Physiology and Molecular Biology of Trace Element Hyperaccumulation

Merlot, Sylvain; Torre, Vanesa S. García de la; Hanikenne, Marc

doi:10.1007/978-3-030-58904-2_8

Cited by 13 publications

(14 citation statements)

References 271 publications

(371 reference statements)

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“…The first stage is the uptake and transport of a metal by the roots. The primary role in this process is played by members of the ZIP family (the zinc-regulated transporter/iron-regulated transporter-like proteins), whose expression is high in the roots and/or shoots of hyperaccumulating plants [ 45 , 46 , 67 ]. ZIP19 and ZIP23 transporters are mainly responsible for the uptake of zinc by the roots of A. halleri and N. caerulescens [ 46 ].…”

Section: Arabidopsis Arenosa and Heavy Metalsmentioning

confidence: 99%

“…ZIP19 and ZIP23 transporters are mainly responsible for the uptake of zinc by the roots of A. halleri and N. caerulescens [ 46 ]. In non-hyperaccumulator species, the expression of several ZIP genes is low and increases during Zn deficiency [ 46 , 67 ]. In addition, it was found that Cd treatment induces the higher expression of genes related to Cd uptake and transport in roots ( IRT1 , ZIF1 ) and shoot ( ZIF1 and YSL3 ), as well as Cd vacuolar sequestration ( HMA3 ) [ 68 ].…”

Section: Arabidopsis Arenosa and Heavy Metalsmentioning

confidence: 99%

“…In addition, it was found that Cd treatment induces the higher expression of genes related to Cd uptake and transport in roots ( IRT1 , ZIF1 ) and shoot ( ZIF1 and YSL3 ), as well as Cd vacuolar sequestration ( HMA3 ) [ 68 ]. IRT1 (iron-regulated transporter 1) encoding a low selective Fe-uptake transporter in the root epidermis is also involved in Zn, Cd and/or nickel (Ni) uptake [ 67 ]. Therefore, it has been shown that different expression levels of these genes in A. halleri are associated with the differential accumulation of these metals in shoots [ 68 , 69 ].…”

Section: Arabidopsis Arenosa and Heavy Metalsmentioning

confidence: 99%

“…Due to the presence of Casparian strips, the further transport of Zn is only possible via ZIP4/ZNT1 transporters. The increased expression of genes encoding these transporters was demonstrated in the roots of both A. halleri and N. caerulescens [ 46 , 67 , 71 ]. The next stage is the loading of metals into the xylem, which is mediated by the HM transporter, the HMA4 protein, a plasma membrane ATPase [ 40 , 72 ].…”

Section: Arabidopsis Arenosa and Heavy Metalsmentioning

confidence: 99%

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The Different Faces of Arabidopsis arenosa—A Plant Species for a Special Purpose

Gieroń

Sitko

Małkowski

2021

Plants

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The following review article collects information on the plant species Arabidopsis arenosa. Thus far, A. arenosa has been known as a model species for autotetraploidy studies because, apart from diploid individuals, there are also tetraploid populations, which is a unique feature of this Arabidopsis species. In addition, A arenosa has often been reported in heavy metal-contaminated sites, where it occurs together with a closely related species A. halleri, a model plant hyperaccumulator of Cd and Zn. Recent studies have shown that several populations of A. arenosa also exhibit Cd and Zn hyperaccumulation. However, it is assumed that the mechanism of hyperaccumulation differs between these two Arabidopsis species. Nevertheless, this phenomenon is still not fully understood, and thorough research is needed. In this paper, we summarize the current state of knowledge regarding research on A. arenosa.

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Section: Arabidopsis Arenosa and Heavy Metalsmentioning

confidence: 99%

Section: Arabidopsis Arenosa and Heavy Metalsmentioning

confidence: 99%

Section: Arabidopsis Arenosa and Heavy Metalsmentioning

confidence: 99%

Section: Arabidopsis Arenosa and Heavy Metalsmentioning

confidence: 99%

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The Different Faces of Arabidopsis arenosa—A Plant Species for a Special Purpose

Gieroń

Sitko

Małkowski

2021

Plants

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“…The physiological mechanisms underlying hyperaccumulation have been intensively studied and current knowledge is summarized in recent reviews representing many perspectives, including genetic, molecular, and evolutionary biology [13][14][15][16][17][18][19][20]. In very broad terms, hyperaccumulation involves the two suites of processes that can be termed metal accumulation and metal tolerance.…”

Section: Introductionmentioning

confidence: 99%

Intraspecific Variation in Nickel Tolerance and Hyperaccumulation among Serpentine and Limestone Populations of Odontarrhena serpyllifolia (Brassicaceae: Alysseae) from the Iberian Peninsula

Pollard

McCartha

Quintela-Sabarís

et al. 2021

Plants

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Odontarrhena serpyllifolia (Desf.) Jord. & Fourr. (=Alyssum serpyllifolium Desf.) occurs in the Iberian Peninsula and adjacent areas on a variety of soils including both limestone and serpentine (ultramafic) substrates. Populations endemic to serpentine are known to hyperaccumulate nickel, and on account of this remarkable phenotype have, at times, been proposed for recognition as taxonomically distinct subspecies or even species. It remains unclear, however, to what extent variation in nickel hyperaccumulation within this taxon merely reflects differences in the substrate, or whether the different populations show local adaptation to their particular habitats. To help clarify the physiological basis of variation in nickel hyperaccumulation among these populations, 3 serpentine accessions and 3 limestone accessions were cultivated hydroponically under common-garden conditions incorporating a range of Ni concentrations, along with 2 closely related non-accumulator species, Clypeola jonthlaspi L. and Alyssum montanum L. As a group, serpentine accessions of O. serpyllifolia were able to tolerate Ni concentrations approximately 10-fold higher than limestone accessions, but a continuous spectrum of Ni tolerance was observed among populations, with the least tolerant serpentine accession not being significantly different from the most tolerant limestone accession. Serpentine accessions maintained relatively constant tissue concentrations of Ca, Mg, K, and Fe across the whole range of Ni exposures, whereas in the limestone accessions, these elements fluctuated widely in response to Ni toxicity. Hyperaccumulation of Ni, defined here as foliar Ni concentrations exceeding 1g kg−1 of dry biomass in plants not showing significant growth reduction, occurred in all accessions of O. serpyllifolia, but the higher Ni tolerance of serpentine accessions allowed them to hyperaccumulate more strongly. Of the reference species, C. jonthlaspi responded similarly to the limestone accessions of O. serpyllifolia, whereas A. montanum displayed by far the lowest degree of Ni tolerance and exhibited low foliar Ni concentrations, which only exceeded 1 g kg−1 in plants showing severe Ni toxicity. The continuous spectrum of physiological responses among these accessions does not lend support to segregation of the serpentine populations of O. serpyllifolia as distinct species. However, the pronounced differences in degrees of Ni tolerance, hyperaccumulation, and elemental homeostasis observed among these accessions under common-garden conditions argues for the existence of population-level adaptation to their local substrates.

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