Environmental fate of RNA interference pesticides: Adsorption and

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Environmental fate of RNA interference pesticides: Adsorption and degradation of double-stranded RNA molecules in agricultural soils Kimberly M. Parker, Verónica Barragán Borrero, Daniël M. van Leeuwen, Mark A. Lever, Bogdan Mateescu, and Michael Sander Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.8b05576 • Publication Date (Web): 25 Jan 2019 Downloaded from http://pubs.acs.org on January 25, 2019

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Environmental fate of RNA interference pesticides: Adsorption and degradation of double-

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stranded RNA molecules in agricultural soils

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Kimberly M. Parker,*a,b Verónica Barragán Borrero,c Daniël M. van Leeuwen,c Mark A.

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Lever,b Bogdan Mateescu,c Michael Sander*b

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a Department

7 8 9

of Energy, Environmental & Chemical Engineering,

Washington University in St. Louis, St. Louis, Missouri 63130, United States b Institute c

of Biogeochemistry and Pollutant Dynamics, ETH Zurich, 8092 Zurich, Switzerland

Institute of Molecular Plant Biology, Department of Biology, ETH Zurich, 8092 Zurich,

10

Switzerland

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*(K.M.P.) Email: [email protected], phone: (314)935-3461; fax: (314)935-7211.

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*(M.S.) Email: [email protected]; +41(0)44 632 8314.

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Words: 5,342.

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Figures: 4 (2,100 word-equivalents).

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Total word-equivalents: 7,442.

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Abstract.

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Double-stranded RNA (dsRNA) pesticides are a new generation of crop protectants that

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interfere with protein expression in targeted pest insects by a cellular mechanism called RNA

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interference (RNAi). The ecological risk assessment of these emerging pesticides necessitates an

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understanding of the fate of dsRNA molecules in receiving environments, among which

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agricultural soils are most important. We herein present an experimental approach using

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phosphorous-32 (32P)-radiolabeled dsRNA that allows studying key fate processes of dsRNA in

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soils with unprecedented sensitivity. This approach resolves previous analytical challenges in

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quantifying unlabeled dsRNA and its degradation products in soils. We demonstrate that

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dsRNA and its degradation products are quantifiable at concentrations as low as a few nanogram

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dsRNA per g soil by both Cerenkov counting (to quantify total 32P-activity) and by polyacrylamide

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gel electrophoresis (PAGE) followed by phosphorimaging (to detect intact 32P-dsRNA and its 32P-

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containing degradation products). We show that dsRNA molecules added to soil suspensions

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undergo adsorption to soil particle surfaces, degradation in solution, and potential uptake by soil

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microorganisms. The results of this work on dsRNA adsorption and degradation advance a

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process-based understanding of the fate of dsRNA in soils and will inform ecological risk

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assessments of emerging dsRNA pesticides.

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32P-

2

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Introduction.

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RNA interference (RNAi) has recently been implemented in agricultural biotechnology to

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protect crops against pests.1-8 RNAi is a conserved cellular mechanism in eukaryotic organisms

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that regulates gene expression at a post-transcriptional stage by disrupting the translation of

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messenger RNAs (mRNAs) into proteins.9,10 In RNAi-based crop protection, pesticidal double-

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stranded RNA (dsRNA) is taken up by the target pest (e.g., through ingestion) and subsequently

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directs the degradation of specific, targeted pest mRNA.4,5,7,11 Degradation of this mRNA prevents

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the synthesis of essential proteins in the pest, resulting in reduced pest growth or leading to pest

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mortality.5,12-15 RNAi biotechnology has been shown to be effective against an array of agricultural

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pests including insects, nematodes, viruses and fungi.8 The first commercially-available RNAi-

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based product targeting an insect pest is a genetically engineered maize that expresses a dsRNA

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pesticide within the plant’s tissue (e.g., as a so-called “plant-incorporated protectant”).1,16

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However, RNAi-based crop protection can also be achieved by applying exogenous dsRNA

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pesticides to crops.17,18

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Agricultural use of RNAi biotechnology is expected to result in the release of pesticidal

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dsRNA to agricultural soils and other secondary receiving environments.19 Consequently, dsRNA

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pesticides must undergo ecological risk assessment (ERA) to evaluate potential ecological hazards

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to non-target organisms that may be exposed to the dsRNA.20,21 However, ERAs are currently

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challenged by a poor understanding of dsRNA fate and stability in soils, resulting in large

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uncertainties in estimated dsRNA pesticide concentrations in soils and hence exposure levels of

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non-target organisms.19 Consequently, process-oriented research on dsRNA fate in soils has been

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requested by the Scientific Advisory Panels to the U.S. Environmental Protection Agency,22-24 as

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well as other U.S. and European regulatory agencies.25,26

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To date, there are only a few published studies assessing dsRNA fate in soils and sediments

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using laboratory incubations.27-29 These studies universally determined dsRNA dissipation (i.e.,

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concentration decrease of intact dsRNA over time) using hybridization assays.30 While these

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studies demonstrated decreasing dissolved dsRNA concentrations over the timescale of days, their

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experimental approach required relatively high dsRNA concentrations (i.e., g/mL or g/g-soil

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levels)27-29 and did not allow the contributions of dsRNA adsorption to particle surfaces and of

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dsRNA (bio)degradation to the overall concentration decrease to be assessed. As both adsorption

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and degradation are expected to control dsRNA fate in receiving environments19 based existing

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knowledge on the fate of DNA and single-stranded RNA (ssRNA),31-35 a clear delineation of

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adsorption and degradation of dsRNA in soils at environmentally relevant dsRNA concentrations

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(likely ng/g-soil or lower levels, as calculated in the Supporting Information (SI)) is critical for

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ERAs.19 Specifically, analytical approaches are needed to quantify and differentiate both dissolved

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and adsorbed dsRNA molecules, as well as products of dsRNA degradation and incorporation into

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biomolecules.

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The goal of this work was to investigate adsorption and degradation of dsRNA molecules

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in agricultural soils. To this end, we developed an approach using 32-phosphorous (32P)-labeling

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of dsRNA in combination with radiochemical analysis techniques. Previously, DNA fate has been

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investigated using tritium labeling (3H).34-36 As opposed to working with unlabeled dsRNA

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molecules, the use of the

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quantification of both intact dsRNA and products of dsRNA degradation and also enables

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balancing of

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and associated with soil particulates. The half-life of

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investigate adsorption and degradation of 32P-dsRNA in soils, as both processes are expected to

32P-activity

32P-labeled

added as

dsRNA (hereafter

32P-dsRNA

32P-dsRNA)

via quantification of 32P

enables highly sensitive

32P-activity

both in solution

(14.3 days) is sufficiently long to

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occur over hour to day timescales.27-29 In this study, we investigated adsorption and degradation

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of freely dissolved

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processes investigated herein apply to dsRNA pesticides that are exogenously applied to crops

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(e.g., via spray application)17 and that are released from the tissue of RNAi crops into soils. In case

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of the latter, we note that the scope of our study did not allow also addressing potential processes

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that affect dsRNA molecules within RNAi crop tissue prior to their release into the soil. We first

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assessed degradation of

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(Scheme 1A). In a second set of experiments, we investigated concurrent degradation and

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adsorption of

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implications of the experimental results for the fate of dsRNA molecules in agricultural soils in

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the broader context of ERA of dsRNA pesticides.

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Materials and Methods.

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Synthesis of 32P-dsRNA molecules.

32P-dsRNA

molecules in soil solutions and suspensions. We expect that the

32P-dsRNA

32P-dsRNA

in solutions prepared from an agricultural soil suspension

added to soil suspensions (Scheme 1B). Finally, we discuss the

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Materials and supplies used in this study are described in the SI. We synthesized a 32P-

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dsRNA molecule with 261 base pairs (bp), similar in size to emerging dsRNA pesticides.5,13,37 The

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synthesis method is detailed in the SI. In brief, the DNA templates were first amplified by

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polymerase chain reaction (PCR) using forward primers containing the T7 promoter sequence.

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Next, sense and antisense ssRNA molecules were produced by in vitro transcription of the DNA

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templates using T7 RNA polymerase. The produced molecules were confirmed to be the correct

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size (Figure S1). Both sense and antisense ssRNA strands were 32P-labeled by introducing [alpha-

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32P]uridine

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during the in vitro transcription reaction. Finally, the sense and antisense 32P-ssRNA strands were

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mixed in equimolar concentrations and annealed to produce the 32P-dsRNA molecule. The 32P-

triphosphate (UTP) (800 Ci/mmol; such that 1% of the total UTP was

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32P-labeled)

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dsRNA was stored frozen until its use in experiments. At the start of each experiment, the nominal

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32P-dsRNA

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presence of intact 32P-dsRNA was verified across experiments by analysis of controls (e.g., shown

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in Figure 1A,B, as well as additional figures in the SI) prepared using the same 32P-dsRNA stock

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interspersed among the experiments.

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Soil preparation and characterization.

concentration was verified by measuring 32P activity aliquoted into each sample. The

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A total of six diverse agricultural standard soils were obtained from the

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Landwirtschaftliche Untersuchungs- und Forschungsanstalt Speyer (LUFA Speyer) (Table S2).

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The soils included one loamy sand (soil 2.1), three sandy loams (soils 2.2, 2.3, and 5M), one loam

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(soil 2.4), and one clay (soil 6S). Each soil was homogenized by sieving (2 mm) and stored in the

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dark at 4 ºC until use. Subsamples of the six soils were treated with X-ray irradiation (dose = 43.5

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kGy) by Synergy Health Däniken AG to decrease microbial activity. Effectiveness of this

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treatment was confirmed by decreased soil basal respiration and abundance of viable

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microorganisms in the irradiated soils relative to the untreated soils (Figure S2-S5).

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Incubation of 32P-dsRNA in soil solutions and suspensions.

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In the first set of experiments (Scheme 1A), we incubated 32P-dsRNA in soil solutions. Soil

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solutions were obtained by placing soil samples (0.20 g) in nuclease-free microcentrifuge tubes

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(selected due to negligible 32P-dsRNA adsorption to tube walls, Figure S6), followed by adding

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0.4 mL incubation buffers to each tube. The incubation buffers contained sodium chloride (10

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mM) and either 4-morpholineethanesulfonic acid (MES, pKa= 6.15; used for soils 2.1, 2.2, and

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2.3) or 4-morpholinepropanesulfonic acid (MOPS, pKa= 7.20; used for soils 2.4, 5M, and 6S)

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(both 5 mM) and were adjusted to the pH of the soils (4.9-7.4, Table S2). The identity and

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concentration (5 mM) of the buffer were selected to result in stable pH buffering during the

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incubation at the natural pH values reported for the respective soils. We chose organic pH-buffers

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over phosphate which would have competed with dsRNA for adsorption sites on mineral

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surfaces.38,39 Following initial vortex mixing, soil samples were incubated for 24 hr under

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horizontal shaking (500 rpm; 22 ºC). At the end of the incubation, the samples were centrifuged

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for 5 minutes (10,000 RCF; 4 ºC). The supernatant solution (0.325 mL) was then pipette-

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transferred to a new microcentrifuge tube. To this solution, we added

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concentration = 30 ng/mL), followed by incubation for 0.5, 3 or 24 hr under horizontal shaking

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(500 rpm; 22 ºC). Finally, the 32P-dsRNA and its degradation products in the soil solution were

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analyzed as described below.

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In the second set of experiments (Scheme 1B), we incubated

32P-dsRNA

32P-dsRNA

(final

in soil

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suspensions. We added 0.4 mL incubation buffer containing 30 ng/mL

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sample (0.20 g). After initial mixing, samples were incubated (0.3-30 hr) under horizontal shaking

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(500 rpm; 22 ºC). At the end of the incubation, the samples were centrifuged for 5 minutes (10,000

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RCF; 4 ºC). The supernatant solution (0.325 mL) was transferred to a new microcentrifuge tube

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for analysis. Next, from the soil pellet, dsRNA was extracted into 0.55 mL extraction buffer (220

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mM borate, pH 9.4; 7 mM EDTA; 3 mM sodium hexametaphosphate, to competitively displace

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dsRNA from particle surfaces). This extraction buffer composition was adapted from buffers

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effective in extracting DNA and RNA from sediments,40 while minimizing artefactual dsRNA

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degradation (i.e., base-catalyzed hydrolysis of phosphodiester bonds41) and lysis of

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microorganisms. After resuspending the soil pellet in the extraction buffer, the vials were shaken

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for 1 hr in the dark (500 rpm; 4 ºC) and then centrifuged for 5 minutes (10,000 RCF; 4 ºC). The

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supernatant solution (0.550 mL) was transferred to a new microcentrifuge tube for analysis.

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32P-dsRNA

to each soil

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All buffers were prepared with sterile-filtered water in pre-baked glassware and autoclaved

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once per day for three consecutive days to avoid microbial and nuclease contaminations (details

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in SI).

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Quantification of 32P-activity in soil solutions and pellets.

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The 32P-activities in both soil solutions and pellets were quantified by Cerenkov counting

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using a Packard Tri-Carb liquid scintillation counter. Each sample was analyzed twice. Results

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were averaged and corrected for signal suppression by the sample matrix and 32P radioactive decay

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(Figure S7; Table S3). We determined the distribution of

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pellet after accounting for the volume of solution that we could not remove from the pellet when

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pipette-transferring the supernatant to a new microcentrifuge tube. We calculated the 32P-activity

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in the residual solution by assuming

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supernatant and the residual solution.

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Size analysis of 32P-dsRNA and degradation products.

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32P-activity

32P-activity

between the solution and

per unit volume was equivalent between the

We used polyacrylamide gel electrophoresis (PAGE) coupled to phosphorimaging to semi-

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quantitatively analyze dissolved

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degradation and incorporation into biomolecules. For this analysis, samples (5 µL) were mixed

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with 2x loading dye (5 µL, 95% formamide), heated (95˚C; 5 min), and then loaded on denaturing

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PAGE gels (14% polyacrylamide-8 M urea). Denaturing PAGE gels42 were selected so that RNA

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molecules were separated only by length. Gels were run at 100 V for 2 hours, dried, and exposed

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overnight on a storage phosphor screen (GE). The phosphor screen was scanned on a Typhoon

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Phosphorimager. The image intensity as a function of migration distance into the gel was

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quantified using ImageJ Fiji software after background subtraction. Using 32P-dsRNA standards,

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we determined that the image intensity increased with increasing 32P-activity according to a non-

32P-dsRNA

molecules and

32P-containing

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products of dsRNA

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linear function (Figure S8). We showed that matrix components in the soil supernatant solutions

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did not affect dsRNA migration or intensity, but that matrix components in the soil extracts

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increased the dsRNA migration distance and decreased measured 32P intensities (Figure S9).

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Statistical analysis.

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Results represent means and standard deviations (indicated by error bars), unless otherwise

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stated. Statistical analyses were performed using Prism 7 for Mac OS X (GraphPad Software, Inc.).

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Statistical significance was determined using an unpaired Student’s t-test with Welch’s correction

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(ns = not significant, p > 0.05; * p < 0.05; ** p < 0.01; *** p < 0.001, **** p < 0.0001).

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Results and Discussion.

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Incubation of 32P-dsRNA in soil solutions.

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To assess degradation and microbial utilization of dissolved 32P-dsRNA, while at the same

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time minimizing

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solutions collected as the supernatant of centrifuged soil suspensions (Scheme 1A). Centrifugation

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removed most, but not all, particulates: the solution contained a small number of soil particles and

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active microorganisms (Figure S3-5). Because abiotic dsRNA hydrolysis is slow under the

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experimental pH and temperature conditions (i.e., on a timescale of years),41 we anticipated

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decreasing dissolved

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occurring processes: (i) dsRNA hydrolysis by extracellular hydrolases and (ii) microbial uptake

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and utilization of dsRNA and its hydrolysis products. We note that while hydrolases either specific

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to or competent towards dsRNA have been identified,43-45 their abundance and activity in soils is

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not documented.

32P-dsRNA

adsorption to soil particles, we first incubated

32P-dsRNA

32P-dsRNA

in soil

concentrations during incubation would result from two co-

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We first verified that PAGE coupled to phosphorimaging allows investigating hydrolysis

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reactions by detecting both loss of the intact molecule and formation of lower molecular weight

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(LMW) fragments. To this end, in a control experiment, we treated 32P-ssRNA with the ssRNA-

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specific46 RNase T1 hydrolase to generate smaller ssRNA fragments. We note that we monitored

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ssRNA hydrolysis by RNase T1 because a dsRNA-specific hydrolase was not available to us.

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RNase T1 treatment decreased the amounts of intact ssRNA and produced LMW fragments

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(Figure 1A, B). The total 32P counts in the gel (i.e., intensity values integrated over the gel length)

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in the ssRNA sample degraded by RNase T1 was the same as in the untreated ssRNA sample. We

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therefore concluded that most 32P-containing hydrolysis products were retained in the gel under

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the selected run conditions.

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As expected, the ssRNA-specific RNase T1 did not degrade dsRNA (Figure 1A, B).

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However, incubation of dsRNA in the soil solution resulted in decreasing dissolved concentrations

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of intact dsRNA (Figure 1C, D), indicating that dsRNA degradation may occur in the soil solution.

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While intact 32P-dsRNA was still present after 0.5 hr of incubation, it was no longer detectable

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after 24 hr incubation. Total 32P activity retained in the gel decreased by 45 (8)% from 0.5 to 24

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hr. In comparison to ssRNA hydrolysis by RNase T1 (Figure 1B), incubation of dsRNA in the soil

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solution resulted in few detectable LMW hydrolysis products, demonstrated by low intensities at

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longer migration distances (Figure 1D). Instead, a sharp peak in 32P-activity was detected at a short

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migration distance (< 0.1 cm into the gel). The intensity at this location approximately doubled

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during incubation from 0.5 to 24 hr. Based on the short migration distance, we hypothesized that

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these higher molecular weight (HMW)

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microorganisms synthesized from 32P-dsRNA and/or its hydrolysis products. To provide support

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that these products resulted from microbial uptake and utilization, we conducted a series of

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experiments in which microbial activity in the solutions was reduced either by filter-sterilization

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or by X-ray pre-treatment of the soils, as described in the following paragraphs.

32P-containing

molecules were biomolecules that

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After incubating 32P-dsRNA in soil solutions for 0.5 or 24 hr, we passed aliquots of the soil

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solutions through 0.22 µm syringe filters and quantified dissolved 32P-activity in the filtrate (Figure

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1E). Filtration removed microbial cells (Figure S3) and larger particles from the solutions. After

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incubation for 0.5 hr, the 32P-activity in the filtrate corresponded to 79 ± 3% of the initial total 32P-

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activity added to the solution as 32P-dsRNA; therefore, most of the added 32P remained dissolved

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over the 0.5 hr incubation. The minor loss of dissolved 32P-activity observed at this early timepoint

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may have resulted from either adsorption of

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transfer of 32P-containing molecules to cells or particles. In contrast, after 24 hr incubation, no 32P-

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activity was quantifiable in the filtrate, demonstrating that the solution was completely depleted of

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dissolved

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HMW products (nor other products) were detected by PAGE analysis of the filtrate (Figure 1F).

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These findings imply that incubation of 32P-dsRNA from 0.5 to 24 hr resulted in substantial transfer

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of the 32P-activity into cells or onto suspended particles that were removed by filtration.

32P-dsRNA

and

32P-containing

32P-containing

molecules to the filter apparatus or

degradation products. Consistently, no

32P-containing

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To further characterize solution-phase dsRNA degradation, we performed another 24 hr

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incubation experiments in which we filtered the soil solutions before adding the 32P-dsRNA. When

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these solutions were filtered again after incubation, 79 ± 8% of the 32P-activity remained in the

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final filtrate (Figure 1E). Therefore, the removal of cells and particles from solution prior to

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incubation increased the fraction of

236

only filtered prior to incubation, the formation of the HMW products was reduced by ~75% relative

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to the unfiltered solution (Figure 1F). Though dissolved 32P-activity remained in the filtrate and

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few HMW products formed in pre-incubation filtered solutions, we did not detect intact dissolved

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32P-dsRNA

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dsRNA suggested that it had been degraded by extracellular hydrolases that were not removed in

32P-activity

that remained dissolved. In a solution that was

in the pre-incubation filtered solution or its filtrate (Figure 1F). The absence of 32P-

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the pre-incubation filtration step. However, unlike small hydrolysis products produced from 32P-

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ssRNA hydrolysis by RNase T1 (Figure 1B), no 32P-containing hydrolysis products were retained

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on the PAGE gel in the pre-incubation filtered solutions (Figure 1F). Because the filtrate contained

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dissolved 32P-activity (Figure 1E) but not intact 32P-dsRNA nor 32P-containing products retained

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by PAGE, we conclude that 32P-dsRNA was likely degraded into LMW 32P-containing molecules

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that were too small to be retained in the gel (e.g., short oligomers (< 15 bp), monomers, or

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inorganic phosphate; detailed explanation in SI).

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To support the involvement of microorganisms in the incorporation of

32P

from dsRNA

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into HMW products (as opposed to resulting from

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particles also removed by filtration), we incubated 32P-dsRNA in unfiltered soil solutions obtained

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from both native and X-ray pre-treated soils (soil 2.2 in Figure 1G, H; soil 2.3 in Figure S10). We

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verified that X-ray pre-treatment of the two soils decreased the number of viable microorganisms

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of the respective soil solutions (Figure S3-S5). At the same time, solutions from the treated soils

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contained nonviable microorganisms (Figure S4, S5) and other particulates. Solutions from X-ray

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treated soils were expected to also retain some enzymatic activity.47,48 After incubation of

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dsRNA in the soil solutions for 3 hr, more 32P-dsRNA remained intact in the solutions obtained

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from X-ray treated soils than from the untreated soils (i.e., 30 and 40% more in soils 2.2 and 2.3,

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respectively). This finding indicates that the stability of dsRNA increased when the number of

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viable microorganisms decreased. While intact 32P-dsRNA was not detected in any of the solutions

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after incubation for 24 hr (despite 32P-activity remaining in solution, Figure S11), the formation of

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HMW products was suppressed by >90% in solutions with fewer viable microorganisms from X-

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ray treated soils as compared to solutions from untreated soils (Figure 1H). These results support

32P-containing

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32P-

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the formation of HMW products due to microbial utilization of 32P-containing dsRNA and/or its

264

degradation products.

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These results collected by dsRNA incubation in solutions provide strong evidence for

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degradation of dissolved dsRNA, even in solutions with decreased microbial activity obtained by

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filtration or X-ray soil treatment. While a reduction in microbial activity only slightly decreased

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dsRNA loss, it largely decreased the formation of 32P-containing HMW products. Taken together,

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these results are consistent with degradation of dissolved dsRNA in soil solutions by extracellular

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microbial hydrolases and – if viable microorganisms are present – microbial uptake and utilization

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of the dsRNA or its hydrolysis products.

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Distribution of 32P-activity between solution and soil particulates in soil suspensions.

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In comparison to soil solutions, dsRNA in soil suspensions is subjected to additional

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processes due to the presence of soil particles, including degradation and utilization of dsRNA by

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particle-associated microorganisms and adsorption to particle surfaces. In a first set of soil

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suspension experiments, we assessed the timescale over which 32P-activity, added as 32P-dsRNA

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to the solution phase, became associated with suspended particulates of soil 2.4 (selected because

278

of its high basal respiration rate, Figure S2). To this end, we incubated

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suspensions for 0.3-30 hr, followed by centrifugation and quantification of 32P-activity in both the

280

supernatant solution (i.e., 32Paq) and in the soil pellet (i.e., 32Psoil) (Figure 2A). Over the first 6 hr,

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32P

282

activity remained in solution. The decrease in 32Paq during the incubation was matched by an equal

283

increase in 32Psoil. The sum of 32Paq and 32Psoil (i.e., 32Ptotal) remained approximately constant over

284

the entire incubation and was in good agreement with the initial 32P-activity added as 32P-dsRNA.

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The use of 32P-dsRNA thus allows closing the balance on added 32P-activity in soil suspensions.

aq

32P-dsRNA

in soil

decreased at an approximately constant rate. After 12 hr of incubation, 12 hr, most (>85%) 32P-activity was both soil-associated and non-

32 extracted

Psoil

formed initially after 0.3 hr of incubation reflected adsorbed

32 non - extracted

Psoil

that formed after this initial phase was largely

32P

Based on the results obtained with soil 2.4, we selected incubation times of 3 hr (when

298

32P

299

experiments. We incubated 32P-dsRNA for 3 and 24 hr in suspensions prepared with five additional

300

soils with varying physicochemical properties (Table S2) and subsequently quantified 32Paq and

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32P

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and 85% of 32Ptotal – indicating that soil properties greatly affected the rates at which 32P-containing

303

molecules associated with soil particulates. For all tested soils except 2.3, 32Paq further decreased

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from 3 to 24 hr of incubation (p < 0.05). In soil 2.3, 32Paq had already decreased to only ~5% of

305

32P

306

incubation. In all soils and at both timepoints, the balance on 32P-activity label was closed (i.e.,

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decreases in 32Paq over time were offset by increases in 32Psoil). Among soils, 32Pextracted accounted soil

308

for 10-60% of 32Ptotal. With the exception of soil 2.1, 32Pextracted remained approximately constant soil

soil

soil

total

increased with time) and 24 hr (when

32P

soil

had plateaued) for further incubation

(Figure S12). After 3 hr incubation, 32Paq for the tested soils ranged widely – between 5%

within 3 hr of incubation. For all soils, 32Paq had decreased to < 20% of 32Ptotal after 24 hr of

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32 non - extracted

309

or slightly decreased when the incubation time increased from 3 to 24 hr, while

310

increased from 5-40% of 32Ptotal after 3 hr of incubation to 25-85% of 32Ptotal after 24 hr incubation.

311

We hypothesized that differences in the distribution of

32P

Psoil

among the six soils resulted

312

from different rates and extents of processes that relate to certain soil-specific factors (e.g., pH,

313

soil texture, microbial activity) (Table S2, Figure S2). We tested for correlations of

314

, and Pextracted soil

315

physicochemical properties of these soils (Table S4). None of the

316

― extracted after 24 hr was higher in samples with high with soil pH. However, the amount of 32Pnon soil

317

fine content ( 0.05; * p < 0.05; ** p < 0.01; ***

618

p < 0.001, **** p < 0.0001).

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Environmental Science & Technology

HMW A 14000 products intact

12000

14000 products intact 12000

8000 6000 No treatment

0 -1

0

1

4000

2 3 4 Distance (cm)

intact

3000 Intensity

6000

X-ray treated No treatment

2000 5

0 -1

6

extract from soil 2.2 tincubation = 3 hr X-ray treated

2000 No treatment

D

0

4000

1

2 3 4 Distance (cm)

intact

3000 Intensity

2000

0 -1

0

1

2 3 4 Distance (cm)

5

0 -1

F

HMW products intact solution from soil 2.3

0

1

2 3 4 Distance (cm)

HMW products intact

8000

5

6

solution from soil 2.3 tincubation = 24 hr

2000

No treatment

0 -1

0

4000

1

2 3 4 Distance (cm) intact

3000

Intensity

X-ray treated

4000

5

extract from soil 2.3 tincubation = 3 hr X-ray treated

No treatment

1000

No treatment

0 -1

6

2000

0 -1

X-ray treated

2000

H

0

1

4000

2 3 4 Distance (cm)

intact

3000 Intensity

Intensity

6000

4000

Intensity

extract from soil 2.2 tincubation = 24 hr

No treatment

6

6000

619

6

X-ray treated

2000

tincubation = 3 hr

G

5

1000

1000

E 8000

8000 4000

4000

C

solution from soil 2.2 tincubation = 24 hr

10000

X-ray treated

Intensity

Intensity

10000

HMW

B

solution from soil 2.2 tincubation = 3 hr

Page 30 of 31

5

6

extract from soil 2.3 tincubation = 24 hr X-ray treated

2000

No treatment

1000

0

1

2 3 4 Distance (cm)

5

6

0 -1

0

1

2 3 4 Distance (cm)

5

6

620

Figure 3. PAGE analysis of supernatant solution and extracts collected from soil suspensions (0.20

621

g soil in 0.40 mL incubation solution containing 10 mM NaCl and 5 mM buffer at native soil pH)

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622

incubated with 32P-dsRNA (12 ng). Intact dsRNA and higher molecular weight (HMW) products

623

are indicated. The soil suspensions were prepared using soil 2.2 (A-D) and soil 2.3 (E-H) with or

624

without treatment by X-ray irradiation (43.5 kGy). The supernatant solution was obtained by

625

centrifugation and analyzed after incubation for 3 hr (A, E) or 24 hr (B, F), The extract was

626

obtained from the soil pellet (extraction buffer: pH 9.4; 220 mM borate, 7 mM EDTA, 3 mM

627

hexametaphosphate) from the same samples (incubation period of 3 hr (C, G) or 24 hr (D, H).

628

Results shown are from triplicate experiments.

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