Toxicity of Naturally-Contaminated Manganese Soil to Selected Crops

Jun 26, 2014 - 42 Brno, Czech Republic. ABSTRACT: The impact of manganese excess using naturally contaminated soil (Mn-soil, pseudototal Mn 6494 vs ...
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Toxicity of Naturally-Contaminated Manganese Soil to Selected Crops Jozef Kovacik, Dagmar Št#rbová, Petr Babula, Pavel Švec, and Josef Hedbavny J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/jf5010176 • Publication Date (Web): 26 Jun 2014 Downloaded from http://pubs.acs.org on June 30, 2014

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Journal of Agricultural and Food Chemistry

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Toxicity of Naturally-Contaminated Manganese Soil to Selected Crops

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Jozef Kováčik†*, Dagmar Štěrbová†, Petr Babula‡, Pavel Švec†, Josef Hedbavny†

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Zemědělská 1, 613 00 Brno, Czech Republic

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Pharmaceutical Sciences Brno, Palackého 1/3, 612 42 Brno, Czech Republic

Institute of Chemistry and Biochemistry, Faculty of Agronomy, Mendel University in Brno,

Department of Natural Drugs, Faculty of Pharmacy, University of Veterinary and

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*

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Address: Institute of Chemistry and Biochemistry, Faculty of Agronomy, Mendel University

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in Brno, Zemědělská 1, 613 00 Brno, Czech Republic

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e-mail address: [email protected]

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phone: +420 545 133281

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fax: +420 545 212044

Corresponding author: Jozef Kováčik

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ABSTRACT

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Impact of manganese excess using naturally-contaminated soil (Mn-soil, pseudo-total Mn

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6,494 vs. 675 µg g-1 DW in control soil) in the shoots of four crops was studied. Mn content

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decreased in order Brassica napus > Hordeum vulgare > Zea mays > Triticum aestivum.

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Growth was strongly depressed just in Brassica (containing 13,696 µg Mn g-1 DW). Some

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essential metals (Zn, Fe) increased in Mn-cultured Brassica and Zea while macronutrients (K,

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Ca, Mg) decreased in almost all species. Toxic metals (Ni and Cd) were rather elevated in

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Mn-soil. Microscopy of ROS, NO, lipid peroxidation and thiols revealed stimulation in all

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Mn-cultured crops but changes were less visible in Triticum, a species with low shoot Mn

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(2,363 µg g-1 DW). Antioxidative enzyme activities were typically enhanced in Mn-cultured

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plants. Soluble phenols increased in Brassica only while proteins rather decreased in response

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to Mn excess. Inorganic anions (chloride, sulphate, and phosphate) were less accumulated in

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almost all Mn-cultured crops while nitrate level rather increased. Organic anions (malate,

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citrate, oxalate, acetate, and formate) decreased or remained unaffected in response to Mn-soil

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culture in Brassica, Hordeum and Triticum but not in Zea. However, the role of organic acids

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in Mn uptake in these species is not assumed. Because control and Mn-soil differed in pH (6.5

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and 3.7), we further studied its impact on Mn uptake in solution culture (using Mn

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concentration ~5 mM deducted from water-soluble fraction of Mn-soil). Shoot Mn contents in

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Mn-treated plants were similar to those observed in soil culture (high in Brassica and low in

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Triticum) and pH had negligible impact. Fluorescence indicator of “general ROS” revealed no

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extensive or pH-dependent impact either in control or Mn-cultured roots. Observed toxicity of

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Mn excess to common crops urges for selection of cultivars with higher tolerance.

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KEYWORDS: cereals; fluorescence microscopy; ion-exchange chromatography; oxidative

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stress; soil pollution.

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Journal of Agricultural and Food Chemistry

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INTRODUCTION

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Manganese (Mn) is an essential micronutrient for plants, being e.g. component of various

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enzymes.1 Its bioavailability increases with decreasing pH and Mn excess could therefore

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represent risk for plant growth in acidic soils2,3 though some reports show no impact of media

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pH on Mn uptake.4

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Compared to other metals, Mn uptake is relatively fast process that typically leads to

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depression of productivity in various crops5,6 while some cereals seem to be partially tolerant

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to high Mn excess.7,8 Mn uptake is also affected by various factors including given species,

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available nutrients or pH.3,4 To date, reports about effect of Mn excess on crops using

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artificially contaminated soil are rare2 but changes of Mn amount in plants grown on multi-

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metallic soils can be deducted.9,10

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Toxicity of metals is typically connected with oxidative damage (reactive oxygen

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species formation, ROS) being affected mainly by the given metal and exposure

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concentration.11,12 This oxidative stress is mainly controlled by various antioxidative enzymes

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to prevent damage.13 Despite high amount of Mn accumulated usually in plants, ROS

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formation is relatively slightly enhanced if assayed by classic spectrophotometry.6,7

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Fluorescence microscopy is more sensitive qualitative method owing to the use of specific

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reagents and it was previously reported that impact of Mn on ROS formation could be

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concentration-dependent.14 Mn toxicity may be attenuated by nitric oxide14,15 but its formation

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in crops has not yet been studies.

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Analyses of antioxidative enzyme activities revealed even no impact of Mn on

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peroxidase activity in some plants16 and generally stimulation of enzymes is lower in high Mn

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treatments compared to other metals7,8 or even depleted if plants contain high endogenous Mn

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amount.17 This indicates species-specific responses determined by both plant species and

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culture conditions. To our knowledge, comparison of various crops in the same work was not

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published but it is needed to provide background for further selection of species/cultivars

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tolerant to Mn excess.

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Despite numerous data related to Mn uptake and toxicity in various crops, our study is

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the first one where naturally-contaminated Mn soil was used. Fluorescence microscopy that is

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not frequently used in agricultural research was also carried out to detect symptoms of

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oxidative stress with sensitive techniques. Ion-exchange chromatography was involved in the

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monitoring of inorganic and mainly organic anions (aliphatic organic acids) that could

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participate in metal chelation. Besides, impact of pH on Mn uptake in some crops did not

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match with known fact that "its bioavailability increases with decreasing pH" as for example,

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potato contained more Mn at less acidic pH.3 Because control and Mn-soil we used differed in

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pH, further solution test was done to verify its involvement in Mn uptake.

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MATERIALS AND METHODS

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Plant Cultured and Experimental Design. Selected crops were tested in the present study

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(provided by Josef Hedbavny), namely Brassica napus cv. Smaragd, Hordeum vulgare cv.

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Bojos, Zea mays cv. Korneli, Triticum aestivum cv. Tiguan. Seeds were surface sterilized and

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sown directly to pots containing 500 g of control or naturally-contaminated soil (5 for Zea, 10

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for cereals and 20 seeds for Brassica in order to achieve approximately similar biomass/soil

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ratio). Control soil, collected on the field (by Jozef Kováčik, western Slovakia, village

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Bošany), is widely distributed in the Slovak Republic – Eutric Cambisol (with sandy loamy

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texture) as reported previously.18 Mn-contaminated soil was collected on the natural locality

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in the Krušné Hory Mountains (or Ore Mountains) as described in the previous paper.19 We

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note that origin of this soil is not clear but is probably natural because composition of plant

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species around and within this locality is similar (P. Švec, personal visitation). Soil moisture

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was maintained at 60% of water holding capacity with distilled water to prevent the impact on

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minerals. Cultivation was realized under laboratory conditions with ~300 µmol m-2 s-1 PAR at

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leaf level supplied by cool white fluorescent tubes L36W/840 (Lumilux, Osram), 25/20°C

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day/night temperature and relative humidity of ~60 %.14 Whole shoots of plants were

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harvested after 21 days of cultivation because growth retardation was visible. In the

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subsequent experiment, crops were sown directly on filter paper placed on glass balls in

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plastic box and supplemented with 5 mM MnCl2·4H2O solution (deducted from Mn content

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in water-soluble fraction of Mn-contaminated soil, see discussion) with pH 6.5 or 3.7 (based

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on pH of water extracts from control and Mn-contaminated soil, see results). Plants were

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harvested 10 days later because Brassica plants showed strong retardation of growth. For

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fresh mass-requiring parameters, individual plants were powdered using liquid N2 and fresh

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material was extracted as described below. Dry samples (dried at 75°C to constant weight)

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were analyzed for mineral nutrients including Mn.

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Quantification of Mn and Mineral Nutrients. Samples were prepared by

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mineralization of dry plant material (10-20 mg) in the mixture of concentrated HNO3 and

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water (5 + 5 ml) using microwave decomposition (Ethos Sel Microwave Extraction

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Labstation, Milestone Inc.) at 200°C over 1 h (complete duration of the mineralization

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program). Resulting clear solution was placed to glass flasks and diluted to a final volume of

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20 ml. Soil samples for total content of metals (more exactly it is pseudo-total content because

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primary HNO3 concentration in mineralizates is ca. 5 M and traces of metals may remained

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bound in silicates present in the soil) were prepared by the same way while water-soluble Mn

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and nutrients were extracted with deionised water as reported earlier.18 All measurements

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were carried out using an atomic absorption spectrometer AA30 (Varian Ltd.; Mulgrave,

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Australia) and the air-acetylene flame. Measurements of mineral nutrients were done as

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described previously and Mn was quantified at λmax = 279.5 nm, LOD of Mn was 2 µg/l.14

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Fluorescence Microscopy. For microscopic analyses, cross sections were taken ca. 1

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cm above the stem base and were immediately stained with respective reagents. General

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accumulation

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dichlorodihydrofluorescein diacetate (DCF-DA, 502Ex/526Em nm, Life Technologies, USA)

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and CellROX® Deep Red Reagent (644Ex/665Em nm, Life Technologies, USA). Staining

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procedure was conducted as reported previously.20 Nitric oxide or reactive nitrogen species

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(RNS) were visualized with 2,3-diaminonaphthalene (DAN, 365Ex/415Em nm, Sigma-Aldrich,

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USA) using 250 µM DAN for 1 h at room temperature.14 Lipid peroxidation was visualized

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by BODIPY® 581/591 C11 lipid peroxidation sensor (581Ex/591Em nm, Life Technologies,

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USA) and total thiols by monochlorobimane (394Ex/490Em nm) according to previous

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protocols.20,21 Staining solution was always removed by respective buffer and samples were

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observed using fluorescence microscope and appropriate set of filters (Axioscop 40, Zeiss,

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Germany).

of

ROS

was

monitored

using

two

widely-used

reagents:

2’,7’-

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Assay of Antioxidative Enzymes and Metabolites. For the assay of enzymatic

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activities, whole shoots were homogenized with inert sand in potassium phosphate buffer

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containing 1% insoluble PVPP (pH 7.0). Soluble proteins were quantified according to

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Bradford method22 and bovine serum albumin as standard (595 nm). Ascorbate peroxidase

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(APX) and guaiacol peroxidase (GPX) activities were measured as the oxidation of ascorbate

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and guaiacol at 290 and 470 nm, respectively.11,12,23 Glutathione reductase (GR) activity was

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assayed as the reduction of GSSG at 412 nm.11 Catalase activity was measured as the

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reduction of H2O2 to water monitored at 240 nm.23 Randomly selected supernatants were

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boiled and assayed in order to check that reactions were enzymatic.

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Total soluble phenols were extracted with 80% methanol and quantified using FolinCiocalteu method with gallic acid as standard and detection at 750 nm.23

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Journal of Agricultural and Food Chemistry

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Quantification of organic and inorganic anions was performed by an Ion-Exchange

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Chromatography system (DX 600, Dionex Corporation, Sun Valley, CA, USA) equipped with

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ED50 Electrochemical detector and conductivity cell installed in DS3 Detection Stabilizer

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and Anion Self-Regenerating Suppressor – Ultra II (2 mm, ASRS-ULTRA II) operating at

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100 mA in AutoSuppression Recycle Mode. Samples were prepared in deionised water (0.1 g

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FW/1 ml) that was found to be more suitable in comparison with acidified water (data not

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shown). Separation was carried out with an IonPac AS 11–HC (2 x 250 mm) analytical

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column and IonPac AS 11–HC (2 x 50 mm) guard column (Dionex Corporation, Sun Valley,

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CA, USA). The mobile phase consisted of deionised water (A) and 100 mM NaOH in

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deionised water (B). A linear gradient profile of the mobile phase from 1% B (0 – 4 min), 1 -

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15% B (4 – 12 min), 15 - 25% B (12 – 17 min), 25 - 45% B (17 – 20 min), 45 – 1% B (20 –

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21 min) was applied at a flow rate 0.35 ml/min. The column was equilibrated for 15 min

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under initial conditions prior to injection of the next sample. The column temperature was

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30°C and injection loop was 10 µl. The peak identity was confirmed by comparing the

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retention times with retention time of standards and by spiking standard solutions to the

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samples. Calibration curves were linear (r2 > 0.998) for each compound in the concentration

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range 1-100 µg ml-1. Limit of detection was 0.2-0.9 µg ml-1. Reagents (malic acid, citric acid,

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ammonium acetate, ammonium formate) were purchased from Sigma-Aldrich (Chemie

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GmbH, Steinheim, Germany), sodium hydroxide solution 50%, sodium phosphate and sodium

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sulphate were supplied by Fluka Chemie (Buchs, Switzerland) and other chemicals (sodium

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chloride, oxalic acid, potassium nitrate, sodium nitrite) were obtained from Penta Chrudim

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(Czech Republic). All chemicals used were of analytical grade. De-mineralized water with a

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specific resistance of 18.2 MΩ cm-1 (Mili-Q RG, Millipore, Bedford, MA, USA) was used to

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prepare all solutions and standards.

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Statistical Analyses. Two independent repetitions of the whole experiment were

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performed in order to check reproducibility. At least six pots were used for each crop and soil.

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Data were evaluated using ANOVA followed by a Tukey’s test (MINITAB Release 11,

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Minitab Inc.; State College, Pennsylvania) at P