article: The effect of humic substances on phosphate and iron acquisition by higher plants: Qualitative and quantitative aspects

The arbuscular mycorrhizal mycelium from barley differentially influences various defense parameters in the non-host sugar beet under co-cultivation

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