Transcriptome Analysis of Invasive Plants in Response to Mineral

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Transcriptome Analysis of Invasive Plants in Response to Mineral

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Toxicity of Reclaimed Coal-mine Soil in the Appalachian Region

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Thangasamy Saminathan1‡, Sridhar A. Malkaram1‡, Dharmesh Patel2, Kaitlyn Taylor1, Amir

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Hass2, Padma Nimmakayala1, David Huber1, Umesh K. Reddy1*

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Department of Biology, Gus R. Douglass Institute, West Virginia State University, Institute,

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WV 25112-1000, USA. 2

Agricultural and Environmental Research Station, Gus R. Douglass Institute, West Virginia State University, Institute, WV 25112-1000, USA.

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KEYWORDS: Coal mine; Soil; Toxicity; Transcriptome; RNA-seq; Mugwort; Goutweed;

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Reclamation; Appalachian Mountains.

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ABSTRACT:

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Efficient post-mining reclamation requires successful revegetation. By using RNA sequencing,

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we evaluated the growth response of two invasive plants, goutweed (Aegopodium podagraria L.)

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and mugwort (Artemisia vulgaris), grown in two Appalachian acid-mine soils (MS-I and -II, pH

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~4.6). Although deficient in macronutrients, both soils contained high levels of plant-available

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Al, Fe and Mn. Both plant types showed toxicity tolerance, but metal accumulation differed by

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plant and site. With MS-I, Al accumulation was greater for mugwort than goutweed (385±47 vs

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2151±251 µg g-1). Al concentration was similar between mine sites, but its accumulation in

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mugwort was greater with MS-I than MS-II, with no difference in accumulation by site for

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goutweed. An in situ approach revealed deregulation of multiple factors such as transporters,

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transcription factors, and metal chelators for metal uptake or exclusion. The two plant systems

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showed common gene expression patterns for different pathways. Both plant systems appeared

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to have few common heavy-metal pathway regulators addressing mineral toxicity/deficiency in

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both mine sites, which implies adaptability of invasive plants for efficient growth at mine sites

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with toxic waste. Functional genomics can be used to screen for plant adaptability, especially for

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reclamation and phytoremediation of contaminated soils and waters.

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INTRODUCTION:

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Coal mining process in the Appalachian region

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The Appalachian basin is a coal-rich region extending from Alabama to Maine in the United

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States. Coal mining has been performed in West Virginia, in the Central Appalachian region, for

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271 years. Mining activity results in a land cover change with huge environmental consequences.

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In total, 5% (19,581 km2) of the land surface in southern West Virginia was converted to surface

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mines in the 3 decades after 1976 1. Coal mining in Appalachia is expected to continue to be a

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significant contributor to the region economy and US energy portfolio, with projected production

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of 240 million tons per year by 2040 (reduced from 266 million tons in 2012) 2.

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Mountain-top removal is used for near-surface coal extraction. Such a large-scale disturbance

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and activity leads to coal slurry, or sludge, a mix of water, coal dust and clay containing toxic

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heavy metals such as arsenic, mercury, lead and chromium and excess essential minerals. In

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addition to an imbalance in toxic mineral and heavy metal content, soil pH decreases to < 5.5

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because of weathering of rocks and oxidation of pyritic minerals into sulfuric acid during mining

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3

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forming ions (H, Al). Moreover, the removal of the native soil and its replacement with soil

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replacement material, namely finely crushed rocks, creates additional challenges for plant

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establishment and growth and overall success of revegetation and reclamation in the post-mining

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area.

. The process involves removing the base-forming ions (Ca, Mg, K) and replacement with acid-

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Heavy metal toxicity and plant signaling

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Macronutrients such as N, P, K, Ca, Mg, and S, and micronutrients such as Fe, Cu, Mn, Zn,

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Mo, Cl, and Ni are required for plant growth. Other minerals such as Na, Co, V, Se, Al and Si

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are beneficial but not necessary to plants. Nutrient toxicity or deficiency occurs when nutrients

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are present in excess or insufficient quantity 4. Basal heavy-metal toxicity occurs in plants by

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uptake, sequestering and chelating the excess minerals that are present 5. The easiest strategy for

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plants is to sequester or exclude minerals. However, this process causes homeostasis disruption

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with symptoms such as impaired chlorophyll synthesis 6, diminished photosynthesis 7 or altered

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root ultrastructure 8. Hyperaccumulator plants use different strategies for metal accumulation in

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aboveground tissues.

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Glutathione (GSH) plays a key role in metal scavenging because of the great affinity of metals

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to bind its thiol (-SH) group and is a precursor of phytochelatins. Almost one third of

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characterized proteins are metalloproteins, containing essential metals in their active center.

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During metal homeostasis, metals enter the cell and are involved in two mechanisms: specific

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chaperones deliver metals to the site of action 9 and chelators sequester excess free metal ions 10.

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In addition to metal homeostasis, when plants are exposed to an abnormal concentration of

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metals, they show oxidative stress, whereby the cellular redox balance between anti- and pro-

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oxidants is further disturbed 11. To cope with oxidative damage, the level of pro-oxidants plays a

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major role in cellular protection for Cd or Cu toxicity 12. During oxidative defense against metal

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stress, the primary response of plants is to generate reactive oxygen species (ROS), namely

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hydrogen peroxide (H2O2), superoxide (O2⋅–), and hydroxyl radical (HO⋅)

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adversely affect plant growth at morphological, physiological and biochemical levels

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sedentary, plants require both efficient perception and signaling systems for elevated ROS

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production when experiencing metal stress. When plants sense Cd or Cu toxicity, NADPH

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oxidase and lipoxygenase, respectively, are upregulated. Mitogen-activated protein kinases

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(MAPKs), sensors of ROS, link the perception of metal stress to downstream phosphorylation of

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. These species 14

. Being

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transcription factors (TFs). The MAPK cascade plays key roles in signaling activated by

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different metals 15-17.

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Metal toxicity and gene regulation

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The hyperaccumulator Arabidopsis halleri features the expression of > 30 candidate genes as 18

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compared with the non-accumulator Arabidopsis thaliana on exposure to Zn

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such as heavy-metal ATPases (HMA) transporters are required to absorb the metals

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transport Zn2+, Cu+, Cu2+, Cd2+, Pb2+, Ni2+, and Co2+ across biological membranes to load them

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into the xylem stream with the help of HMAs 20. Plant cells possess different transport systems

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such as HMAs; natural resistance-associated macrophage proteins (Nramps); ZRT, IRT-like

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proteins (ZIPs); ATP-binding cassette (ABC) transporters; antiporters of cations; and other metal

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transporters. Arabidopsis iron-regulated transporter (IRT1), located in the root plasma

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membrane, can transport a wide range of substrates including Fe

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Zn tolerance via cross-homeostasis between Zn and Fe in Arabidopsis

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cation/proton exchangers sequester metals into subcellular compartments such as the vacuole 24.

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Malate transporter (AtALMT1), in a 14-member family, is critical for Al tolerance in Arabidopsis

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Cu, Cd, Fe, Co, Zn, and Cr 26.

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. Metal-pumps 19

. They

. GSH plays a key role in 23

. ABC transporters or

. Multiple cellular responses and downstream signals exist for different heavy metals such as

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TFs play key roles in metal toxicity. Basic helix-loop-helix TFs control the expression of key

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genes such as IRT and ferric oxidase reductase (FRO) functioning in Fe acquisition in tomato 27.

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Other TFs, bZIP, Myb and zinc-finger proteins are upregulated by Cd exposure

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. More than

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131 TFs were significantly upregulated in Thlaspi caerulescens grown under Zn-sufficient

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conditions

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element-binding factor and dehydration-responsive element-binding protein were up- or

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. In addition to TFs, cis-element binding proteins such as ethylene-responsive

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downregulated with Cd and Cu treatment

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metal hyperaccumulating abilities.

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. Therefore, TFs play pivotal roles in maintaining

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Because of surface-mining operations used on a large scale in the Appalachian region for coal

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excavation, successful post-mining revegetation processes are needed to restore ecosystem

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services such as clean water and stable grounds. Use of genomic technologies such as RNA

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transcriptome sequencing (RNA-seq) has great potential for studying and identifying

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differentially regulated factors in plants, including hyperaccumulation of metals, when grown

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under adverse environmental conditions.

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In this study, we used two different invasive medicinal plant species, goutweed and mugwort,

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to study the effect of two different mine soils on the transcriptome profiles. We examined 2 mine

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sites in West Virginia, mine site I and II (MS-I and -II), that contained a range of metals at toxic

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levels and analyzed the gene expression profile of the two plant species grown in soil from the

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sites. We profiled the key TFs, metal transporters, and enzymes of biochemical pathways. Both

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plants exhibited many common regulators across both mine soils. We discuss these results and

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their implications for bioremediation and reclamation.

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EXPERIMENTAL METHODS:

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Plant materials and soil collection

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The invasive plants goutweed (Aegopodium podagraria L.; Ap) and mugwort (Artemisia

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vulgaris; Av) were collected from local mountains in West Virginia. They were vegetatively

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propagated from a single genotype by using stolon and rhizomes, respectively, to ensure

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homogeneity. Young new shoots were chosen for pot experiments. We collected surface soil

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samples (0-15 cm) from two different mining locations that were mined and reclaimed in 1980

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(MS-I; 38°10’39.89” N; 81°31’46.29” W) and in 2005 (MS-II; 38°11’47.38” N; 81°38’35.14”

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W).

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Soil processing and experimental analysis

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Mine soils were air-dried and sieved through a 2-mm screen before analysis. Soil samples were 32

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analyzed for Mehlich-3 extractable elements as described

. Leaf and stem tissues were

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microwave-digested as described 33. Soil extracts and digested plant materials were analyzed by

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use of the Optima 8300 ICP-OES Spectrometer (Perkin Elmer, Waltham, MA, USA).

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Pots were filled with the mine soils, and commercial Promix-filled pots were used as a control.

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The vegetatively propagated plantlets were transplanted into pots, with three biological

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replications. Plants were irrigated with no additional nutrients and grown for 40 days before

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harvesting. Root and shoot tissues were collected from 40-day old plants for RNA extraction and

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plant element analysis, respectively.

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RNA extraction, Library preparation and RNA-seq

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Roots of goutweed and mugwort were washed to remove dirt and stored at -70°C. Total RNA 34

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was extracted as suggested

by using TRIzol reagent (Invitrogen, Carlsbad, CA, USA) and the

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RNA MiniPrep kit (Zymo Research, Irvine, CA, USA). Later, on-column DNase digestion was

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also performed. RNA integrity number (RIN) >8.0 was confirmed by use of the 2100

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Bioanalyzer (Agilent Technologies, Santa Clara, CA, USA). Beads with Oligo(dT) were used to

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isolate poly(A) mRNA after total RNA was collected. Furthermore, mRNA was broken down

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into short fragments by adding fragmentation buffer. Taking these short fragments as templates,

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random hexamers were used to synthesize the first-strand cDNA. The second-strand cDNA was

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synthesized by using GEX Second Strand buffer and DNA polymerase I (Illumina, San Diego,

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CA, USA). The double-strand cDNA short fragments were then purified and resolved with EB

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buffer for end repair and adding a poly(A). Next, the short fragments were connected with

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sequencing adapters and purified by agarose gel electrophoresis. Suitable fragments were

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selected as templates for the PCR amplification. Finally, the library from two biological

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replications was used for 50-bp paired-end RNA-seq (Genomic Services Laboratory, Huntsville,

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AL, USA) with the Illumina HiSeq 2500 system (Illumina, Inc., San Diego, CA, USA).

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RNA-seq and data analysis

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Poly(A) RNA from two biological replicates in each treatment was sequenced by the Ilumina

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paired-end sequencing protocol. About 80 to 107 M total reads were generated for each

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treatment.

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(http://www.bioinformatics.babraham.ac.uk). The adapter sequence was removed from reads by

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use of cutadapt v.1.2.1

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reads were checked and trimmed for A/T homopolymer tails of >8 bases and filtered with >2 Ns

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present or with quality score