Impact of Root-Induced Mobilization of Zinc on Stable Zn Isotope Variation in the Soil–Plant System

Houben, David; Sonnet, Philippe; Tricot, Guillaume; Mattielli, Nadine; Couder, Eléonore; Opfergelt, Sophie

doi:10.1021/es5002874

Cited by 49 publications

(48 citation statements)

References 64 publications

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“…With organic matter, there is a preferential retention of heavy Zn isotopes on phenolic sites of purified humic acids (Jouvin et al, 2009), which is also confirmed for surface complexation onto the organic coating of diatom cell walls (Gélabert et al, 2006) or bacteria (Kafantaris and Borrok, 2014). Zinc mobilization by plant roots or root exudates preferentially releases heavy Zn isotopes (Smolders et al, 2013;Houben et al, 2014). Within the plant, heavy Zn isotopes sorb onto the root surface, and light Zn isotopes are preferentially transported into aerial plant parts (Arnold et al, 2010;Aucour et al, 2011;Jouvin et al, 2012;Moynier et al, 2009;Weiss et al, 2005;Viers et al, 2007Viers et al, , 2015Couder et al, 2015;Tang et al, 2016;Caldelas and Weiss, 2017).…”

Section: Introductionmentioning

confidence: 83%

“…Additionally, the release of dissolved organic compounds, especially in rewetting periods (Fenner et al, 2001), was also found to favour the leaching of Zn through the formation of soluble metal-organic complexes (Kalbitz and Wennrich, 1998;Houben et al, 2013). Soil acidification and complexation with organic ligands mobilize preferentially heavy Zn isotopes (Houben et al, 2014;Balistrieri et al, 2008;Markovic et al, 2017;Fujii et al, 2014;Moynier et al, 2017). As a result, Zn leaching likely contributes to the Zn loss from HA-H soils and to the relative enrichment in light Zn isotopes in these organic-rich soils (Fig.…”

Section: Contribution From Organic Matter To the Zn Isotope Variationmentioning

confidence: 97%

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The influence of weathering and soil organic matter on Zn isotopes in soils

et al. 2017

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Section: Introductionmentioning

confidence: 83%

Section: Contribution From Organic Matter To the Zn Isotope Variationmentioning

confidence: 97%

The influence of weathering and soil organic matter on Zn isotopes in soils

et al. 2017

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“…It is generally accepted that the uptake of Zn from soil has at least four main mechanisms (see also Aucour et al, 2011;Caldelas et al, 2011;Houben et al, 2014;Jouvin et al, 2012;Tang et al, 2012 and references herein): (1) root-induced soil acidification and mobilization of soil Zn (Houben et al, 2014;Loosemore et al, 2004); (2) Zn adsorption on root cell wall (Hall, 2002); (3) non-specific Zn transfer through the plasma membrane into the root symplast via low-affinity transporters (Hacisalihoglu et al, 2001), or (4) Zn specific uptake by either ZIP proteins or phytosiderophores released by the plant roots to transfer the Fe/Zn complexes through the membrane (Claus et al, 2013). The present growth media are far from the Fe-or Zn-deficiency conditions, hence the release of siderophores by L. multiflorum roots was probably negligible (Rö mheld and Marschner, 1990).…”

Section: Species Differences In Zn Uptake Translocation and Isotope mentioning

confidence: 99%

“…The understanding of the Zn transfer processes between soils and plants should help us to fully assess the effects of anthropogenic activities on the metal cycling in the Earth's critical zone. Recent improvements in MC-ICP-MS (multiple collector inductively coupled plasma mass spectrometry) allow obtaining highly precise and accurate data for nontraditional stable zinc isotope compositions in plants and soils (e.g., Arnold et al, 2010aArnold et al, ,b, 2015Houben et al, 2014;Jouvin et al, 2009Jouvin et al, , 2012Moynier et al, 2009;Smolders et al, 2013;Tang et al, 2012;Viers et al, 2007;von Blanckenburg et al, 2009;Weiss et al, 2005). Zinc isotopes can be used as powerful tools for a better understanding of the mechanisms of Zn uptake, transport, storage, and tolerance by plants.…”

Section: Introductionmentioning

confidence: 99%

“…Various studies have measured the change in Zn fractionation between nutrient solutions, roots and shoots under deficient to adequate Zn supply (Arnold et al, 2010a;Jouvin et al, 2009Jouvin et al, , 2012Smolders et al, 2013;Viers et al, 2007;Weiss et al, 2005) but, as far as we know, much less studies have yet been made under toxic conditions (Aucour et al, 2011;Caldelas et al, 2011), especially on contaminated soils (Houben et al, 2014;Tang et al, 2012), where uptake and translocation mechanisms can be different compared to adequate Zn supply. As a result, the biogeochemical cycles of Zn are yet unclear for Zn-polluted sites.…”

Section: Introductionmentioning

confidence: 99%

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Transpiration flow controls Zn transport in Brassica napus and Lolium multiflorum under toxic levels as evidenced from isotopic fractionation

Couder

Mattielli

Drouet

et al. 2015

Comptes Rendus. Géoscience

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A B S T R A C TStable zinc (Zn) isotope fractionation between soil and plant has been used to suggest the mechanisms affecting Zn uptake under toxic conditions. Here, changes in Zn isotope composition in soil, soil solution, root and shoot were studied for ryegrass (Lolium multiflorum L.) and rape (Brassica napus L.) grown on three distinct metal-contaminated soils collected near Zn smelters (total Zn 0.7-7.5%, pH 4.8-7.3). The Zn concentrations in plants reflected a toxic Zn supply. The Zn isotopic fingerprint of total soil Zn varied from À0.05% to +0.26 AE 0.02% (d 66 Zn values relative to the JMC 3-0749L standard) among soils, but the soil solution Zn was depleted in 66 Zn, with a constant Zn isotope fractionation of about À0.1% d 66 Zn unit compared to the bulk soil. Roots were enriched with 66 Zn relative to soil solution (d 66 Zn root À d 66 Zn soil solution = D 66 Zn root-soil solution = +0.05 to +0.2 %) and shoots were strongly depleted in 66 Zn relative to roots (D 66 Zn shoot-root = À0.40 to À0.04 %). The overall d 66 Zn values in shoots reflected that of the bulk soil, but were lowered by 0.1-0.3 % units as compared to the latter. The isotope fractionation between root and shoot exhibited a markedly strong negative correlation (R 2 = 0.83) with transpiration per unit of plant weight. Thus, the enrichment with light Zn isotopes in shoot progressed with increasing water flux per unit plant biomass dry weight, showing a passive mode of Zn transport by transpiration. Besides, the light isotope enrichment in shoots compared to roots was larger for rape than for rye grass, which may be related to the higher Zn retention in rape roots. This in turn may be related to the higher cation exchange capacity of rape roots. Our finding can be of use to trace the biogeochemical cycles of Zn and evidence the tolerance strategies developed by plants in Znexcess conditions.

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Boron isotope variability related to boron speciation (change during uptake and transport) in bell pepper plants and SI traceable n(¹¹B)/n(¹⁰B) ratios for plant reference materials

Geilert

Vogl

Rosner³

et al. 2019

Rapid Comm Mass Spectrometry

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Rationale: Boron (B) is an essential micronutrient in plants and its isotope variations are used to gain insights into plant metabolism, which is important for crop plant cultivation. B isotope variations were used to trace intra-plant fractionation mechanisms in response to the B concentration in the irrigation water spanning the range from B depletion to toxic levels. Methods: A fully validated analytical procedure based on multi-collector inductively coupled plasma mass spectrometry (MC-ICP-MS), sample decomposition and B matrix separation was applied to study B isotope fractionation. The validation was accomplished by establishing a complete uncertainty budget and by applying reference materials, yielding expanded measurement uncertainties of 0.8‰ for pure boric acid solutions and ≤1.5‰ for processed samples. With this validated procedure SI traceable B isotope amount ratios were determined in plant reference materials for the first time. Results: The B isotope compositions of irrigation water and bell pepper samples suggest passive diffusion of the heavy 11 B isotope into the roots during low to high B concentrations while uptake of the light 10 B isotope was promoted during B depletion, probably by active processes. A systematic enrichment of the heavy 11 B isotope in higher located plant parts was observed (average Δ 11 B leaf-roots = 20.3 ± 2.8‰ (1 SD)), possibly by a facilitated transport of the heavy 11 B isotope to growing meristems by B transporters. Conclusions: The B isotopes can be used to identify plant metabolism in response to the B concentration in the irrigation water and during intra-plant B transfer. The large B isotope fractionation within the plants demonstrates the importance of biological B cycling for the global B cycle.

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Impact of Root-Induced Mobilization of Zinc on Stable Zn Isotope Variation in the Soil–Plant System

Cited by 49 publications

References 64 publications

The influence of weathering and soil organic matter on Zn isotopes in soils

The influence of weathering and soil organic matter on Zn isotopes in soils

Transpiration flow controls Zn transport in Brassica napus and Lolium multiflorum under toxic levels as evidenced from isotopic fractionation

Boron isotope variability related to boron speciation (change during uptake and transport) in bell pepper plants and SI traceable n(¹¹B)/n(¹⁰B) ratios for plant reference materials

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Impact of Root-Induced Mobilization of Zinc on Stable Zn Isotope Variation in the Soil–Plant System

Cited by 49 publications

References 64 publications

The influence of weathering and soil organic matter on Zn isotopes in soils

The influence of weathering and soil organic matter on Zn isotopes in soils

Transpiration flow controls Zn transport in Brassica napus and Lolium multiflorum under toxic levels as evidenced from isotopic fractionation

Boron isotope variability related to boron speciation (change during uptake and transport) in bell pepper plants and SI traceable n(11B)/n(10B) ratios for plant reference materials

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Boron isotope variability related to boron speciation (change during uptake and transport) in bell pepper plants and SI traceable n(¹¹B)/n(¹⁰B) ratios for plant reference materials