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

Couder, Eléonore; Mattielli, Nadine; Drouet, Thomas; Smolders, Erik; Delvaux, Bruno; Iserentant, Anne; Meeus, C.; Maerschalk, C.; Opfergelt, Sophie; Houben, David

doi:10.1016/j.crte.2015.05.004

Cited by 32 publications

(36 citation statements)

References 63 publications

(111 reference statements)

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“…The Zn was then purified by a novel chromatographic separation technique on microcolumns loaded with 0.2 ml AG1-× 8 resin. This method involves successive additions of acids: 6N HCl (for column conditioning and sample loading), 1 N HCl (for matrix rinsing) and 1N HNO 3 /HBr (for zinc fraction elution) (Couder et al, 2015). Upon separation the eluate was dried down and digested with 100 μl concentrated HNO 3 to dissolve potential co-eluted organics.…”

Section: Measurements Of Zn Concentration and Zn Isotope Compositionsmentioning

confidence: 99%

“…Crushed soil samples (~2 mg) were dry-ashed for 24 h at 450°C to remove organic matter (Couder et al, 2015). The dry-ashed samples were dissolved by applying the tri-acid digestion technique (with concentrated 14 M HNO 3 24 M HF and re-dissolution in 6 M HCl) in a Teflon Savillex® beaker placed on a hot plate (120°C) for evaporation until dryness (Couder et al, 2015). The Zn was then purified by a novel chromatographic separation technique on microcolumns loaded with 0.2 ml AG1-× 8 resin.…”

Section: Measurements Of Zn Concentration and Zn Isotope Compositionsmentioning

confidence: 99%

“…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). Plant litter at the soil surface is therefore generally isotopically lighter, and organic matter decomposition is considered to lead to the retention of heavier Zn isotopes by humification (Viers et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

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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: Measurements Of Zn Concentration and Zn Isotope Compositionsmentioning

confidence: 99%

Section: Measurements Of Zn Concentration and Zn Isotope Compositionsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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

et al. 2017

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“…There is now a considerable body of research on heavy metal isotopes in plants, including Fe (Arnold et al, 2015;Guelke and von Blanckenburg, 2007), Cu (Jouvin et al, 2012;Ryan et al, 2013;Weinstein et al, 2011), Zn (Couder et al, 2015;Moynier et al, 2009;Viers et al, 2015, Viers et al, 2007Weiss et al, 2005), Ca (Page et al, 2008), and Mg (Black et al, 2008;Bolou-Bi et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

“…As mineral elements are taken up by the plant root and translocated throughout the plant, Cu in the upper stems and branches is translocated upward from lower stems and branches. It is generally assumed that two main mechanisms are involved in the transport of Cu into stems and branches: diffusion of Cu over relatively short distances according to a concentration gradient (Moynier et al, 2009;Weinstein et al, 2011), and convective mass flow in the plant, controlled by transpiration (Barberon and Geldner, 2014;Couder et al, 2015;Lorenz et al, 1994).…”

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Cu isotopic compositions in Elsholtzia splendens: Influence of soil condition and growth period on Cu isotopic fractionation in plant tissue

Zhu

et al. 2016

Chemical Geology

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This study investigates the magnitude and direction of Cu isotopic fractionation in the Cu-tolerant, strategy I plant, Elsholtzia splendens, considering the effect of soil condition and plant growth cycle. Uptake of Cu by E. splendens from soil was found to favor light Cu isotopic enrichment (δ 65 Cu b 0‰) due to reduction at the soilroot interface. The magnitude of fractionation between soil and plant was found to be dependent on free Cu ion species in soil solution correlated with pH value of soil other than the phytoavailable component of soil or total soil for the same parent soil. Cu isotopic fractionation occurs in plant, the fractionation direction and magnitude would vary between different plant organs (i.e., root and stem) as well as different plant tissues (i.e., xylem and phloem). Remobilization of Cu associated with plant senescence was found to have a considerable effect on Cu isotopic fractionation within the plant, and the fractionation factor was found to change with the degree of remobilization. Overall, the results show that the Cu isotopic composition is useful as a tracer for probing the mechanisms of Cu translocation and retranslocation between soil and plants, and within plants.

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Use of Zinc Carbonate Spiking to Obtain Phytotoxicity Thresholds Comparable to Those in Field‐Collected Soils

Grigorita

Neaman

Brykova

et al. 2020

Enviro Toxic and Chemistry

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Several studies have reported the presence of smithsonite (ZnCO3) in soils polluted by zinc mining. The present study aimed to determine upper critical threshold values of Zn phytotoxicity in a substrate spiked with ZnCO3 and to compare them with those obtained in field‐collected soils. We studied Zn toxicity to perennial ryegrass (Lolium perenne L.) grown in pots with unpolluted peat treated with increasing concentrations of ZnCO3 that produced nominal total Zn concentrations of 0, 0.7, 1.3, 2.0, 2.6, and 3.3%. To keep constant near‐neutral pH value in all the treatments, we used decreasing concentrations of dolomitic lime. In the treatment with total soil Zn of 3.3% (pH 6.8), the foliar Zn concentration of L. perenne was 1914 ± 211 mg kg–1, falling into the range of 2400 ± 300 mg kg–1 reported for Lolium species grown under similar laboratory conditions in a polluted soil (total soil Zn 5.4%, pH 7.3) collected near a Zn smelter. The value of 92 ± 98 mg kg–1 was obtained for the median effective concentration (EC50) values of 0.01 M KNO3‐extractable Zn using the responses of shoot dry biomass, shoot length, and total pigments. This value falls within the range of 95 ± 46 mg kg–1 reported in other studies for the EC50 values of salt‐extractable Zn using field‐collected soils. The application of ZnCO3 for spiking was able to mimic foliar Zn concentrations of Lolium species observed in field‐collected soils. The effective concentrations of soil Zn obtained in the present study are comparable to those obtained in field‐collected soils. Future research should determine effective concentrations of metals using soils spiked with metal‐containing compounds that mimic a real source of contamination. Environ Toxicol Chem 2020;39:1790–1796. © 2020 SETAC

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

Cited by 32 publications

References 63 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

Cu isotopic compositions in Elsholtzia splendens: Influence of soil condition and growth period on Cu isotopic fractionation in plant tissue

Use of Zinc Carbonate Spiking to Obtain Phytotoxicity Thresholds Comparable to Those in Field‐Collected Soils

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