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May 11, 2018 - Plant-driven changes to rhizosphere pH altered accumulation of lamotrigine (pKa = 5.7) but not carbamazepine, a non-ionizable contamina...
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Plant-induced Changes to Rhizosphere pH Impact Leaf Accumulation of Lamotrigine but not Carbamazepine Sara L Nason, Elizabeth Lianne Miller, K.G. Karthikeyan, and Joel A. Pedersen Environ. Sci. Technol. Lett., Just Accepted Manuscript • DOI: 10.1021/acs.estlett.8b00246 • Publication Date (Web): 11 May 2018 Downloaded from http://pubs.acs.org on May 12, 2018

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Plant-induced Changes to Rhizosphere pH Impact Leaf Accumulation of Lamotrigine but not Carbamazepine

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Sara L. Nason†, Elizabeth L. Miller‡, K.G. Karthikeyan†,§, Joel A. Pedersen*,†,‡,ǁ

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Environmental Chemistry and Technology Program, University of Wisconsin, Madison, WI 53706 ‡

§

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Molecular and Environmental Toxicology Center, University of Wisconsin, Madison, WI 53706

ǁ

Department of Biological Systems Engineering, University of Wisconsin, Madison, WI 53706

Departments of Soil Science, Civil & Environmental Engineering, and Chemistry, University of

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Wisconsin, Madison, WI 53706

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*Corresponding author: [email protected]

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ABSTRACT. Many ionizable organic contaminants (IOCs) are present in treated wastewater

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used to irrigate edible crops and accumulate in plants under field conditions. Phytoavailability of

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IOCs with pKa values between 4 and 9 may be affected by the pH of the rhizosphere (the water

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and soil within 2-3 mm of the root surface). Plants can alter rhizosphere pH by 2 to 3 units in

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either direction in response to nutrient availability. The effects of plant modulation of

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rhizosphere pH on IOC accumulation has not been previously reported. Here we provide direct

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evidence that plant-driven changes in rhizosphere pH impact accumulation of an IOC in plant

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leaves. Using a modified hydroponic system, we found that rhizosphere pH was higher by 1.5-

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2.5 units when plants received only nitrate rather than a combination of nitrate and ammonium.

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Plant-driven changes to rhizosphere pH altered accumulation of lamotrigine (pKa = 5.7) but not

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carbamazepine, a non-ionizable contaminant. Lamotrigine accumulation in leaves correlated

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strongly with the concentration of the neutral species available in porewater. We expect plant-

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driven changes in rhizosphere pH to be important across a wide range of plant species and IOCs.

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Consideration of plant modulation of rhizosphere pH may be necessary to accurately predict IOC

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bioaccumulation.

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INTRODUCTION

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Conventional wastewater treatment processes do not completely remove many ionizable

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organic contaminants (IOCs), including pharmaceuticals.1 Irrigation of food crops with

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reclaimed wastewater and effluent-dominated water sources is common in arid regions

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worldwide2 and is expected to grow as global climate warms, population increases, and demands

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on freshwater sources rise. Crop plants can accumulate pharmaceuticals in edible tissues under

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field conditions,3–5 prompting the need to evaluate the potential risks associated with effluent

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irrigation of food crops.

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Understanding the controls on IOC availability to plants may allow identification of

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situations that lead to unacceptable accumulation in food crops. Current models have had limited

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success predicting IOC uptake by crops.3 A variety of processes in the immediate vicinity of root

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surfaces (the rhizosphere) can impact contaminant uptake by plants. Plants alter rhizosphere pH

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to maintain electrochemical equilibrium as they take in nutrients. Root cells release H+ to the

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rhizosphere as they take in cations (e.g., NH4+). Energy for anion (e.g. NO3–) uptake is provided

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via co-transport of H+ from the rhizosphere into cells.6 These processes can raise or lower

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rhizosphere pH by 2-3 units up to 2-3 mm from the root surface, resulting in rhizosphere pH

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values of 4-8, depending on initial conditions.6–8 Speciation impacts IOC degradability,9 sorption

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to soil particles10,11 and plant roots,11,12 uptake by roots,11–13 and movement through plants.11,12,14

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Additionally, organic root exudates can alter sorption, stimulate microbial growth, and influence

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the degradative capability of microorganisms.15–18 Changes in rhizosphere pH can affect copper,

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uranium, cadmium, and inorganic nutrient phytoaccumulation from soils.6,19–22 Published studies

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on IOC phytoaccumulation have invoked differences between rhizosphere and bulk soil pH to

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explain uptake trends;23–25 however, direct demonstration of the impact of plant-induced changes

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in rhizosphere pH on IOC phytoaccumulation has not been previously reported.

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This study focuses on the ionizable phenyltriazine anticonvulsant lamotrigine (LTG,

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conjugate acid pKa = 5.7)26 and the non-ionizable tricyclic anticonvulsant carbamazepine (CBZ),

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which have been detected in reclaimed wastewater (concentrations up to 488 and 1,110 ng·L-1,

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respectively)27,28 and accumulate in effluent-irrigated plants.23,25 Both LTG and a primary CBZ

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metabolite, 10,11-epoxycarbamazepine (epCBZ), can accumulate in carrots irrigated with

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reclaimed wastewater to levels exceeding the threshold of toxicological concern at normal

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ingestion rates.23 This threshold serves as a conservative indicator of when additional study of

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toxic effects is warranted.29,30

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We examined the effects of plant-driven changes to rhizosphere pH on trends in LTG and

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CBZ accumulation by wheat plants. We cultivated wheat with different forms of inorganic

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nitrogen in a growth system designed to isolate the rhizosphere.19–21 We measured pH and

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pharmaceutical concentrations in the model rhizosphere and related them to accumulation of

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CBZ and LTG. We tested an ionizable and a non-ionizable contaminant to discriminate between

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effects on accumulation due to changes in rhizosphere pH and those due to other potential

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changes to the plants caused by the different nitrogen sources.

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MATERIALS AND METHODS

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Plant Growth. Durum wheat (Triticum durum) seeds were sterilized, soaked, and

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germinated in a damp paper towel. After 2-5 days, sprouted seeds were transferred to growth

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cells (Figure S1).20,31,32 Four seeds were placed inside each cell, and plants were cultured

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hydroponically for 21 days, allowing the roots to grow into a mat against a layer of 30-µm nylon

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mesh (Text S.1.3).20

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On day 22, each growth cell was transferred to a model rhizosphere setup, placing the mesh

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containing the root mat against a thin layer (5.00 g) of ultrapure quartz sand. A strip of cellulose

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filter paper wicked nutrient solution to the sand from a reservoir (replenished every 2 days). All

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components were autoclaved or washed with methanol to minimize microbial growth. Sand and

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paper were saturated with nutrient solution (containing 100 µg·L-1 LTG or CBZ) for the 8-day

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exposure period. Half the rhizosphere setups received nutrient solution with nitrate as the sole

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nitrogen source; the other half received a solution containing a 1:2 ammonium-to-nitrate molar

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ratio (Text S.1.3). Nutrient solutions had equivalent ionic strength and were adjusted to pH 5.7.

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Solution composition was chosen to induce differences in rhizosphere pH while minimizing

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effects on plant growth. Each treatment (pharmaceutical + solution combination) was replicated

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nine times; controls lacking pharmaceuticals or plants were conducted in triplicate. One replicate

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represents a growth cell containing four plants. After 8 days, above-ground tissues (hereafter

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leaves), roots, and sand were collected, frozen at –80 °C, freeze-dried, and stored at –80 °C until

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extraction. Plant and sand masses were measured before and after freeze-drying.

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Extraction

and

Liquid-Chromatography-Tandem-Mass-Spectrometry

(LC-

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MS/MS). Freeze-dried sand from each replicate was rehydrated with 10 mM CaCl2 for pH

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determination.33 Freeze-dried plant samples were ground, spiked with mass-labeled internal

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standards, and subjected to Accelerated Solvent Extraction with methanol (10,300 kPa, 80 °C).

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Extracts were evaporated to dryness and reconstituted in 4:1 water:acetonitrile with 0.1% acetic

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acid. We measured LTG, CBZ, and the primary CBZ metabolites epCBZ and 10,11-trans-

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dihydroxycarbamazepine (diOH-CBZ) in leaf and root extracts, sand rehydration solution, and

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nutrient solution before and after a two-day replenishment cycle using LC-MS/MS (Agilent 1260

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HPLC, Waters Xterra MS C18 column, Agilent 6460 triple quadrupole mass spectrometer, ESI+

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source) (Text S.1.4-S.1.7).

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RESULTS AND DISCUSSION

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Plant Modulation of Rhizosphere pH. Wheat plants altered porewater pH in the model

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rhizospheres in response to the form of inorganic nitrogen provided (Figure 1). Nutrient solution

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pH in the reservoirs was initially 5.7 ± 0.05 and differed by 99% LTG was

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in the neutral form. This difference has been noted previously23,25,35 and may be caused by ion

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trapping in root cell vacuoles.3,24,25 Lamotrigine speciation is dominated by LTG0 in root cell

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cytosol (pH 7-7.4)11 and by LTG+ in vacuoles (pH 4-5.5).11 Thus, if LTG0 crosses the vacuole

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membrane, a portion will remain trapped in the vacuole as LTG+, unable to be translocated

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through the plant. We also cannot exclude the possibility that CBZ and LTG accumulation

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differs due at least in part to differential metabolism in planta. This topic merits future

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investigation.

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Environmental Implications. We isolated the effect of nitrogen source-induced

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rhizosphere pH changes on plant accumulation of an IOC, a process that we expect also occurs in

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the field and may increase in importance if elevated atmospheric CO2 concentrations promote

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root exudation of organic acids and shift plant assimilation preferences to reduced nitrogen

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forms.36–39 We expect our results to serve as a basis for future experimental studies that

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incorporate more of the complexity that exists in field scenarios. Discussion is therefore

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warranted of how simplifications in our model system may result in differences from what

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occurs in the field.

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The model rhizosphere consisted of ultrapure quartz sand with low pH buffering capacity and

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low sorption capacity for CBZ and LTG.24 Sorption had little impact on our findings, but pH-

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dependent sorption processes could significantly influence contaminant availability to plants

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grown in field soils. The magnitude and spatial extent of rhizosphere pH change depends on the

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buffering capacity of the soil. Nonetheless, even in a soil with high buffering capacity due to

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30% CaCO3 content, chickpeas changed pH by ~2 units within 1 mm of the root surface.6

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Overall, we expect plant-driven changes in rhizosphere pH to be important under field conditions

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for the accumulation of IOCs with pKa values between 4 and 9, although pH-dependent sorption

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to soil constituents and high soil buffering capacity may impact relative trends in

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phytoavailability. Using different initial pH and nutrient ratios could result in a higher or lower

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rhizosphere pH range than observed in our study.

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We used durum wheat, a species used in previous rhizosphere pH studies.20 Other species

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known to alter rhizosphere pH in response to inorganic nitrogen availability include maize,

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sorghum, chickpea, Norway spruce, white lupine, white clover, tomato, and rapeseed.8,19 Species

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demonstrated to alter rhizosphere pH include graminaceous and non-graminaceous monocots,

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dicots, and species with and without N2-fixing symbionts.8 We expect the effect demonstrated in

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this study to be important across most crop species, although the magnitude of plant-driven

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changes in rhizosphere pH is species-specific and can vary among cultivars.8

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Rhizosphere microbiota vary among soils and plant species and can affect pH, nutrient

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availability, and contaminant degradation. Their effect on contaminant phytoavailability and the

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impact of contaminants on rhizosphere microbial communities have received little study.

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Although our growth system was not sterile, we expect that any influence of microorganisms on

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our results was small; we saw no evidence of microbial growth, and the observed pH shifts

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resembled previously reported plant-induced rhizosphere pH changes.20,32 Rhizosphere

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microbiota are a potential factor that could cause differences between our model system and field

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conditions, even when the same process of nutrient-driven rhizosphere pH change occurs.

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We suggest future studies on plant accumulation of IOCs report the main forms of nitrogen

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and other nutrients supplied to the plants and consider rhizosphere pH. Differences in compound

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speciation between the rhizosphere and bulk soil may hinder the ability to predict plant uptake of

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IOCs. State-of-the-art models for organic contaminant uptake allow specification of soil

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porewater pH.11 While knowledge of rhizosphere pH is required to account for the differential

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contaminant uptake demonstrated in the present study, the underlying processes leading to

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modulation of rhizosphere pH are not currently incorporated into such models. We suggest future

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models explicitly incorporate rhizosphere processes, as has been done for a model to predict

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uranium phytoaccumulation.22 Plants irrigated with reclaimed wastewater are exposed to and

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accumulate a large variety of IOCs; testing all current and future IOCs is impractical. Accurate

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prediction of IOC accumulation in plants may require detailed understanding of the impact of

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rhizosphere processes on IOC availability.

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ASSOCIATED CONTENT

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Supporting information (SI) is available. SI contains methodological details and additional

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results noted in the main text.

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AUTHOR INFORMATION

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Corresponding Author

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* Phone: +1 (608) 263-4971. Email: [email protected].

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ORCID

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Sara Nason: 0000-0002-3866-6399

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Liz Miller: 0000-0002-9711-2863

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K.G. Karthikeyan: 0000-0002-2478-4941

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Joel Pedersen: 0000-0002-3918-1860

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Notes

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The authors declare no competing financial interest.

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ACKNOWLDEGEMENTS

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We thank Prof. Christina Remucal and Dr. Curtis Hedman for use of instruments and laboratory

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space, Troy Humphry for help with growth cell construction, and Rhea Ewing for help with

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artwork. This work was funded by USDA-CSREES Hatch project WIS01647 and U.S.-Israel

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Binational Agriculture Research & Development Fund grant US-4771-14R. J.A.P. acknowledges

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support from the William A. Rothermel Bascom Professorship.

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pore water pH

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A

A C

6

5 NO₃⁻

NH₄⁺ + NO₃⁻

NO₃⁻

NH₄⁺ + NO₃⁻

plants

no plants

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Figure 1. Wheat plants altered porewater pH in model rhizospheres in response to the form of nitrogen

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provided. Plants raised porewater pH when supplied with nitrate as the sole nitrogen source. The pH in

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the nutrient solution reservoirs at the end of each solution replenishment cycle varied from the initial

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value by ≤ 0.1 pH unit. Letters indicate statistical significance based on a Wilcoxon/Kruskal-Wallis test

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with Steel-Dwass post hoc analysis (p ≤ 0.05). Bars represent mean values; error bars indicate one

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standard deviation (n = 21 for treatments with plants; n = 9 for treatments lacking plants).

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bioconcentration factor (L·kg-1)

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Form of Nitrogen

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Nitrate Ammonium + Nitrate

120 90

p = 3x10-4

60 30 0

LTG roots CBZ roots LTG leaves CBZ leaves

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Figure 2. Bioconcentration factors for lamotrigine (LTG) and carbamazepine (CBZ) in the roots and

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leaves of wheat plants supplied with the indicated nitrogen sources. Lamotrigine accumulation in the

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leaves of plants provided with only nitrate exceeded that in plants receiving both ammonium and nitrate

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by a factor exceeding two. Bioconcentration factors were calculated by dividing the concentration in the

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plant roots or leaves by that in the porewater at the end of the exposure period. Porewater concentrations

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of LTG and CBZ did not differ between nitrate and ammonium + nitrate treatments (Figure S3).

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Concentrations measured in the plant tissue followed the same trends as the shown bioconcentration

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factors. Welch’s t-test was used for pairwise comparison between treatments. Error bars indicate one

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standard deviation.

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Figure 3. Lamotrigine (LTG) accumulation in wheat leaves and roots correlated with the concentration of

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the neutral LTG species in porewater (calculated via the Henderson-Hasselbalch equation). White and

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yellow circles correspond to plants provided with nitrate as the sole nitrogen source. Red and black

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triangles correspond to plants provided with ammonium + nitrate. The bottom line shows a linear

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regression of the concentration of LTG in leaves against the concentration of neutral LTG in porewater

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(R2 = 0.73). The slope is 0.015 ± 0.002 (p = 1.4 × 10-5), the y-intercept does not differ from zero (p =

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0.31). The top line shows a linear regression of LTG concentration in plant roots against the concentration

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of neutral LTG in porewater (R2 = 0.27). The slope is 0.023 ± 0.009 (p = 0.032), the y-intercept is 23 ± 2

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(p = 9.7 × 10-8).

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LTG0 Nutrient Solution

Nitrate Only

CBZ

pH

Nitrate + Ammonium

pH

+ LTG

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+H